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Performance Audit Report on the Control of F MD Note: The following factors were considered during assessments of disease control gates; As Table 5 indicates most check points were deficient in many aspects from a bio-security stand point. The only aspect that had alternative measures in place were vehicle baths whereby knapsack sprayers were used instead. However it was observed that knapsack sprayers provided relatively limited coverage of vehicles (compared to vehicle baths) and were subject to improper application by the person spraying. For instance the Setata and Samochima gates lacked lighting needed for disinfection throughout the night. Interviews with Principal Veterinary Officers in the visited districts attributed such structural deficiencies at the disease control gates to financial constraints. The safety of staff manning the gate at night and poor visibility (as a result of lack of lighting) could result in significant compromise in conducting searches and disinfection at night at the two gates. The structural inadequacies of disease control gates was attributable to lack of standards for designs of disease control gates as well as inadequate resource planning for improving general conditions of movement control gates. There was no evidence (budget and plans) availed during the audit that could indicate that 34 | P a g e  Signage: important for awareness of travelers needed for facilitating cooperation with DVS personnel at check points and safety of personnel on the road.  Lighting: needed for providing visibility at night crucial for facilitating checks and disinfection at night as well as for security of staff manning the gates.  Cattle grid: important for stopping cattle from straying into other zones especially in the event gates happen to be unmanned (due to bad weather conditions and staff absenteeism).  Vehicle bath: facilitate better vehicle coverage during disinfection and cause less disruption to traffic flow and therefore minimising inconveniences to travelers.  Movement Protocol Boards: needed for awareness to travelers crucial for ensuring cooperation with DVS personnel at check points.  Guard house: to shelter staff manning gates and their equipment
2laws_and_regulations
I C» t ’ / \ _/ ’\ )- PR~SSURE L LINE ’ ’---- - / ’ENGINE / ~' _ r- OILTANK ( ---............._ ~- 1 ro"~''"' / PRESSURE GAUGE LIN£ STARBOARD ENGINE \ ’ ;-- "’--- ~- ''-< ~ ~ ~ ~ ~2_) OIL OUTLET FROiiEiiGT!it --OIL INLET TO ENGINE SCREEN ~ ~~ (*1011[SH -Oi!5 WIR£ }~ :::: ~ - < wJ ~ ~r · i!}) ~ \ //Ill I )"’ ’ # SCREEN FLANGE DETAIL ~r - OIL COOLER --FROM TEMP. REGULATOR - - TEMPERATURE REGULATOR ---------- --------- Fig. XXXI OIL SYSTEM (K-75 and Future)
2laws_and_regulations
SECTION 1283 . Additional Counsel to Assist Attorney-General. — The Attorney-General shall when in his opinion the public interest requires it upon the approval of the Secretary of Finance and Justice employ and retain in the name of the Government of th e Philippine Islands such attorneys as he may deem necessary to assist him in the discharge of his duties. Such attorneys shall be entitled to travel expenses if incurred and such compensation as shall be stipulated for. [523-3.] SECTION 1284 . Authority of Officers to Administer Oaths and Take Testimony . — The Attorney-General the Solicitor-General the assistant attorneys of the Bureau of Justice and provincial fiscals are authorized to administer oaths in matters of official bus iness. The Attorney-General and Solicitor-General and any assistant attorney or provincial fiscal thereunto especially deputed by the Attorney-General shall have further authority to take testimony in any matter or investigation within the competency of th e Bureau of Justice. SECTION 1285 . Annual Report of Attorney-General. — The annual report of the Attorney-General shall among other things contain a statement of the conditions affecting the administration of justice throughout the Islands and an account of public litigation pending in the courts. [1699-1; Comp. 107.] Estates of Government Employees SECTION 1286 . Settlement of Estates of Deceased Employees . — When a citizen of the United States who is an employee of the Philippine Government or who is a civilian employee of the United States in the Philippine Islands shall die leaving property in sai d Islands either real or personal not exceeding one thousand five hundred pesos in value the Attorney-General shall if no regular administration of his estate is had take possession of such estate make a complete inventory thereof and file the same with the Insular Auditor. [1407-18 ( b ); 2136-1.] He shall thereupon proceed to ascertain by the best means within his power the names and residences of the persons who are lawfully entitled to the estate and shall proceed to settle the same and to dispose of the assets in accordance herewith. [290-1; 2136-1.] ARTICLE II Copyright 2012 CD Technologies Asia Inc. and Accesslaw Inc. Philippine Law Encyclopedia 2011 379
2laws_and_regulations
hereinafter referred to as GDE2 2 ) which describes SSD2 transmission requirements metadata and general business rules definition which might be integrated for each data collection through a business rule engine. In this remit EFSA has developed and is maintaining a set of controlled terminologies. It is of fundamental importance the effort done by EFSA in the field of food description and classification. EFSA defined the FoodEx food classification and description system to allow food coding across data domains. The first guidance on FoodEx was published in 2012 3 and an updated guidance document was published in 2015 4 (here after referred to as FoodEx2). In this context EFSA is seeking the support of a contractor for scientific data management activities and processes. This call is based on EFSA’s 2021 Work Programme for grants and operational procurements as presented in Annex XIa of the Programming Document 2021 – 2023 available on the EFSA’s website 5 . The present Call for tenders aims to conclude a framework contract up to a maximum of 4 years with one contractor. The framework contract will be implemented through specific contracts or order forms. Every time there is a need for a service/activity EFSA will request to the contractor an offer based on the prices agreed under the framework contract. Once the estimate provided by the contractor is accepted by EFSA a specific contract or order form will be concluded between EFSA and the contractor. The specific contract or order form will set out the specific conditions for performing the individual assignment. For more details on the administrative implementation modalities of the framework contract please refer to section 1.4 of these tender specifications. 1.2 OBJECTIVES The contractor must be able to carry out several individual assignments in parallel and to provide the required services within assigned time and according to quality criteria defined by EFSA. The objective of this call for tender is to acquire support in the following areas: a. Scientific data management: i. Data collection and data connection; ii. Management of standard and controlled terminology; iii. Data flows for integration and transformation; iv. Scientific data validation; v. Identity management; 5 2 Guidance on Data Exchange version 2.0. EFSA Journal 2014;12(12):3945 173 pp. doi:10.2903/j.efsa.2014.3945 3 European Food Safety Authority; The food classification and description system FoodEx 2 (draft revision 1). Supporting Publications 2011:215. [438 pp.]. Available online: www.efsa.europa.eu 4 European Food Safety Authority 2015. The food classification and description system FoodEx2 (revision 2). EFSA supporting publication 2015:EN-804. 90 pp. Available online: www.efsa.europa.eu 5 https://www.efsa.europa.eu/sites/default/files/event/2020/mb201217/9-programming-document-2021-2023- 7mb201217-a2.pdf
1government_tenders
Development of the World Economy According to a value assessment of the “Kiel Institute for World Economics ” the world economy maintained its upswing in 2004 but lost some momentum from the spring onward. This weakening is attributable in part to a tightening of previously expansive economic policy. Although the impetus of US fiscal policy had lost most of its momentum monetary conditions nevertheless remained clearly positive. China took administrative measures to slow down the excessive economic boom. Economic activities were additionally dampened by the steep rise in oil prices. However the negative effects of oil price increases were buffered by economic expansion in various regions of the world. The economic recovery also continued in the Euro zone over the course of the year. Real gross domestic product grew faster than in the second half of 2003. In general however development in the Euro Zone differed significantly from country to country. The major sports events in the year 2004 also had a positive impact on the sporting goods industry. Despite limited consumer spending additional growth was reported in nearly all markets. Overall PUMA has achieved strong global positioning as a Sportlifestyle brand resulting in a competitive advantage and enabling adaptation to constantly changing market conditions. The selective distribution strategy will anchor and further expand the desirability of the brand. Foreword | Mission | Management Report | Share | Marketing | Consolidated Financial Statements - IFRS - | Report of Supervisory Board | Board of Management 14
0financial_reports
Increased pricing pressure and other restrictions in the U.S. and abroad from MCOs institutional purchasers and government agencies and programs among others continue to negatively affect our revenues and profit margins. Our products continue to be subject to increasing pressures across the portfolio from market access pharmaceutical pricing controls and discounting and other restrictions in the U.S. the EU and other regions around the world that result in lower prices lower reimbursement rates and smaller populations for whom payers will reimburse which negatively impact our revenues and profit margins including from (i) the impact of the increased pricing pressure from Medicare Part D formularies Medicare Part B reimbursement rates (including the potential implementation of the pilot program by the Centers for Medicare & Medicaid Services (“CMS”) that would among other things set payment amounts to physicians on Part B drugs based on international drug prices and would include fifty percent of Medicare Part B single source drugs) expanded utilization under the 340B Drug Pricing Program (“340B”) as well as commercial formularies in general; (ii) rules and practices of MCOs and institutional and governmental purchasers taking actions to control costs or shift the cost burden to manufacturers including actions that could result in the exclusion of a product from or the unfavorable placement of a product on a MCO formulary; (iii) government administrative and policy changes and changes in laws and regulations for federal healthcare programs such as Medicare and Medicaid other government actions and inquiries at the federal level (including the proposals contained in the “ American Patient First Blueprint ”) that seek to amend pharmaceutical pricing and reimbursement practices such as using international pricing indexes modifying the federal Anti-Kickback statute discount safe harbor accelerating generic drug approval processes promoting the use of biosimilar drugs and the option of applying step therapy listing prices of products in DTC television advertisements and granting additional authority to governmental agencies to manage drug utilization and negotiate drug prices and laws at the state level (including laws that have recently been enacted in California Vermont Nevada and New York that are focused on drug pricing transparency and/or limiting state spending on drugs) including the proposed rule by the U.S. federal government to allow states or certain other non-federal government entities to submit proposals to the FDA allowing for the importation of certain prescription drugs from Canada; (iv) the potential impact of changes to U.S. federal pharmaceutical coverage and reimbursement policies and practices including changes resulting from our implementation of the guidance in the 2016 final rule issued by the CMS on the calculation of average manufacturer price and best price (which also will require inclusion of sales in U.S. Territories in the calculation of average manufacturer price and best price beginning on April 1 2022) as well as the scrutiny of drug manufacturers including Celgene by the House Oversight and Reform Committee in January 2019 seeking documents and detailed information about drug-pricing practices; (v) reimbursement delays; (vi) government price erosion mechanisms across Europe and in other countries resulting in deflation for pharmaceutical product pricing; (vii) the increased purchasing power of entities that negotiate on behalf of Medicare Medicaid and private sector beneficiaries; (viii) collection delays or failures to pay in government-funded public hospitals outside the U.S.; (ix) the impact on pricing from parallel trade and drug importation across borders; (x) other developments in technology and/or industry practices that could impact the reimbursement policies and practices of third-party payers; and (xi) inhibited market access due to real or perceived differences in value propositions for our products compared to competing products. We expect that these market access constraints pharmaceutical pricing controls and discounting and other restrictions will become more acute and will continue to negatively affect our future revenues and profit margins. Additionally in early 2016 Health Resources and Services Administration (“HRSA”) finalized a regulation regarding the 340B pricing methodology and providing guidelines for when civil monetary penalties may be issued for “knowing and intentional” manufacturer overcharges of 340B covered entities. The effective date of this regulation was January 1 2019. Following the effective date manufacturers who are found to have knowingly and intentionally overcharged 340B covered entities could be subject to significant monetary penalties. Such findings could also result in negative publicity that could harm the manufacturer’s reputation or cause business disruption. Over the course of the past few years Celgene had received inquiries from HRSA regarding the limited distribution networks for Revlimid Pomalyst and Thalomid and compliance with the 340B program. We believe that we have complied with applicable legal requirements. If we are ultimately required to change our sales or pricing practices with regard to the distribution of these drugs under the 340B program or if we were required to pay penalties under the applicable regulations there would be an adverse effect on our revenues and profitability. Compounds or products may appear promising in development but fail to reach market within the expected or optimal timeframe or at all. In addition product extensions or additional indications may not be approved. Furthermore products or indications approved under the U.S. FDA's Accelerated Approval Program may be contingent upon verification and description of clinical benefit in confirmatory studies and such studies may not be successful. For example in July 2019 we announced that Part 2 of the Phase III CheckMate-227 trial did not meet its primary endpoint of overall survival with Opdivo plus chemotherapy versus chemotherapy therapy in patients with first-line non-squamous NSCLC. Developing and commercializing new compounds and products involve inherent risks and uncertainties including (i) efficacy and safety concerns delayed or denied regulatory approvals delays or challenges with producing products on a commercial scale or excessive costs to manufacture products; (ii) inability to enroll patients and timely completion of the clinical trials; (iii) failure to enter into or implement optimal alliances for the development and/or commercialization of new products; (iv) failure to maintain a consistent scope and variety of promising late-stage products; (v) failure of one or more of our products to achieve or maintain commercial viability; and (vi) changes in regulatory approval processes may cause delays or denials of new product approvals. We may experience difficulties or delays in the development and commercialization of new products. 20
0financial_reports
Santos Basin Blocks S-M-1352 and S-M-1354 Equity Interests During August 2010 Karoon entered into agreements with Petrobras to farm-in to two contiguous Blocks S-M-1352 and S-M-1354 to earn a 20% interest. Karoon is currently awaiting regulatory approval from the ANP at the date of this Annual Report. During the financial year Petrobras drilled two exploration wells one well on each block to satisfy work programs. The first well Quasi-1 was drilled on Block S-M-1354 did not make a discovery and was plugged and abandoned in September 2010. This block expired during November 2010 and was formally relinquished by Petrobras during January 2011. The second well in the campaign Maruja-1 drilled in Block S-M-1352 discovered high quality light oil of 38 gravity API within a Oligocene aged sandstone reservoir. A full wire-line and pressure sampling program concluded that the reservoir was of high quality with excellent porosity and permeability. This reservoir interval was drill stem tested (‘DST’) which although constrained by surface tubing flowed oil at a maximum stabilised rate of 4 675 barrels of oil per day and 0.8 million cubic feet of gas per day through a ½ inch choke with a flowing well head pressure of 1050 psia. The well was then suspended during January 2011 and may be used as part of a longer production test in preparation for any eventual development that may occur. The joint venture deemed that commercial flow rates could be achieved from Maruja-1 and requested and subsequently received approval for an evaluation licence from the ANP for an area defining the Maruja field. This evaluation permit included the drilling of an appraisal well and the reduction of Block S-M-1352 to the area around Maruja field. During February 2011 Petrobras commenced the drilling of an appraisal well Maruja-2 with a location designed to intersect reservoir at over 80 metres down dip and 4.5 kilometres from the initial discovery well. This well found good quality reservoirs contained below the oil/water contact at this location but no hydrocarbons were recovered. A side track well was also drilled from the initial Maruja-2 well bore to test further up-dip on the structure. This well encountered a very similar sandstone reservoir of excellent quality but was also found to be below the oil water contact at this location. The well was plugged and abandoned during April 2011. The confirmation of good quality reservoir in a location on the edge of the interpreted Maruja field demonstrated the continuity of the sands assisting in the understanding of the field. An evaluation using all of the newly acquired well data is underway and reprocessing of the existing 3D seismic has commenced to better define and evaluate this field. Subject to ANP approval Karoon will receive a 20% equity interest in Block S-M-1352 with Petrobras holding the remaining 80% equity interest. Karoon Gas Australia Ltd Annual Report 2011 11
0financial_reports
11.1 Introduction to the HMC and SE 11.2 HMC and SE changes and new features 11.2.1 Driver Level 36 HMC and SE new features The HMC is a stand-alone computer that runs a set of management applications. The HMC is a closed system which means that no other applications can be installed on it. The HMC is used to set up manage monitor and operate one or more CPCs. It manages IBM Z hardware its logical partitions (LPARs) and provides support applications. At least one HMC is required to operate an IBM Z. An HMC can manage multiple Z CPCs and can be at a local or a remote site. The SEs are two integrated servers in the z14 ZR1 frame. One SE is the primary SE (active) and the other is the alternative SE (backup). As with the HMCs the SEs are closed systems and no other applications can be installed on them. When tasks are performed at the HMC the commands are routed to the active SE of the z14 ZR1. The SE then issues those commands to their CPC. One HMC can control up to 100 SEs and one SE can be controlled by up to 32 HMCs. Some functions are available only on the SE. With Single Object Operations (SOOs) these functions can be used from the HMC. For more information see “Single Object Operations” on page 376. With Driver 27 (Version 2.13.1) the IBM Dynamic Partition Manager (DPM) was introduced for CPCs that are running Linux only with Fibre Channel Protocol (FCP) attached storage. HMC Driver 32 (Version 2.14.0) with MCLs added support for ECKD FICON disks to the DPM (Release 3.1). HMC 2.14.1 includes DPM 3.2 with enhanced storage management capabilities. DPM is a mode of operation that enables customers with little or no knowledge of IBM Z technology to set up the system efficiently and with ease. For more information see IBM Knowledge Center. At IBM Knowledge Center click the search engine window and enter DPM . The HMC Remote Support Facility (RSF) provides an important communication to a centralized IBM support network for hardware problem reporting and service. For more information see 11.4 “Remote Support Fa cility” on page 374. The initial release that is included with z14 ZR1 is HMC application Version 2.14.0. Use the “What’s New” task to examine the new features that are available for each release. For more information about HMC and SE functions use the HMC and SE (Version 2.14.0) console help system or see IBM Knowledge Center. At IBM Knowledge Center search for “z14 HMC”. The following support has been added with Driver 36: GLYPH<SM590000> Dynamic I/O for Standalone CF CPCs (requires z/OS or z/VM support) GLYPH<SM590000> CTN Split and CTN merge GLYPH<SM590000> Coupling Facility Control Code 23 (enhancements and new features) 358 IBM 14 Model ZR1 Technical Guide
3manuals
2013 Financial Highlights Dollars in thousands except per share per store and per gross square foot data 1. For description of this financial and store data please see the fiscal 2014 Annual Report on Form 10-K. 2. Retail gross margin represents net retail sales less cost of retail merchandise sold. Retail gross margin percentage represents retail gross margin divided by net retail sales. BBW vs. S&P 500 Retailing Index vs. S&P 500 Index for Fiscal Year 2013 8 BUILD-A-BEAR WORKSHOP INC. 2013 ANNUAL REPORT BBW stock ended the fiscal year at $7.74 +98% higher than the start of the year while the S&P 500 finished the year +31% and the S&P 500 Retailing finished +46% compared to the start of the year. As part of our real estate optimization we closed 37 stores in 2013 ending the year with 28 fewer stores. Total revenue declined 0.5% with 28 fewer stores at year's end. $395.9 $401.5 $394.4 $380.9 $379.1 Dollars in millions NUMBER OF COMPANY-OWNED STORES At end of period 160% 140% 120% 100% 80% 60% 40% 20% 0% Dec 2012 Jan 2013 Feb 2013 Mar 2013 Apr 2013 May 2013 June 2013 July 2013 Aug 2013 Sept 2013 Oct 2013 Nov 2013 Dec 2013 Build-A-Bear Workshop S&P 500 Retailing S&P 500 STOCK PERFORMANCE TOTAL REVENUE $395.9 2009 2010 2011 2012 2013 $401.5 $394.4 $380.9 $379.1 287.2 359.0 350 2009 2010 2011 2012 2013 359 356 351 323 REVENUES 2013 2012 2011 Net retail sales $ 373 173 $ 374 553 $ 387 041 Franchise fees $ 3 564 $ 3 598 $ 3 391 Commercial revenue $ 2 332 $ 2 790 $ 3 943 Total revenues $ 379 069 $ 380 941 $ 394 375 Net loss $ (2 112) $ (49 295) $ (17 062) LOSS PER COMMON SHARE Basic $ (0.13) $ (3.02) $ (0.98) Diluted $ (0.13) $ (3.02) $ (0.98) OTHER FINANCIAL AND STORE DATA (1) Retail gross margin (dollars) (2) $ 153 477 $ 145 687 $ 154 468 Retail gross margin (percent) (2) 41.1% 38.9% 39.9% Number of company-owned stores 323 351 356 at end of period North American average net retail sales per store $ 1 080 $ 1 003 $ 1 021 North American net retail sales per gross square foot $ 381 $ 350 $ 354 321.2
0financial_reports
IMPROVING OUR PROFITABILITY To be able to afford increased brand building and innovation investment we need to improve our gross profit margin and control our overhead expenses. In 2003 we improved our underlying prof- itability enough to invest for the future. While our reported gross profit margin declined modestly this was largely due to investment. We incurred $70 mil- lion of asset write-offs and other up-front costs relat- ed to cost-savings initiatives; these are investments in future profitability. We also increased the use of toys in the box and other inserts a form of consumer promotion that is accounted for in cost of goods sold. We faced higher costs in the form of commodi- ties fuel and benefits but we were able to offset them with a combination of the following: These factors are expected to raise our gross profit margin over time even as we continue to face rising commodity fuel and benefits costs. Importantly we plan to use this improved profitability to reinvest in our brands. When we refer to brand building we mean advertising and consumer promotion not price discounting. In 2003 our brand-building investment was increased at a strong double-digit rate and we plan for this investment to again out- pace sales growth in 2004. Our earnings growth in 2003 was of very high quali- ty. It included the investment in brand building and cost-savings projects as well as nearly $30 million of other charges related to asset impairments and bond repurchases that are not typical events. To post a strong earnings gain in the face of these signficant charges and investments suggests a very strong underlying profitability that can be used to drive growth in the future. Kellogg Company has a significant competi- tive advantage in its global infrastructure. The decision to expand our business internationally was taken early in the Company’s history and was a far-sighted one. This scale allows us to take advantage of global sourcing decrease our input costs transfer production and administrative functions between regions and share best practices and ideas across all our markets. In 2003 our global packaging sourcing group which has members around the world instituted a broad program to coordinate the sourcing of materials adhesives and cartons in many of our markets. This program is expected to dramati- cally improve efficency and save the Company millions of dollars each year. Yet another way we are earning our stripes. Kellogg Company 17 $699 2003 $519 2001 $589 2002 2001 2002 2003 45.0% 44.2% 44.4% Gross Profit Margin Investing in Our Business: Advertising Spending % of Net Sales Millions • Increased net sales which leveraged our fixed costs; • A favorable mix shift toward our more profitable products thanks to the Volume to Value focus; • Synergies related to the Keebler acquisition which reached their targeted level; • Ongoing productivity improvements which we have relentlessly pursued and achieved over the past several years.
0financial_reports
2 were performed and the sample details are presented. The data analysis and results are presented in section III. Finally a discussion and a summary are given in sec- tion IV. tered intensity are also observed along the c -axis indi- cating a two-dimensional character to the paramagnetic fluctuations. In general spin correlations weaken and broaden further in momentum and energy with increas- ing temperature but are still observed up to the highest measured temperature of 300 K. These observations can be explained in the context of spin dynamics overdamped by particle-hole excitations. In particular we use a phe- nomenological theoretical model with in-plane and inter- plane magnetic anisotropy to consistently fit our data for all temperatures obtaining the ratios J$_{1}$/J$_{2}$ ≃ 0 . 55 and J$_{c}$/J$_{2}$ ≃ 0 . 1. We find that the spin fluctuations in the paramagnetic phase of the parent compound bear a close resemblance to the paramagnetic fluctuations in the su- perconducting compositions. This article is laid out as follows. In section II below the experimental conditions under which the experiment Inelastic neutron scattering measurements were per- formed on a single crystal mosaic ( ∼ 400 small single- crystal samples) of CaFe$_{2}$As$_{2}$ with a total mass of ∼ 2 grams that are co-aligned to within 1.5 degrees full-width-at-half-maximum (FWHM). The preparation methods of the single-crystals have been described elsewhere. 24 Data were collected using the HB3 and HB1A triple-axis spectrometers at the High Flux Iso- tope Reactor at Oak Ridge National Laboratory and the MAPS chopper spectrometer at the ISIS facility at Rutherford Appleton Laboratory. HB3 was operated in relaxed resolution for measurement of the diffuse scat- tering signals in the paramagnetic phase with fixed final energy ( E$_{f}$ ) configurations E$_{f}$ = 14.7 meV and 41.2 meV and 48’-60’-80’-120’ collimation. The sample was mounted in a closed-cycle refrigerator and oriented for scattering in the tetragonal ( hhL ) plane. HB1A was op- erated with fixed incident neutron energy of 14.7 meV and 48’-40’-40’-136’ collimation and the sample mounted in the ( h 0 L ) plane. The MAPS experiment was per- formed at T =180 K with an incident energy of 100 meV using the same sample aligned with the c -axis along the incident beam direction. To avoid confusion the data is exclusively presented in tetragonal units and we define Q = 2 π a ( h i + k j ) + 2 π c L k as the momentum transfer indexed according to the I 4 /mmm tetragonal cell with lattice parameters a = 3.88 ˚ A and c = 11.74 ˚ A at 300 K. The vectors i j and k are the fundamental translation unit vectors in real space. For comparison with the AFM low temperature orthorhom- II. EXPERIMENTAL PROCEDURES FIG. 2: Temperature evolution of the neutron scattering signal measured on HB3 at ¯ hω = 10 meV. (a) Background estimate measured away from Q AFM at (002) (solid symbols) and (003) (open symbols) showing no anomaly at T$_{N}$ . Solid lines are lin- ear fits to the temperature dependent intensity. (b) Intensity at Q AFM = (1 / 2 1 / 2 1) and (1 / 2 1 / 2 0). The solid line is the non-magnetic background estimate obtained from averaging the fits at (002) and (003) shown in panel (a). FIG. 1: Summary of scans performed at T = 10 K 140 K (empty symbols) and 180 K (filled symbols) on HB3 ( E$_{f}$ = 41.2 meV) and HB-1A with spectrometer configurations described in the text. (a) shows ( hhL ) plane in reciprocal space where the scans at HB3 were performed. (b)-(f) shows the various cuts investigated as indicated in (a). (g) and (h) show the scans performed in the ( h 0 L ) plane using HB1A. No diffuse magnetic scattering was observed in the ( h 0 L ) plane. The magnetic signal is only observed centered at wavevectors Q = Q AFM .
5scientific_articles
3 breaking factor. Indeed at the field of 0.16 T where the first minimum at Φ$_{0}$ is expected in the Fraunhofer interference pattern the magnetic length ξ B is as large as 110 nm and thus comparable to the junction width. For sample B a similar dependence of I c on B is ob- served with a full suppression of I c at 0.2 T. By using the model of Hammer et al. 16 for the the case of low transparent junctions we calculated the expected depen- dence of I c on B for E ∗ Th = 0 . 15 meV. As can be seen in Fig. 3(b) a reasonable agreement between experiment and theory is obtained. The same is true for sample B with E ∗ Th = 0 . 7 meV [cf. Fig. 3(b) inset]. A possi- ble reason for the discrepancy between the experimental values and theoretical curves might be that in our InN nanowires the current flows mainly in the surface accu- mulation layer which leads to an inhomogeneous current distribution. In summary superconducting Nb/InN-nanowire/Nb junctions with large critical currents up to 5.7 µ A and large I c R N products up to 0.44 mV have been fabricated. Owing to the small width of nanowires a monotonous decrease of I c with B was observed since in this case the magnetic field is the main pair breaking factor. The present results suggest that Nb/InN-nanowire/Nb struc- tures are well suited for fundamental research and appli- cation in nano-scaled Josephson junction-based devices. We are grateful to A. A. Golubov (Twente Univer- sity The Netherlands) and V. V. Ryazanov (Institute of Solid State Physics RAS Chernogolovka) for fruitful discussions and H. Kertz for support during the measure- ments. I.E.B. acknowledges the Russian Foundation for Basic Research: project RFBR 09-02-01499 for financial support. supercurrent is completely suppressed. In contrast to wide S/semiconductor/S Josephson junctions 27 no Fraunhofer-type interference pattern of I c ( B ) is ob- served. The absence of a magnetic interference pattern in SNS structures was first observed by Anger et al. 28 and theoretically explained by Hammer et al. 16 and Cuevas and Bergeret. 17 The reason for the monotonous decay of I c is that for junctions with a width smaller than the magnetic length ξ B the magnetic field acts as a pair- FIG. 3: (Color online) (a) I c ( ◦ ) and I r ( □ ) vs. T of sam- ple A. The dashed line represents the calculated values fol- lowing Ref. [16]. (b) I c as a function of B of sample A. The dashed line corresponds to the calculated I c ( B ) dependence following Ref. [16]. The inset shows the corresponding values for sample B. GLYPH<s49> GLYPH<s50> GLYPH<s51> GLYPH<s52> GLYPH<s48> GLYPH<s49> GLYPH<s50> GLYPH<s51> GLYPH<s52> GLYPH<s53> GLYPH<s54> GLYPH<s48>GLYPH<s46> GLYPH<s48> GLYPH<s48>GLYPH<s46> GLYPH<s50> GLYPH<s48>GLYPH<s46> GLYPH<s52> GLYPH<s48>GLYPH<s46> GLYPH<s54> GLYPH<s48> GLYPH<s49> GLYPH<s50> GLYPH<s51> GLYPH<s48>GLYPH<s46>GLYPH<s48> GLYPH<s48>GLYPH<s46>GLYPH<s49> GLYPH<s48>GLYPH<s46>GLYPH<s50> GLYPH<s48>GLYPH<s46>GLYPH<s48> GLYPH<s48>GLYPH<s46>GLYPH<s49> GLYPH<s48>GLYPH<s46>GLYPH<s50> GLYPH<s48>GLYPH<s46>GLYPH<s51> GLYPH<s48>GLYPH<s46>GLYPH<s52> GLYPH<s115>GLYPH<s97>GLYPH<s109>GLYPH<s112>GLYPH<s108>GLYPH<s101>GLYPH<s32>GLYPH<s65> GLYPH<s115>GLYPH<s97>GLYPH<s109>GLYPH<s112>GLYPH<s108>GLYPH<s101>GLYPH<s32>GLYPH<s65> GLYPH<s84> GLYPH<s61>GLYPH<s50>GLYPH<s46>GLYPH<s48>GLYPH<s32>GLYPH<s75> GLYPH<s73> GLYPH<s114> GLYPH<s73> GLYPH<s99> GLYPH<s32> GLYPH<s73>GLYPH<s32>GLYPH<s40> GLYPH<s65>GLYPH<s41> GLYPH<s84> GLYPH<s101>GLYPH<s109>GLYPH<s112>GLYPH<s101>GLYPH<s114>GLYPH<s97>GLYPH<s116>GLYPH<s117>GLYPH<s114>GLYPH<s101>GLYPH<s32>GLYPH<s40>GLYPH<s75>GLYPH<s41> GLYPH<s66>GLYPH<s61>GLYPH<s48> GLYPH<s40> GLYPH<s97>GLYPH<s41> GLYPH<s73> GLYPH<s99> GLYPH<s32>GLYPH<s40> GLYPH<s65>GLYPH<s41> GLYPH<s66>GLYPH<s32>GLYPH<s40>GLYPH<s84> GLYPH<s41> GLYPH<s40> GLYPH<s98>GLYPH<s41> GLYPH<s115>GLYPH<s97>GLYPH<s109> GLYPH<s112>GLYPH<s108>GLYPH<s101>GLYPH<s32>GLYPH<s66> GLYPH<s84> GLYPH<s61>GLYPH<s48>GLYPH<s46>GLYPH<s55>GLYPH<s32>GLYPH<s75> GLYPH<s32> GLYPH<s66>GLYPH<s40> GLYPH<s84> GLYPH<s41> GLYPH<s32> GLYPH<s73> GLYPH<s99> GLYPH<s32> GLYPH<s40> GLYPH<s181>GLYPH<s65> GLYPH<s41> 16 J. C. Hammer J. C. Cuevas F. S. Bergeret and W. Belzig Phys. Rev. B 76 064514 (2007). 15 T. Richter Ch. Bl¨ omers H. L¨ uth R. Calarco M. In- dlekofer M. Marso and Th. Sch¨ apers Nano Lett. 8 2834 (2008). 14 R. Calarco and M. Marso Appl. Phys. A 87 499 (2007). 13 F. Werner F. Limbach M. Carsten C. Denker J. Malin- dretos and A. Rizzi Nano Lett. 9 1567 (2009). 12 C.-Y. Chang G.-C. Chi W.-M. Wang L.-C. Chen K.-H. Chen F. Ren and S. J. Pearton Appl. Phys. Lett. 87 093112 (2005). 8 C. Thelander P. Agarwal S. Brongersma J. Eymery L. Feiner A. Forchel M. Scheffler W. Riess B. Ohlsson 7 I. E. Batov T. Sch¨ apers N. M. Chtchelkatchev H. Hardt- degen and A. V. Ustinov Phys. Rev. B 76 115313 (2007). 6 J. Eroms D. Weiss J. D. Boeck G. Borghs and U. Z¨ ulicke Phys. Rev. Lett. 95 107001/1 (2005). 5 I. E. Batov Th. Sch¨ apers A. A. Golubov and A. V. Usti- nov J. Appl. Phys. 96 3366 (2004). 4 H. Takayanagi T. Akazaki and J. Nitta Phys. Rev. Lett. 75 3533 (1995). 3 T. Akazaki H. Takayanagi J. Nitta and T. Enoki Appl. Phys. Lett. 68 418 (1996). 2 T. Sch¨ apers Superconductor/Semiconductor Junctions vol. 174 of Springer Tracts on Modern Physics (Springer- Verlag Berlin Heidelberg 2001). 1 A. A. Golubov M. Y. Kupriyanov and E. Il’ichev Rev. Mod. Phys. 76 411 (2004). ‡ Electronic address: th.schaepers@fz-juelich.de † Nanoelektronik Technische Fakult¨ at Christian-Albrechts- Universit¨ at zu Kiel 24143 Kiel Germany ∗ Current address: Physics Department University of Cali- fornia Santa Barbara 93106 Santa Barbara CA USA 9 J. A. van Dam Y. V. Nazarov E. P. A. M. Bakkers S. D. Franceschi and L. P. Kouwenhoven Nature 442 667 (2006). 10 Y.-J. Doh J. A. van Dam A. L. Roest E. P. A. M. Bakkers L. P. Kouwenhoven and S. D. Franceschi Sci- ence 309 272 (2005). 11 T. Sand-Jespersen J. Paaske B. M. Andersen K. Grove- Rasmussen H. I. Jørgensen M. Aagesen C. B. Sørensen P. E. Lindelof K. Flensberg and J. Nyg˚ ard Phys. Rev. Lett. 99 126603 (2007) . U. G¨ osele et al. Materials Today 9 28 (2006).
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3 ¯ hv ∼ e 2 we can rewrite this second condition simply as l$_{E}$ ≪ d . Thus the Thomas-Fermi equation (9) for the equilibrium charge density and the hydrodynamic equa- tion (5) for its variation are applicable as long as flake is not useful. Instead the equation for the n -th fre- quency gap can be obtained by setting q = 0 in Eq. (5). We observe that where β$_{n}$ are the eigenvalues of the equation ω 2 $_{n}$(0) = β$_{n}$ e $^{2}$v ¯ hl$_{E}$d (15) l$_{E}$ ≪ d q ≪ 1 /l$_{E}$. (10) 2 √$_{π}$ d dξ √ | ξ | (1 − ξ $^{2}$)1 / 4 ∫ 1 − 1 dξ $_{′}$δρ ( n $^{)}$( ξ $^{′}$) ξ − ξ ′ = β$_{n}$δρ ( n $^{)}$( ξ ) . (16) ρ$_{0}$ ( x ) = E$_{0}$x √$_{d}$ 2 − x $_{2}$. (11) β$_{1}$ = 1 . 41 β$_{2}$ = 6 . 49 β$_{3}$ = 6 . 75 ... (17) However the ratio of q and 1 /d can be arbitrary. For a moderate external electric field ∼ 10 $^{4}$V/m the value of electric length l$_{E}$ ∼ 0 . 4 µ m and the first of the conditions (10) is satisfied easily for micron-sized samples. Analytic solution of Eq. (9) is possible when the second term is small in which case the charge density is [15] The zeroth mode β$_{0}$ = 0 see Eq. (14) is found ana- lytically: δρ (0) ∝ 1 / √ 1 − ξ $^{2}$. It describes charge dis- tribution in the strip in response to a (uniform along x direction and smooth along y -direction) change of its chemical potential [16]. Other solutions of Eq. (16) are found numerically: Substituting this expression back into Eq. (9) we ob- serve that the second term is indeed negligible as long as x ≫ l 2 $_{E}$/d . This is assured whenever the condi- tions (10) are satisfied. It is also worth pointing out that Eq. (11) justifies the linear approximation for the charge density used in deriving Eq. (1) for q ≫ 1 /d with ρ ′ $_{0}$/e = 1 / ( l 2 $_{E}$d ). With increasing n the eigenmodes of integro-differential equation (16) oscillate faster but in general do not follow the oscillation theorem familiar from quantum mechan- ics. In particular the solutions with n = 0 and n = 3 are even while n = 1 n = 2 are odd [17]. We now turn to the analysis of plasma oscillations propagating on top of the density distribution Eq. (11). For small plasmon momenta q ≪ 1 /d electric field ex- tends beyond the width of the flake and the equation (5) needs to be supplemented with the boundary condition which ensures that electric field (and thus the current) vanishes at the edges x = ± d : Finally we mention the case of a gate-controlled p - n junction Fig. 1b. The equilibrium density profile is linear near x = 0 and saturates for large | x | [18]. Eq. (1) is still applicable for q > 1 /d . In the limit q < 1 /d one should take into account the screening of long-range Coulomb interaction by metallic gates. In this case the logarithm in the spectrum of the gapless plasmon disappears and the lowest mode Eq. (14) becomes sound-like. Magnetoplasmons. If external magnetic field B is ap- plied perpendicularly to the plane of graphene the plas- mon spectra acquire new modes. The equation of motion (2) should now be modified to include the Lorentz force P ∫ d − d dx δρ ( x ) x ± d = 0 . (12) ˙ J ( r t ) = e 2 π ¯ h 2 | µ ( x ) | E ( r t ) − ev 2 cµ ( x ) J × B . (18) The spectrum of the lowest symmetric mode can be most easily found by integrating Eq. (5) across the width of the flake. The first term in the brackets will then van- ish exactly due to the boundary condition (12). The remaining integral can now be calculated to the log- arithmic accuracy with the help of the approximation K$_{0}$ ( q | x − x $^{′}$| ) = − ln q | x − x $^{′}$| : ∫ d − d dx √ | ρ$_{0}$ ( x ) | e ln ( q | x − x $^{′}$| ) ≈ 2 d Γ $^{2}$(3 / 4) $_{l$_{E}$}$√$_{π}$ ln ( qd ) . (13) Eqs. (5) and (13) combine to give the equation [ ω 2 − ω 2 $_{0}$( q )] ∫ d − $_{d}$dxδρ ( x ) = 0 that yields the dispersion of the gapless symmetric plasmon reminiscent of the plasmon spectrum in quasi-one- dimensional wires The remaining modes n ≥ 1 are gapped. For these modes ∫ d − $_{d}$dxδρ ( x ) = 0 and simple procedure of integrating Eq. (5) over the width of the ω 2 $_{0}$( q ) = Γ $^{2}$(3 / 4) 4 e $^{2}$vd π ¯ hl$_{E}$ q $^{2}$ln (1 /qd ) (14) δρ ( x ) + 2 e 2 π { q $^{2}$Z − q ω ( ω$_{B}$ Z ) ′ − d dx Z d dx } × ∫ d − d dx $^{′}$δρ ( x $^{′}$) K$_{0}$ ( | q || x − x $^{′}$| ) = 0 (19) The relative coefficient between electric and magnetic terms in this equation follows from the expression for the Lorentz force acting on a single particle. The last term has opposite sign for electrons and holes. Note that the frequency of cyclotron motion ω$_{B}$ ( x ) = ev $^{2}$B/cµ ( x ) in graphene p - n junctions is position-dependent. The remaining equations (3)-(4) are intact in the presence of magnetic field. The boundary condition requires now the vanishing of the normal component of electric current at the boundary rather than simply vanishing of the elec- tric field as in Eq. (12). Eliminating J and E we arrive at the generalization of equation (5)
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42 of 124 Construction of Giresun Wastewater Treatment Plant Tender Dossier Volume 3 Employer’s Requirements Section 08: Electrical Works Level transmitters shall be provided for non-contact continuously measuring of liquid levels. Maximum measuring range shall be suitable max. 30 m. Measuring principle shall be operating based on the time-of-flight method. The sensor shall be suitable for installation in wastewater/sludge and the sensor house shall be made of 316 L or similar material. The housing shall be in protection class IP68. Common communication protocols and interfaces such as 0/4...20 mA and Ethernet or 0/4…20mA/HART shall be integrated. The compensation shall be electronic. The accuracy of the level measuring system shall as a minimum be 2 mm of the full scale. The full scale shall be selected according to the location of the level measuring. Device shall have an integrated overvoltage protection. Detector will be appropriate to be mounted in an open or covered tank and completely covered and protected against water that may reach on itself IP68 rate protected from environmental effects. Control units must have independent balancing features between zero and certain interval and its output must be between (4-20 mA) as proportional with the level. General accuracy of the measurement device must not be higher than (±2 mm) of the measurement device level indicator. The connection between the detector and control units must be shielded type cable that is available in the market and equipment must be able to operate with cables up to 60 meters. Material process connection shall be PVDF. Antenna diameter shall be in 40 mm and its shape shall be horn antenna. 8.8.12 Hydrostatic Level Measurement Level transmitters shall be provided for continuously measuring of water levels and for control of the machinery. Analogue level measuring shall be based on the hydrostatic measuring principle based on the pressure generated by the height of a liquid column. The pressure acting on the pressure-measuring cell built-in the sensor shall be converted into a level-proportional electrical signal. The sensor shall be suitable for installation in wastewater/sludge and the sensor house shall be made of 316 L or similar material. The housing shall be in protection class IP68. The level transmitter shall provide the PLC with a 4-20 mA level proportional signal and additionally provide the sensor with the necessary power supply. The transmitter shall automatically compensate for the atmospheric pressure. The compensation shall be electronic. The accuracy of the level measuring system shall as a minimum be (±0.2%) of the full scale. The full scale shall be selected according to the location of the level measuring. The linearity shall be better than 1%. It shall be possible to change the full scale for the sensor by using a special programming device connected to the sensor. Device shall have an integral overvoltage protection. Alternatively level measurement will be performed by contact free echo time measurement device that operates at ultrasonic frequency at locations where required. Equipment will transmit the vibration that is reflected to the detector from the surface of the liquid that is being measured. Equipment will be consisted of separate control system and a detector that has transmitter and receiver. Equipment will be provided with automatic temperature balancing mechanism and will comply with the approved design for operation under defined weather conditions. 8_Vol3_d4 3_Section 8 electrical works_en_GIR rev6.doc
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5 4 3 πp 3 $_{F}$n ( p ) → ∫ d $^{3}$r 4 3 πp 3 F n$_{NM}$ [ ρ ( r ) p ] ρ$_{A}$ ( r ) (17) S$_{PWIA}$ ( q ω ) = ∫ d $^{3}$p dE P$_{h}$ ( p E ) [ 1 − 4 π 3 p 3 F n ( p + q ) ] × δ ( ω − E − | p + q | 2 2 M ) (18) It has to be pointed out that the above prescriptions while being justified in the case of uniform nuclear mat- ter are questionable when applied to nuclei. In nuclear matter due to translation invariance the linear momen- tum is a good quantum number that can be used to label single particle states. As a consequence the momentum distribution also provides the occupation probability of the states. In finite nuclei on the other hand single particle states must be labeled according to the total an- gular momentum J . In this case for any given p n ( p ) receives contributions from states of different J and may even exceed unity. The available results of accurate nuclear matter calcu- lations can be used to model the particle spectral function of finite nuclei within the framework of the local density approximation [5] i.e. using the definition of Eq. (14) with where ρ$_{A}$ ( r ) is the nuclear density distribution normal- ized to unity and n$_{NM}$ [ ρ ( r ) p ] is the momentum distri- bution of nuclear matter at uniform density ρ ( r ). This procedure has been used in all calculations of nuclear cross sections discussed in this paper. Within the nonrelativistic approximation in which both the response and the hole spectral function can be evaluated using realistic nuclear Hamiltonians the valid- ity of the IA can be tested comparing S ( q ω ) of Eq. (10) to FIG. 5. Energy dependence of the nuclear matter response S ( q ω ). Solid lines: correlated Hartree-Fock approxima- tion [6]. Dashed lines: PWIA results obtained from Eq. (18) using the SF of Ref. [7]. Dot-dashed lines: results of the Fermi gas model (with nonrelativistic energies) at k$_{F}$ = 262 . 4 MeV corresponding to the equilibrium density of nuclear matter. The panels are labeled according to the value of | q | . the Fermi gas model with nonrelativistic kinetic energy spectrum are also displayed. for different values of the momentum transfer q . The nuclear matter S ( q ω ) at equilibrium density ρ$_{0}$ = 0 . 16 fm − 3 (corresponding to p$_{F}$ = 262 . 4 MeV) has been recently computed using the correlated basis func- tion formalism and an effective interaction derived from a state-of-the-art parametrization of the nucleon-nucleon potential [6]. To analyze the interplay between short- and long-range correlations the response defined as in Eq. (10) has been evaluated in both the Hartree-Fock and Tamm-Dancoff approximations. The results of Fig. 5 clearly show that at | q | < 2 p$_{F}$ the response obtained from Eq. (18) does not exhibit the linear behavior at low ω resulting from the antisym- metrization of the final state. On the other hand as the momentum transfer increases the PWIA response draws closer to the one obtained in Ref. [6]. At | q | ∼ 600 MeV the results of the two approaches are within 10% of one another in the region of the maximum. Note that inclu- sion of dynamical FSI e.g. according to the approach of Ref. [8] would produce a quenching of the PWIA re- sponse in the top panel of Fig. 5 thus bringing the solid and dashed lines in even better agreement. Theoretical studies of electron-nucleus scattering [15] suggest that at | q | ∼ 600 MeV the FSI effect at the quasifree peak is ∼ 10 %. Figure 5 shows a comparison between the responses of Ref. [6] obtained using Eq. (10) and the correlated Hartree-Fock approximation and those obtained from Eq. (18) using the nuclear matter hole spectral function of Ref. [7]. The main difference between the two calcu- lations lies in the treatment of the target final state. In the IA scheme the state describing the struck particle is factored out while in the approach of Ref. [6] the final A -nucleon state includes both statistical and dynamical correlations between the struck particle and the specta- tors.To make the comparison fully consistent the PWIA response has been computed including only the contribu- tions of one-hole final states to P$_{h}$ ( p E ). The results of The emerging pattern suggests that the assumptions underlying the IA are likely to be valid at momenta larger than ∼ 2 p$_{F}$ while at lower | q | factorization does not ap- pear to provide an adequate description of the final state.
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Distributed Recovery 18.5.3 Distributed Recovery Tip 3736 State transfer from the binary log is Group Replication’s base mechanism for distributed recovery and if the donors and joining members in your replication When the joining member is up to date with all the group’s transactions it is declared online and can participate in the group as a normal member and distributed recovery is complete. Group Replication automatically selects the best combination of these methods for state transfer after you issue START GROUP_REPLICATION on the joining member. To do this Group Replication checks which existing members are suitable as donors how many transactions the joining member needs from a donor and whether any required transactions are no longer present in the binary log files on any group member. If the transaction gap between the joining member and a suitable donor is large or if some required transactions are not in any donor’s binary log files Group Replication begins distributed recovery with a remote cloning operation. If there is not a large transaction gap or if the clone plugin is not installed Group Replication proceeds directly to state transfer from a donor’s binary log. Group Replication uses a combination of these methods for state transfer during distributed recovery: After this the joining member connects to an online existing member to carry out state transfer. The joining member transfers all the transactions that took place in the group before it joined or while it was away which are provided by the existing member (called the donor ). Next the joining member applies the transactions that took place in the group while this state transfer was in progress. When this process is complete the joining member has caught up with the remaining servers in the group and it begins to participate normally in the group. The joining member begins by checking the relay log for its group_replication_applier channel for any transactions that it already received from the group but did not yet apply. If the joining member was in the group previously it might find unapplied transactions from before it left in which case it applies these as a first step. A member that is new to the group does not have anything to apply. Whenever a member joins or rejoins a replication group it must catch up with the transactions that were applied by the group members before it joined or while it was away. This process is called distributed recovery. •A remote cloning operation using the clone plugin’s function which is available from MySQL 8.0.17. To enable this method of state transfer you must install the clone plugin on the group members and the joining member. Group Replication automatically configures the required clone plugin settings and manages the remote cloning operation. •Replicating from a donor’s binary log and applying the transactions on the joining member. This method uses a standard asynchronous replication channel named group_replication_recovery that is established between the donor and the joining member. •During a remote cloning operation the existing data on the joining member is removed and replaced with a copy of the donor’s data. When the remote cloning operation is complete and the joining member has restarted state transfer from a donor’s binary log is carried out to get the transactions that the group applied while the remote cloning operation was in progress. •During state transfer from a donor’s binary log the joining member replicates and applies the required transactions from the donor’s binary log applying the transactions as they are received up to the point where the binary log records that the joining member joined the group (a view change event). While this is in progress the joining member buffers the new transactions that the group applies. When state transfer from the binary log is complete the joining member applies the buffered transactions.
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Europol Public Information • technical and financial tenders against the pre-defined award criteria. • compliance with the minimum requirements; • capacity of the candidate/tenderer to perform the contract against the selection criteria; 6. Award and signature of the contract with the successful tenderer 6.1. Award and notification of the outcomes of the procurement procedure General Guidance on Europol Procurement Procedures Page 16 of 20 Once the award notice is published in the Official Journal of the European Union unsuccessful tenderers may submit a request for a debriefing meeting. However Europol reserves the right to accept or refuse such requests and schedule the meeting date on the basis of the particular circumstances of each individual procurement procedure or of the existing workload. Europol would like to stress that it is not free to disclose any information where such disclosure would hinder the application of the law be contrary to public interest harm the legitimate business interests of public or private undertakings or distort fair competition. After the closing of the tendering procedure and in order to improve the quality of tenders and the quality of our procedures Europol may hold upon request from the unsuccessful tenderers an optional debriefing meeting of its representatives with unsuccessful tenderers aimed at exchanging feedback and suggestions for improvement in view of future procurement procedures. For high value contracts equal to or above the Directive threshold (i.e. 139.000 € for services and supplies) the contract will not be signed for 10 days (standstill period) counting from the day after simultaneous dispatch of the notification by e-mail to all tenderers (successful and unsuccessful). Only after the end of this "standstill period" Europol may sign the contract. The notification will be sent to the e-mail address provided in the request to participate/ tender. The same e-mail address will be used by the contracting authority for all other communications with the candidate/ tenderer. It is the candidate/tenderer’s responsibility to provide a valid e- mail address together with contact details in the request to participate/ tender and to check this e-mail address regularly. Candidates/tenderers will be simultaneously and individually notified by e-mail as soon as possible about the decision taken about their request to participate / tender including the grounds for any decision to not award the contract or to cancel the procedure. Following the finalisation of the evaluation a decision will be taken about the selection of candidates/award of the contract. For the purposes of the evaluation related to exclusion and selection criteria the contracting authority may also refer to publicly available information in particular evidence that it can access on a national database free of charge. The evaluation will be based on the information and evidence contained in the tenders and if applicable on additional information and evidence provided at the request of the contracting authority during the procedure. If any of the declarations or information provided proves to be false the contracting authority may impose administrative sanctions (exclusion or financial penalties) on the entity providing the false declarations/information. A request to participate/tender failing to pass a given category of criteria will not be evaluated under the other categories and the candidate/tenderer will be informed of the ground for rejection without being given feedback on the non-assessed content of the tender.
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“pre–commencement works” means operations on the pre–commencement land only consisting of land preparation environmental surveys and monitoring investigations for the purpose of assessing ground conditions (including the making of trial boreholes) receipt and erection of construction plant and equipment erection of construction welfare facilities erection of any temporary means of enclosure the temporary display of site notices or advertisements and any other works that do not give rise to any likely significant adverse environmental effects as assessed in the environmental statement; “relevant planning authority” means the London Borough of Bexley and any successor to its functions in relation to land in its area and Dartford Borough Council and any successor to its functions in relation to land in its area; “REP and RRRF Application Boundaries Plan” means the plan of that description referred to in Schedule 11 certified by the Secretary of State as the REP and RRRF Application Boundaries Plan for the purposes of this Order; “requirements” means those matters set out in Schedule 2 to this Order; “Riverside Energy Park Limited” means the company of that name (company number 11536739) whose registered address is Level 5 10 Dominion Street London England EC2M 2EF; “RRRF” means the Riverside Energy from Waste Facility known as Riverside Resource Recovery Facility located at Norman Road Belvedere Kent; “RRRF condition” means a condition to the RRRF planning permission and where a condition is referred to by a number that reference is to the corresponding numbered condition on the RRRF planning permission; “RRRF planning permission” means the planning permission granted under the 1990 Act by the relevant planning authority for the RRRF and given reference number 16/02167/FUL; “RRRL” means Riverside Resource Recovery Limited (company number 03723386) whose registered office is at 2 Coldbath Square London EC1R 5HL together with its successors in title of that part of the Order land identified in the book of reference; “section 36 consent” means the consent granted by the Secretary of State pursuant to section 36 (consent required for construction of etc. generating stations) of the Electricity Act 1989( a ) in respect of the RRRF as varied by the Secretary of State on 13 March 2015 under Section 36C (variation of consents under section 36) of that Act and given reference number GDBC/003/00001C–06; “statutory undertaker” means any person falling within section 127(8) (statutory undertakers’ land) of the 2008 Act and includes a public communications provider defined by section 151(1) (interpretation of Chapter I) of the Communications Act 2003( b ); “street” means a street within the meaning of section 48 (streets street works and undertakers) of the 1991 Act together with land on the verge of a street or between two carriageways and includes any footpath and “street” includes any part of a street; “street authority” in relation to a street has the same meaning as in Part 3 of the 1991 Act; “traffic authority” has the same meaning as in section 121A of the Road Traffic Regulation Act 1984; “transport assessment” means the document of that description referred to in Schedule 11 certified by the Secretary of State as the transport assessment for the purposes of this Order; “Transport for London” means the body corporate established under section 154 (establishment) of the Greater London Authority Act 1999 of 55 Broadway London SW1H 0BL and any successor to its functions in relation to streets within the London Borough of Bexley; a ) 1989 c.29 b ) 2003 c.21 7
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Management’s Discussion and Analysis of Results of Oper ations and Financial Condition Long-Term Financing Marketable Equity Securities and Forward Contracts In December 2003 U.S. Cellular sold $444 million of 6.7% Senior Notes. Interest is payable semi-annually. These Notes may be redeemed in whole or in part at any time prior to maturity at a redemption price equal to the greater of (a) 100% of the principal amount of such notes plus accrued but unpaid interest or (b) the sum of the present values of the remaining scheduled payments of principal and interest thereon discounted to the redemption date on a semi-annual basis at the Treasury Rate plus .30%. U.S. Cellular and its subsidiaries hold a substantial amount of mar- ketable equity securities that are publicly traded and can have volatile ments in publicly traded companies and all of these interests were acquired as a result of sales trades or reorganizations of other assets. The investment in Vodafone resulted from certain sales or trades of non-strategic cellular investments to or settlements with AirTouch Communications in exchange for stock of AirTouch which was then acquired by Vodafone for American Depositary Receipts representing Vodafone stock. The investment in Rural Cellular Corporation is the share prices. U.S. Cellular and its subsidiaries do not make direct invest- In November 2002 U.S. Cellular sold $130 million of 8.75% Senior Notes. Interest is payable quarterly. These Notes are callable by U.S. Cellular at the principal amount plus accrued and unpaid interest at any time on and after November 7 2007. U.S. Cellular’s interest costs related to the revolving credit facility would increase if its credit rating goes down which would increase its cost of financing but the facility would not cease to be available solely as a result of a decline in its credit rating. A downgrade in U.S. Cellular’s credit rating could adversely affect its ability to renew existing or obtain access to new credit facilities in the future. In August 2002 U.S. Cellular issued the $175 million principal amount of 9% Series A Notes in conjunction with the acquisition of USCOC of Chicago. These Notes were originally issued in a private placement to the parties who sold USCOC of Chicago to U.S. Cellular and were due in August 2032. In November 2002 U.S. Cellular repurchased $129.8 million of the 9% Series A Notes with the proceeds of its 8.75% Senior Notes issuance. In January 2003 U.S. Cellular repurchased the remaining $45.2 million of the 9% Series A Notes with borrowings from its revolving credit facilities. As a result of these repurchases the 9% Series A Notes have been cancelled. The restatements of the financial statements for the years ended December 31 2003 and 2002 resulted in defaults under the revolving credit agreement between U.S. Cellular and certain lenders. U.S. Cellular has not failed to make nor expects to fail to make any scheduled payment of principal or interest under such revolving credit agreement. U.S. Cellular has received waivers from the lenders under which the lenders agreed to waive any defaults that may have occurred as a result of the restatements. The continued availability of the revolving credit facility requires U.S. Cellular to comply with certain negative and affirmative covenants maintain certain financial ratios and to represent certain matters at the time of each borrowing. The restatements of the financial statements for the years ended December 31 2003 and 2002 resulted in defaults under certain forward contracts between a subsidiary of U.S. Cellular and a counterparty. U.S. Cellular has not failed to make nor expects to fail to make any scheduled payment of principal or interest under such forward con- tracts. U.S. Cellular and its subsidiaries have received waivers from the counterparty under which the counterparty agreed to waive any defaults that may have occurred as a result of the restatements. result of a consolidation of several cellular partnerships in which U.S. Cellular subsidiaries held interests in Rural Cellular Corporation and the distribution of Rural Cellular Corporation stock in exchange for these interests. U.S. Cellular has not disposed of the investments because their low tax basis would trigger a substantial taxable gain upon disposal. U.S. Cellular and its subsidiaries have entered into a number of variable prepaid forward contracts (“forward contracts”) related to the mar- ketable equity securities that they hold. The forward contracts mature in May 2007 and at U.S. Cellular’s option may be settled in shares of the respective security or cash. U.S. Cellular has provided guarantees to the lenders which provide assurance to the lenders that all principal and interest amounts are paid upon settlement of the contracts by its sub- sidiary. If shares are delivered in the settlement of the forward contract U.S. Cellular would incur a current tax liability at the time of delivery based on the difference between the tax basis of the marketable equity securities delivered and the net amount realized through maturity. Deferred taxes have been provided for the difference between the financial reporting basis and the income tax basis of the marketable equity securities and are included in deferred tax liabilities on the balance sheet. As of December 31 2003 such deferred tax liabilities totaled $86.3 million. U.S. Cellular is generating cash from its operations and anticipates financing the 2004 obligations listed above with internally generated cash and with borrowings under its revolving credit facilities as the timing of such expenditures warrants. U.S. Cellular had $9.8 million of cash and cash equivalents at December 31 2003. At December 31 2002 and up until December 23 2003 U.S. Cellular had a $500 million revolving credit facility with a group of banks. This credit facility was terminated on December 23 2003 in connection with the amendment of U.S. Cellular’s $325 million credit facility to $700 million discussed above. Borrowings under this facility accrued interest at the LIBOR rate plus 19.5 basis points. Other terms of this facility were similar to those in the recently amended facility discussed above. LIBOR rate at December 31 2003). Interest and principal are due the last day of the borrowing period as selected by the borrower of either seven days or one two three or six months; any borrowings made under the facility are short-term in nature and automatically renew until they are repaid. U.S. Cellular pays annual facility and administrative fees in addition to interest on any borrowings; these fees are recorded as interest expense. As of December 31 2003 U.S. Cellular had $699.8 million available net of outstanding letters of credit of $0.2 million. In February 2004 U.S. Cellular repaid the entire $105 million Intercompany Note plus accrued interest of $1 million to TDS using cash borrowed under the revolving credit facility. 33
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Management’s Discussion and Analysis of Results of Operations and Financial Condition Revenues for EMCOR’s United States electrical construction and facilities services segment for 2000 increased by $357.6 million or 36.0% compared to 1999. The increase in revenues was due to favorable market conditions for most of the business units in the segment and was primarily attributable to both new construction and renovation and retrofit jobs for commercial construction and the communication infrastructure and technology markets. Offsetting this overall increase was a decrease in new construction revenues for casino work although this was partially offset by increased renovation and retrofit casino work. Additionally certain industrial construction related renovation and retrofit revenues decreased principally due to these facilities not having as many shut-downs in production to perform major maintenance during 2000. The $104.5 million or 11.8% increase in 1999 revenues compared to 1998 was attributable to $23.0 million of revenues from companies acquired during 1999 and 1998 and $81.5 million or a 9.2% increase due to growth from the balance of EMCOR’s United States electrical construction and facilities services businesses. United States mechanical construction and facilities services revenues increased $200.0 million or 19.0%. The increase in revenues was primarily attributable to revenue growth from EMCOR’s operations excluding acquisitions. Revenues from the impact of 1999 acquisitions contributed toward approximately $77.5 million of the increase. Eastern and Western United States based operations were the major contributors to the increase in revenue due to the continued strong renovation market and new construction markets in New York City Houston Connecticut Denver and California. A $454.1 million or 75.7% increase in revenues for 1999 compared to 1998 was attributable to $377.5 million of revenues related to 1999 and 1998 acquisitions and $76.6 million of the increase in revenues or a 12.8% increase was due to growth from the balance of EMCOR’s United States mechanical construction and facilities services. United States other revenues increased by $76.1 million for 2000 compared to 1999. The primary source of the increase in 2000 was revenues of $68.6 million from BTENA and companies acquired during 1999 as well as increases from the balance of EMCOR’s other United States operations. Revenues for 1999 Revenues of the Other international construction and facilities services decreased for 2000 to $0.3 million compared to $0.6 million for 1999 and $12.6 million for 1998. Other international construction and facilities services primarily consist of EMCOR’s operations in the Middle East. Substantially all of the current projects in this operating segment are being performed by joint ventures and accordingly no revenue attributable to such joint ventures was recorded. In 1999 several projects in which EMCOR had majority ownership were completed. EMCOR continues to pursue new business selectively in these markets; however the availability of opportunities has been significantly reduced as a result of local economic factors. EMCOR 2000 Annual Report 18 increased by $81.8 million versus 1998 primarily attributable to revenues of $75.6 million from companies acquired during 1999 and 1998 and revenues from the balance of EMCOR’s United States other operations. Revenues of Canada construction and facilities services increased by $40.3 million or 20.5% for 2000 as compared to 1999 revenues. The increase in revenues for 2000 compared with 1999 was primarily due to an increased level of activities in Eastern Canada especially in the second half of 2000. The $5.2 million or 2.6% decrease in revenues for 1999 compared with 1998 was attributable to a reduced level of activities in Eastern Canada and from delays during 1999 in the commencement of certain projects caused by delays in the bidding process for certain jobs. United Kingdom construction and facilities services revenues decreased $107.5 million or 19.4% for 2000 compared to 1999 revenues principally due to the completion of the Jubilee Line project in London at the end of 1999. The $60.4 million or 12.2% increase in 1999 revenues compared with 1998 revenues was attributable to continued growth in selected construction and facilities markets combined with an increase in revenues associated with two major projects.
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8464ch09_Oper.fm Draft Document for Review February 7 2020 3:15 pm GLYPH<SM590000> InfoCenter Settings: Use this window to upload a new TS7700 IBM Knowledge Center to the cluster’s MI. Note: Although the term InfoCenter is still used in the interface of the product the term IBM Knowledge Center is the current correct term. Figure 9-72 shows the Security Settings window which is the entry point to enabling security policies. Security Settings window To modify the maximum idle time select values from the Hours and Minutes menus and click Submit Changes . The following parameters are valid for Hours and Minutes: GLYPH<SM590000> Session Timeout: This setting is defined from the Security Settings window. The user can specify the number of hours and minutes that the management interface can be idle before the current session expires and the user is redirected to the login page. – Hours: The number of hours the MI can be idle before the current session expires. Possible values for this field are 00 - 23. – Minutes: The number of minutes the MI can be idle before the current session expires. Possible values for this field are 00 - 55 selected in 5-minute increments. GLYPH<SM590000> SSL settings: Use this section to set the SSL/TLS level. Two choices are available: TLS 1.0 (transition) and TLS 1.2 (strict). The default setting is TLS 1.0. This page allows you to change the following settings: Figure 9-72 TS7700 Security Settings 464 IBM TS7700 Release 5.0 Guide
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3.6 Use cases driving hybrid and multicloud adoption 3.6.1 Multicloud strategy 3.6.2 Cloud bursting and scalability 3.6.3 Disaster recovery 3.6.4 Application affinity 3.6.5 Regional flexibility 3.6.6 Geographical high availability Chapter 3. Agile integration: Capability perspectives 83 Here are some use cases to review by clients considering hybrid or multicloud adoption. Customers want to use the strength and unique offerings from different cloud vendors but also want to have a consistent operation and runtime environment so that they can achieve portability without cloud platform lock-in. If you have private cloud environments running on-premises and want to expand the cluster or private cloud to an external infrastructure only in certain special conditions (such as load testing) or for a bursting workload hybrid and multicloud topologies can meet these needs. Because the same workload can be easily and quickly provisioned external cloud providers can be a great place to act as a disaster recovery (DR) data center. Generally API back ends are distributed across multiple on-premises and off-premises clouds. Therefore you should prefer to deploy APIs near systems of records to reduce latency. Exposing APIs from different geographical areas can expand your business into new regions because customers expect fast response (low latency) and secure access to APIs from anywhere in the world. Geographical distribution of API requests from a physically closer cloud unit reduces latency and ensures adherence to local policies that require certain data to be physically present within the area or country. There is a limited value in deploying APIs to another region if the back-end application is not present in that region or consumers accessing APIs from different regions. In that respect geographical HA targets both application affinity and regional flexibility concerns and increases global availability profile and performance of APIs.
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information criterion. J. Am. Statist. Ass. 105 312–323. 33
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notes to the financial statements for the year ended 30 June 2001 27. SEGMENT INFORMATION 30. ECONOMIC DEPENDENCY Information concerning the classification of securities 58 The consolidated entity operates in one geographic segment in Victoria Australia and one industry segment being the design construction and operation of the Melbourne City Link. Consolidated Parent Entity 2001 2000 2001 2000 $’000 $’000 $’000 $’000 28. RECONCILIATION OF OPERATING LOSS AFTER INCOME TAX TO NET CASH FLOW FROM OPERATING ACTIVITIES Operating loss after income tax (221 382) (163 358) (221 801) (164 007) Depreciation and amortisation 86 830 42 633 86 267 42 633 (Increase)/Decrease in prepayments (693) 920 (693) 920 Increase in creditors 11 955 7 959 12 387 7 529 (Increase) in debtors (13 287) (6 313) (13 313) (6 313) Revaluation of Concession Notes 21 429 11 665 21 429 11 665 Increase in provisions 1 763 660 1 763 660 Increase in Loans 217 724 - 217 724 - Net cash inflow/(outflow) from operating activities 104 339 (105 834) 103 763 (106 913) 29. EARNINGS PER SHARE Basic earnings per share (43 cents) (34 cents) Diluted earnings per share (43 cents) (34 cents) Weighted average number of Stapled Securities used as the denominator in calculating basic earnings per Stapled Security 510 000 000 486 191 781 Weighted average number of Stapled Securities and potential Stapled Securities used as the denominator in calculating diluted earnings per Stapled Security 510 476 438 486 191 781 All shares are fully paid. They carry the right to participate in distributions and have been included in the determination of basic and diluted earnings per share. Options granted to executives under the Transurban Executive Option Plan are considered to be potential shares and have been included in the determination of diluted earnings per shares. The options have not been included in the determination of basic earnings per share. (a) Shares (b) Options The consolidated entity is reliant on the Trust for the ongoing funding of operations.
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IaaS service because building out a full infrastructure for unpredictable requirements isn’t economical. In the case of PaaS companies find that PaaS can offer value during development and deployment instead of having to purchase many different tools. By providing the underlying software infrastructure PaaS can reduce organizational costs. PaaS reduces many of the costs involved with the traditional application development and deployment model including server and storage overhead operating systems workload and performance management software network bandwidth software maintenance and support personnel. However there are also some indirect value drivers for PaaS. These include These materials are the copyright of John Wiley & Sons Inc. and any dissemination distribution or unauthorized use is strictly prohibited. ✓ Lowering skill requirements: Perhaps only one or two people in an organization have the skills necessary to work with a certain kind of middleware. By providing the development tools and middleware PaaS lowers the skill level required to deploy applications and removes the bottleneck that can form waiting for one specific person’s assistance. ✓ Reducing careless mistakes: Mistakes such as someone forgetting to load a configuration file can take a week before the problem is identified. Such mistakes add up to time and money wasted and cause deployment delays. With PaaS such mistakes are reduced because the platform has been tested and is known to work. These successful and well-understood patterns are an important benefit of a PaaS. ✓ Some organizations are using IaaS for cloudbursting when there are unexpected or planned high-load periods. The flexibility of using IaaS means that the company doesn’t have to overinvest in hardware. These companies must be able to adapt to higher loads to protect themselves. ✓ Organizations may have a continuing need for additional compute or storage resources over time and can use a private IaaS to make those resources available on demand for a variety of projects. For example additional public or private resources may be required as hardware reaches end-of-service life. Cloud Services For Dummies IBM Limited Edition 28
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Institutional declaration of interests available here In case of a group of economic operators and/or in case of subcontracting such declaration will need to be completed separately and submitted for each partner and for each identified subcontractor and; Individual declarations of interests available here for the following proposed project team members: Account manager back-up account manager project managers. For all the other profiles the DoI will be requested at contract implementation stage prior and as a condition to the signature of the related specific contract/order form. Institutional and Individual DoIs do not need to be provided with your offer. The requirement to submit Institutional and Individual DoIs will be specified in the award letter and will have to be provided and assessed by the EFSA Authorising Officer before and as a condition of contract signature. Please refer to EFSA’s policy on independence and the Decision of the Executive Director on Competing Interest Management for detailed information. With the exception of declarations of interest evidence must be included in the offer for partners in a joint offer and/or subcontractors only if the capacity of those entities is necessary to satisfy the minimum economic financial technical and professional capacity requirements. If any of the declarations or information provided proves to be false EFSA may impose administrative sanctions (exclusion or financial penalties) on the entity providing the false declarations/information. For the purposes of the evaluation related to exclusion and selection criteria EFSA may also refer to publicly available information in particular evidence that it can access on a national database free of charge. Your offer will be assessed for compliance with the tender specifications before its assessment against the award criteria. Tenders that do not comply with the tender specifications will be rejected if they: 2.5 COMPLIANCE WITH TENDER SPECIFICATION AND MINIMUM REQUIREMENTS  do not comply with minimum requirements laid down in the tender specifications; propose a solution different from the one imposed;  propose a price above the fixed maximum set in the specifications including Annex 1 (financial offer template);  are submitted as variants when the specifications do not authorise them; do not comply with applicable obligations under environmental social and labour law established by Union law national law and collective agreements or by the international environmental social and labour law provisions listed in Annex X to Directive 2014/24/EU 8 and compliance with data protection obligations resulting from Regulation (EU) 2016/679 and Regulation (EU) 2018/1725 9 . 22 8 OJ L 94 of 28.03.2014 p. 65 9 Regulation (EU) 2018/1725 of the European Parliament and of the Council of 23 October 2018 on the protection of individuals with regard to the processing of personal data by the Union institutions bodies offices and agencies and on the free movement of such data and repealing Regulation (EC) No 45/2001 and Decision No 1247/2002/EC OJ L 295/39 21.11.2018 https://eur-lex.europa.eu/legal- content/EN/TXT/PDF/?uri=CELEX:32018R1725&from=EN
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The corresponding contributions of the screened VP diagrams depicted in Fig. 2(d)-(f) are where U$_{VP}$ denotes the VP potential and I$_{VP}$ (Δ) is the interelectronic-interaction operator modified by the electron-loop. For the renormalization of the expressions (23)-(26) we refer to the works [5 65]. Accordingly these contributions are divided into the Uehling and Wichmann-Kroll parts. The renormalized Uehling parts of the VP operators U$_{VP}$ and I$_{VP}$ (Δ) are given by the expressions (see e.g. Ref. [5]) where the density ρ$_{eff}$ is related to the nuclear binding and local screening potentials via the Poisson equation Δ V$_{nuc}$ ( r )+Δ V$_{scr}$ ( r ) = 4 παZρ$_{eff}$ ( r ). U scr VP differs from U$_{VP}$ only by replacing ρ$_{eff}$ with ρ$_{scr}$ where the density ρ$_{scr}$ is related to the screening potential V$_{scr}$ . The Wichmann- Kroll parts of the expressions (23)-(25) are evaluated employing the approximate formula for the Wichmann-Kroll potential [66]. The Wichmann-Kroll contribution to Eq. (26) is relatively small [5] and is neglected in the present consideration. The numerical evaluation is based on the wave functions constructed from B-splines employing the dual-kinetic-balance finite basis set method [67]. The sphere model for the 26 U$_{VP}$ ( r ) = − 2 α $^{2}$Z 3 r ∫ ∞ 1 d t √$_{t}$ 2 − 1 t 3 ( 1 + 1 2 t 2 ) ∫ ∞ 0 d r $^{′}$r $^{′}$ρ$_{eff}$ ( r $^{′}$) × [exp ( − 2 | r − r $^{′}$| t ) − exp ( − 2 | r + r $^{′}$| t )] (27) I$_{VP}$ (Δ r$_{12}$ ) = α α$_{1}$$_{µ}$α µ 2 r$_{12}$ 2 α 3 π ∫ ∞ 1 d t √$_{t}$ 2 − 1 t 2 ( 1 + 1 2 t 2 ) exp ( − √$_{4}$$_{t}$ 2 − Δ $^{2}$r$_{12}$ ) (28) Δ E ( b ) a scrVP = Δ E (0) scrVP + Δ E (1 irr) scrVP + Δ E (1 red) scrVP + Δ E (1 b ) $_{scrVP}$ (22) Δ E (0) scrVP = 〈 a | U$_{VP}$ | a 〉 − 〈 a$_{C}$ | U$_{VP}$ | a$_{C}$ 〉 (23) Δ E (1 irr) scrVP = 2 ∑ b ∑ P ( − 1) P [ ε n = ε a ∑ n 〈 P aP b | I (Δ) | nb 〉〈 n | U$_{VP}$ | a 〉 ε$_{a}$ − ε$_{n}$ + ε n = ε b ∑ n 〈 P aP b | I (Δ) | an 〉〈 n | U$_{VP}$ | b 〉 ε$_{b}$ − ε$_{n}$ ] − 2$^{ε}$$^{n}$$^{̸}$$^{=}$$^{ε}$$^{a}$ ∑ n 〈 a | V$_{scr}$ | n 〉〈 n | U$_{VP}$ | a 〉 ε$_{a}$ − ε$_{n}$ (24) Δ E (1 red) scrVP = − ∑ b ∑ P ( − 1) $^{P}$〈 P aP b | I $^{′}$(Δ) | ab 〉 ( 〈 a | U$_{VP}$ | a 〉 − 〈 b | U$_{VP}$ | b 〉 ) (25) Δ E (1 b ) scrVP = ∑ b ∑ P ( − 1) $^{P}$〈 P aP b | I$_{VP}$ (Δ) | ab 〉 − 〈 a | U scr VP | a 〉 (26)
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PLAYERS SECTION IV - WITHDRAWALS AND RETIREMENTS form approved in writing by such Supervisor (or Referee in the case of Billie Jean King Cup). In the case of (i) and (ii) above such player will be allowed to play doubles at another WTA event or singles and/or doubles at another ITF event scheduled the same week. b. If a player is unable to arrive at her first scheduled Main Draw match of a WTA Tournament or withdraws from the Main Draw of a WTA Tournament due to her participation in a Billie Jean King Cup event the player must follow the procedures set forth in this Section to withdraw from such Tournament and the player is subject to the Late Withdrawal fines set out in Section IV.A.3.b. a. Once a player has been accepted into the Main Draw or Qualifying of a WTA Tournament she may not withdraw to play singles or doubles in another Tournament in the same week except as follows: i. a player may withdraw from the Qualifying of a WTA Tournament and play in another Tournament in the same week if she accepts a Wild Card into: 9. Prohibition Against Withdrawing from One Tournament to Play Another (a) the Main Draw of any WTA Tournament; or (b) the Qualifying of a WTA Tournament in a higher category according to the table below: Tournament at which player withdraws from the Qualifying Tournament at which player accepts a Wild Card into the Qualifying WTA 125 WTA 250 WTA 500 or WTA 1000 WTA 250 WTA 500 or WTA 1000 ii. a player may withdraw from the doubles Main Draw of a WTA Tournament and play in another Tournament in the same week in accordance with sub-Section i above or Section III.B.1.b.i(b). If a player is discovered at any time to have violated this prohibition she will (a) forfeit any ranking points received (singles and doubles) from the other Tournament in which she played; and (b) receive the applicable Late Withdrawal fine. 53
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40 Corporate Governance Meetings Principle 7: Recognise and manage risk Risk Management Policies Roles and responsibilities Asset operating risk Regulatory risk Board Compliance risk Climate change Financial risks Committee Notices of meeting sent to AGL’s shareholders comply with the “Guidelines for notices of meeting” issued by the ASX in August 2007. Shareholders are invited to submit questions before the meeting and at the meeting the Chairman attempts to answer as many of these as is practical. Approximately 100 shareholders took the opportunity to submit questions in advance of the 2010 Annual General Meeting. The Chairman also encourages shareholders at the meeting to ask questions and make comments about AGL’s operations and the performance of the Board and senior management. The Chairman may respond directly to questions or at his discretion may refer a question to another Director the CEO or a member of the Executive Team. New Directors or Directors seeking re– election are given the opportunity to address the meeting and to answer questions from shareholders. AGL has adopted the practice of conducting a poll on each motion being considered at the meeting. Shareholders in attendance at the meeting are also given the opportunity to vote by a show of hands before the poll is conducted. The external auditor attends AGL’s Annual General Meeting. Shareholders may submit written questions to the auditor to be considered at the meeting in relation to the conduct of the audit and the preparation and content of the Independent Audit Report by providing the questions to AGL at least five business days before the day of the meeting. No questions were sent to the auditor in advance of the 2010 Annual General Meeting. Shareholders are also given a reasonable opportunity at the meeting to ask the auditor questions relevant to the conduct of the audit the Independent Audit Report the accounting policies adopted by AGL and the independence of the auditor. Recommendation 7.1 – Companies should establish risk management policies for the oversight of material business risks Recommendation 7.2 – Companies should establish risk management and internal control systems to manage material business risk and require management to report to the Board on the eff ectiveness of these systems and the effectiveness of the material business risks AGL faces a wide variety of risks due to the nature of its operations and the regions in which it operates. These risks include: Making sure that AGL can source adequate volumes of gas and electricity on acceptable terms to meet customer needs. This includes making sure that we have effective electricity hedging policies and procedures in place. Supply risk Making sure that AGL’s assets particularly electricity generation assets operate reliably when required. The prices AGL can charge its customers for gas and electricity are regulated in most of the markets in which AGL operates. AGL faces the risk that the regulated prices will not increase at the same rate as the costs of acquiring energy to meet customer needs. AGL operates in a heavily regulated industry. As an energy company government policies on carbon emissions and renewable energy will affect AGL and its customers. Making sure that AGL has the right capital structure to provide the financial capacity to implement its strategy. AGL systematically examines all operational and financial areas of the Company to identify its major risk exposures using an enterprise–wide risk program based on ISO31000 the international standard on risk management. This program is supported by AGL’s Risk Management Policy. AGL has a number of other policies that directly or indirectly serve to reduce and/or manage risk. These include but are not limited to: The Board is responsible for reviewing and approving changes to the Risk Management Policy and for satisfying itself that AGL has a sound system of risk management and internal control that is operating effectively. The Committee assists the Board in carrying out these responsibilities. Details of the operation of the Committee are included in the commentary on Principle 4. The Committee oversees the detailed analysis of the effectiveness of the system of risk management and internal control. The Committee receives an annual presentation of AGL’s material business risks and the controls in place to mitigate the consequences of those risks. The Committee also receives regular presentations from management throughout the year on specific risk topics. The Committee has responsibility for approving the internal audit plan submitted annually by Group Audit. The internal audit plan is based on an assessment of AGL’s main risk exposures. The Committee also reviews and approves the annual external audit plan. Executive Team The CEO has primary responsibility for designing implementing and reporting on AGL’s risk management framework. The Executive Team collectively has responsibility for promoting a risk management culture throughout AGL including consistent application of the Risk Management Policy across AGL. > Compliance Policy; > Market Disclosure Policy; > Code of Conduct; > Delegations of Authority Manual; > Health Safety and Environment Policy; > Wholesale Energy Risk Management Policy; > Treasury Policy; and > Privacy Policy. The Risk Management Policy and the other policies listed above describe the roles and responsibilities for managing risk. This includes as appropriate details of responsibilities allocated to the Board or to the Audit and Risk Management Committee (Committee) Executives the business units and AGL’s Group Audit function.
0financial_reports
Heures ouvrées (Lundi-vendredi 07h00-19h00) Hors heures ouvrées (nuits et Weekend et jours fériés du Conseil): Délai d'intervention Délai de dépannage Délai d'intervention Délai de dépannage Remise en service provisoire: Remise en service définitive: Remise en service provisoire: Remise en service définitive: Criticité 3: 1 heure 4 heures 24 heures 2 heures 8 heures 48 heures Criticité 2: 4 heures 12 heures 48 heures 16 heures 24 heures 48 heures Criticité 1: 8 heures 72 heures 96 heures 24 heures 72 heures 96 heures Les niveaux de criticité par équipement sont repris dans l'inventaire des équipements en appendice 2. Les délais ci-dessus sont prolongés des délais d'approvisionnement dûment justifiés pour les matériels non retenus par le Secrétariat au stock de réserve ou ceux pour lesquels le contractant ne garantit aucun délai d’approvisionnement en accord avec le Secrétariat. Sur demande du contractant auprès du Secrétariat le délai pourrait être prolongé dans le cas où les réparations justifieraient un délai complémentaire lié à des travaux d'autres corps de métiers. Dans ce cas la coordination éventuelle l’organisation voire le suivi des interventions d’autres corps de métier relèvent des missions du Contractant. Pour les interventions de garde en dehors des heures ouvrées le contractant informera le Secrétariat au plus tard le lendemain ou le premier jour ouvré après l'intervention avant 10h du matin. Le contractant fournit à ses frais tous les matériels matériaux et pièces de rechange nécessaires au bon fonctionnement et au maintien des installations étant entendu que d’une part la valeur unitaire (soit le prix de 1 pièce quel que soit le conditionnement proposé) de ces matériels n'excède pas 800 -€ HTVA (prix net remise déduite) et que d’autre part il s’agisse uniquement d’opérations de maintenance préventive ou curative ou de dépannage. La valeur considérée est celle de la facture du fournisseur prix net remise fournisseur déduite hors TVA hors frais de port et hors coefficient de majoration mentionné au bordereau financier. 2.7 Approvisionnements 2.7.1 Fournitures à charge du Contractant de pièces et d'équipements nécessaires au bon fonctionnement des installations. En cas de remplacements multiples d’un élément identique d’une valeur inférieure à ces montants quelle que soit la période considérée le cumul du montant de ces remplacements ne sera pas autorisé. Par exemple: les filtres les lampes et les détecteurs incendie sont considérés comme éléments identiques et font partie de la maintenance préventive. Le fait que des parties ou des composants déterminés sont difficiles à entretenir que le remplacement et/ou la réparation de matériel déterminé est difficile ne constituera pas un 14 Cahier des charges UCA 21/013
1government_tenders
mysqld_safe — MySQL Server Startup Script [mysqld_safe] malloc-lib=tcmalloc To use a specific tcmalloc library specify its full path name. Example: [mysqld_safe] malloc-lib=/opt/lib/libtcmalloc_minimal.so The name of the server program (in the ledir directory) that you want to start. This option is needed if you use the MySQL binary distribution but have the data directory outside of the binary distribution. If mysqld_safe cannot find the server use the --ledir option to indicate the path name to the directory where the server is located. This option is accepted only on the command line not in option files. On platforms that use systemd the value can be specified in the value of MYSQLD_OPTS . See Section 2.5.9 “Managing MySQL Server with systemd” . This option is similar to the --mysqld option but you specify only the suffix for the server program name. The base name is assumed to be mysqld . For example if you use --mysqld- version=debug mysqld_safe starts the mysqld-debug program in the ledir directory. If the argument to --mysqld-version is empty mysqld_safe uses mysqld in the ledir directory. This option is accepted only on the command line not in option files. On platforms that use systemd the value can be specified in the value of MYSQLD_OPTS . See Section 2.5.9 “Managing MySQL Server with systemd” . Use the nice program to set the server’s scheduling priority to the given value. Do not read any option files. If program startup fails due to reading unknown options from an option file --no-defaults can be used to prevent them from being read. This must be the first option on the command line if it is used. For additional information about this and other option-file options see Section 4.2.2.3 “Command-Line Options that Affect Option-File Handling” . The number of files that mysqld should be able to open. The option value is passed to ulimit -n . You must start mysqld_safe as root for this to function properly. The path name that mysqld should use for its process ID file. The path name of the plugin directory. 386 • --plugin-dir= dir_name • --pid-file= file_name • --open-files-limit= count • --no-defaults • --nice= priority • --mysqld-version= suffix • --mysqld= prog_name Note
3manuals
ARTICLE III ARTICLE IV Officials Authorized to Execute Government Conveyances and Contracts SECTION 308 . Authority of Governor-General to Execute Conveyances and Contracts Relating to Real Property . — When the Government of the Philippine Islands is party to a deed or any instrument conveying the title of real property or is party to any lease or other contract relating to real property belonging to said Government said deed instrument or contract shall be executed on behalf of said Government by the Governor-General unless authority to execute the same is by law expressly vested in some other of ficer. [1705-1.] SECTION 309 . Authority of Insular Officials to Make Contracts . — Written contracts not within the purview of the preceding section shall in the absence of special provision be executed with the approval of the proper Department head by the chief of the Bureau or Office having control of the appropriation against which the contract would create a charge; or if there be no such chief by the proper Department head himself or the Governor-General as the case may require. Contracts on behalf of the Insular Government with companies operating vessels engaged in the coastwise trade to secure the carriage of freight and passengers for the Government shall be executed by the Secretary of Commerce and Police subject to such res trictions as may be prescribed by law; but vessels engaged in the coastwise trade and vessels plying between Philippine ports shall continue to carry mail free. IcHDCS Gratuitous Conveyance of Government Property for Certain Purposes SECTION 310 . Conveyance of Government Property to Province City or Municipality . — When real property belonging to the Government of the Philippine Islands is needed for school purposes or other proper governmental use by the province city municipality or other local political division wherein the property is situated it shall be competent for the Governor-General to execute to such province city municipality or other local political division a proper conveyance thereof by way of gift sale lease e xchange or otherwise and upon such terms to be inserted in the instrument of conveyance as shall seem to him most convenient for the interests of the parties concerned. But nothing herein shall be deemed to authorize the conveyance of unreserved publ ic land friar land or any Copyright 2012 CD Technologies Asia Inc. and Accesslaw Inc. Philippine Law Encyclopedia 2011 104
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environmental control systems to support flight. Understanding the aircraft systems of the aircraft being flown is critical to its safe operation and proper maintenance. Consult the AFM/ POH for specific information pertaining to the aircraft being flown. Various manufacturer and owners group websites can also be a valuable source of additional information. 7-42
2laws_and_regulations
175 Exhibit Number Description 4.155 Amended and Restated Intercreditor Agreement (2017-2) dated as of October 5 2017 among Wilmington Trust Company as Trustee of the American Airlines Pass Through Trust 2017-2AA as Trustee of the American Airlines Pass Through Trust 2017-2A and as Trustee of the American Airlines Pass Through Trust 2017-2B National Australia Bank Limited as Class AA Liquidity Provider Class A Liquidity Provider and Class B Liquidity Provider and Wilmington Trust Company as Subordination Agent (incorporated by reference to Exhibit 4.3 to American’s Current Report on Form 8-K filed on October 6 2017 (Commission File No. 1-2691)). 4.156 Amended and Restated Note Purchase Agreement dated as of October 5 2017 among American Airlines Inc. Wilmington Trust Company as Pass Through Trustee under each of the Pass Through Trust Agreements Wilmington Trust Company as Subordination Agent Wilmington Trust National Association as Escrow Agent and Wilmington Trust Company as Paying Agent (incorporated by reference to Exhibit 4.6 to American’s Current Report on Form 8-K filed on October 6 2017 (Commission File No. 1-2691)). 4.157 Form of Participation Agreement (Participation Agreement among American Airlines Inc. Wilmington Trust Company as Pass Through Trustee under each of the Pass Through Trust Agreements Wilmington Trust Company as Subordination Agent Wilmington Trust Company as Loan Trustee and Wilmington Trust Company in its individual capacity as set forth therein) (incorporated by reference to Exhibit B to Exhibit 4.6 to American’s Current Report on Form 8-K filed on October 6 2017 (Commission File No. 1- 2691)). 4.158 Form of First Amendment to Participation Agreement (First Amendment to Participation Agreement among American Airlines Inc. Wilmington Trust Company as Pass Through Trustee under each of the Pass Through Trust Agreements Wilmington Trust Company as Subordination Agent Wilmington Trust Company as Loan Trustee and Wilmington Trust Company in its individual capacity as set forth therein) (incorporated by reference to Exhibit D to Exhibit 4.6 to American’s Current Report on Form 8-K filed on October 6 2017 (Commission File No. 1-2691)). 4.159 Form of Indenture and Security Agreement (Indenture and Security Agreement between American Airlines Inc. and Wilmington Trust Company as Loan Trustee) (incorporated by reference to Exhibit C to Exhibit 4.6 to American’s Current Report on Form 8-K filed on October 6 2017 (Commission File No. 1-2691)). 4.160 Form of Pass Through Trust Certificate Series 2017-2B (incorporated by reference to Exhibit A to Exhibit 4.2 to American’s Current Report on Form 8-K filed on October 6 2017 (Commission File No. 1-2691)). 4.161 Revolving Credit Agreement (2017-2B) dated as of October 5 2017 between Wilmington Trust Company as Subordination Agent as agent and trustee for the trustee of the American Airlines Pass Through Trust 2017-2B as Borrower and National Australia Bank Limited as Liquidity Provider (incorporated by reference to Exhibit 4.12 to American’s Current Report on Form 8-K filed on October 6 2017 (Commission File No. 1-2691)). 4.162 Trust Supplement No. 2012-2C(R) dated as of May 15 2018 between American Airlines Inc. and Wilmington Trust Company as Trustee to the Pass Through Trust Agreement dated as of September 16 2014 (incorporated by reference to Exhibit 4.2 to American’s Current Report on Form 8-K filed on May 16 2018 (Commission File No. 1-2691)). 4.163 Form of Amendment No. 2 to Intercreditor Agreement (2012-2C(R)) among Wilmington Trust Company not in its individual capacity but solely as Trustee of the American Airlines Inc. Pass Through Trust 2012-2C(R) American Airlines Inc. and Wilmington Trust Company not in its individual capacity but solely as Subordination Agent and Trustee (incorporated by reference to Exhibit C to Exhibit 4.6 to American’s Current Report on Form 8-K filed on May 16 2018 (Commission File No. 1-2691)). 4.164 Note Purchase Agreement dated as of May 15 2018 among American Airlines Inc. Wilmington Trust Company not in its individual capacity but solely as Pass Through Trustee under the Class C(R) Pass Through Trust Agreement as Subordination Agent and as Indenture Trustee Wilmington Trust National Association as Escrow Agent and Wilmington Trust Company as Paying Agent (incorporated by reference to Exhibit 4.6 to American’s Current Report on Form 8-K filed on May 16 2018 (Commission File No. 1- 2691)). 4.165 Form of Amendment to Participation Agreement (Amendment to Participation Agreement among American Airlines Inc. Wilmington Trust Company not in its individual capacity but solely as Subordination Agent and as Indenture Trustee and Wilmington Trust Company not in its individual capacity but solely as Pass Through Trustee under each of the Pass Through Trust Agreements) (incorporated by reference to Exhibit A to Exhibit 4.6 to American’s Current Report on Form 8-K filed on May 16 2018 (Commission File No. 1- 2691)). 4.166 Form of Amendment to Trust Indenture and Security Agreement (Amendment to Trust Indenture and Security Agreement between American Airlines Inc. Wilmington Trust Company not in its individual capacity but solely as Indenture Trustee and Wilmington Trust National Association as Securities Intermediary) (incorporated by reference to Exhibit B to Exhibit 4.6 to American’s Current Report on Form 8-K filed on May 16 2018 (Commission File No. 1-2691)). 4.167 Form of Pass Through Trust Certificate Series 2012-2C(R) (incorporated by reference to Exhibit A to Exhibit 4.2 to American’s Current Report on Form 8-K filed on May 16 2018 (Commission File No. 1-2691)).
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Sails and Rigging Parts of sails Rigging Sail terminology The two types of sails This diagram shows the parts of a sail on a typical sail (this is the mainsail). The top corner is called the head the bottom corners are the clew and the tack. On this sail the tack is close to the mast and the clew is at the end of the boom. The sides are called the foot at the bottom the luff at the front near the mast and the diagonal leech at the back. Rigging is the ropes and wires on a boat involved with sails. Every ‘rope’ is named for its function and/or location. This is so when the skipper says “dump the mainsheet and take in the jib!” everyone knows which rope to let go and which one to pull. A topping lift is used to raise or lower a spar like the boom. A halyard raises or lowers a sail and would thus be attached to the head of the sail. A sheet is a rope that controls the angle of the sail to the wind. It is usually attached to the clew . By and large you’ll only have to deal with two kinds of sails : the main and the jib. As you progress you might deal with other kinds of sails including different kinds of jibs and speciality sails like storm sails or spinnakers. For now we’ll concentrate on the main and the jib. The mainsail is the big sail behind the mast and is obviously very important to how the boat works. The mainsail is controlled by a single mainsheet that usually runs to a series of pulleys in the middle of the cockpit. The pulleys supply the extra force need to move the big mainsail when it is full of wind. The jib (in front of the mast) is equally important to how a boat sails especially when it sails into the wind. The jib is controlled by two sheets which run down each side of the boat. When the boat is sailing one of these the working sheet will be under load as it holds the force of the wind in the sail. The other the lazy sheet will be lying slack – essentially doing nothing. When the boat changes direction the lazy sheet and the working sheet will swap sides. The lazy sheet will hold the sail against the force of the wind and become the working sheet and the working sheet will go slack and become the lazy sheet. We’ll look at this in more detail later. • Take in / sheet in – to tighten or pull on a rope • Hard on – as tight as a sheet or sail will go (e.g. “bring the jib hard on”) • Let go / ease - to loosen or let out a rope (e.g. “ease the jib sheet”) • Dump – to let go all at once to ease as far as it will go • Luffing – when a sail flaps at the front edge (i.e. the luff) • Working sheet – a sheet that is tight because it is holding a sail against the force of the wind • Lazy sheet – a sheet that is loose because it is doing nothing (no force)
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Numero del contratto: [ completare ] Gara d'appalto JRC/IPR/2019/OP/0139 Condizioni CQ – Ottobre 2018 (e) modifiche apportate dall'amministrazione aggiudicatrice o da terzi a nome dell'amministrazione aggiudicatrice: (f) diritto di autorizzare o dare in licenza a terzi i modi di sfruttamento di cui alle lettere da a) a e) a condizione tuttavia che ciò non si applichi a diritti preesistenti e a materiali preesistenti se essi sono dati in licenza solo all'Unione tranne come previsto dalla clausola II.13.2; (g) altri adattamenti che le parti possono concordare successivamente; in tal caso si applicano le seguenti disposizioni: l'amministrazione aggiudicatrice deve consultare il contraente. Se necessario quest'ultimo chiede a sua volta il consenso del creatore o altro detentore del diritto e deve rispondere all'amministrazione aggiudicatrice entro un mese dando il suo consenso e fornendo gratuitamente eventuali suggerimenti per le modifiche. Il contraente può opporsi alla modifica prevista soltanto se un creatore può dimostrare che questa rischia di arrecare pregiudizio al suo onore e alla sua reputazione violando così i suoi diritti morali. I modi di sfruttamento possono essere definiti più dettagliatamente nel contratto specifico. 14  accorciamento;  riassunto;  modifica del contenuto delle dimensioni;  modifiche tecniche del contenuto (correzioni necessarie di errori tecnici) aggiunta di nuove parti o funzioni cambiamento di funzioni fornitura a terzi di informazioni supplementari relative al risultato (es.: codice sorgente) in vista di modifiche;  aggiunta di nuovi elementi paragrafi titoli cappelli grassetti legende indici sunti grafici sottotitoli audio;  aggiunta di metadati per l'estrazione dei dati anche testuali; aggiunta di informazioni sulla gestione dei diritti; aggiunta di misure tecnologiche di protezione;  preparazione in formato audio preparazione in forma di presentazione animazione storia in pittogrammi sequenza di diapositive presentazione pubblica;  estrapolazione di una parte o divisione in parti;  integrazione anche mediante rifilatura e taglio dei risultati o di parti di essi in altre opere come ad esempio siti o pagine web;  traduzione inserimento di sottotitoli doppiaggio in diverse versioni linguistiche: - francese inglese tedesco; - tutte le lingue ufficiali dell'UE; - lingue utilizzate all'interno dell'UE; - lingue dei paesi candidati; - altre lingue;
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core values – always learning always teaching. In fact the manage- ment path at Darden begins with a 12-week Manager-In-Training (MIT) program that focuses heavily on leadership skills such as coaching and motivating. The coming year will be a significant one for Red Lobster. With a new senior management team at the helm the company has under- taken a variety of initiatives to strengthen its competitive edge. These include continuing work on a simpler menu a new LightHouse ™ menu showcasing the natural nutritional benefits of seafood an improved and highly acclaimed kid’s menu new advertising and a revamped promotional strategy. “We consider the restaurant general manager to be the most important position in the Company ” says Al Frost Darden’s Senior Director of Leadership Development. “Behind every profit-and-loss statement is a general manager. It is imperative to have the right person with the right training in order to get the right results.” Red Lobster’s commitment to training and professional development at every level has helped the company grow into a market leader in the casual dining industry with over $2.4 billion in sales in fiscal 2004. Red Lobster’s industry leadership truly begins at the local restaurant level with managers like Edward Bermudez. “One of the most reward- ing aspects of my job as a manager is to develop new leaders ” he notes. “I love going to training sessions and seeing old friends grow- ing in new roles.” That kind of passion will certainly help lead the casual dining seafood leader into a new era of growth. Darden Restaurants 15
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Contract number: ECHA/2020/724 Restricted Service contract conditions of December 2018 specific tenders or specific contracts are granted only upon submission of supporting documents proving that the authorised person is empowered to act as a legal representative of the contractor. II.6.1 The contracting authority is not liable for any damage or loss caused by the contractor including any damage or loss to third parties during or as a consequence of performance of the contract . II.6.2 If required by the relevant applicable legislation the contractor must take out an insurance policy against risks and damage or loss relating to the performance of the contract . It must also take out supplementary insurance as reasonably required by standard practice in the industry. Upon request the contractor must provide evidence of insurance coverage to the contracting authority. II.6.3 The contractor is liable for any loss or damage caused to the contracting authority during or as a consequence of performance of the contract including in the event of subcontracting but only up to an amount not exceeding three times the total amount of the contract. However if the damage or loss is caused by the gross negligence or wilful misconduct of the contractor or of its personnel or subcontractors as well as in the case of an action brought against the contracting authority by a third party for breach of its intellectual property rights the contractor is liable for the whole amount of the damage or loss. II.6.4 If a third party brings any action against the contracting authority in connection with the performance of the contract including any action for alleged breach of intellectual property rights the contractor must assist the contracting authority in the legal proceedings including by intervening in support of the contracting authority upon request. II.6.5 If the contractor is composed of two or more economic operators (i.e. who submitted a joint tender) they are all jointly and severally liable to the contracting authority for the performance of the contract . II.6.6 The contracting authority is not liable for any loss or damage caused to the contractor during or as a consequence of performance of the contract unless the loss or damage was caused by wilful misconduct or gross negligence of the contracting authority. II.7.1 The contractor must take all the necessary measures to prevent any situation of conflict of interest or professional conflicting interest. II.7.2 The contractor must notify the contracting authority in writing as soon as possible of any situation that could constitute a conflict of interest or a professional conflicting interest during the performance of the contract . The contractor must immediately take action to rectify the situation. (a) verify that the contractor’s action is appropriate; (b) require the contractor to take further action within a specified deadline; The contracting authority may do any of the following: If the contracting authority’s liability towards the third party is established and that such liability is caused by the contractor during or as a consequence of the performance of the contract Article II.6.3 applies. II.6. LIABILITY II.7. CONFLICT OF INTEREST AND PROFESSIONAL CONFLICTING INTERESTS 16
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SECTION 2520 . Title of Chapter . — This chapter shall be known as the Charter of the City of Baguio. DTIACH SECTION 2521 . Incorporation — Powers . — The territory within the boundaries described in the next succeeding section and the inhabitants thereof shall be a municipality which shall be known as the city of Baguio; and by that name shall have perpetual suc cession; have and use a common seal and alter the same at pleasure; sue and be sued and prosecute and defend to final judgment and execution; take purchase receive hold lease convey and dispose of real and personal property for the benefit of the c ity within or without its corporate limits; contract and be contracted with; and execute all the powers hereinafter conferred. [1963-1.] SECTION 2522 . Boundaries . — The boundaries and limits of the territory of said city are established and prescribed as follows: Beginning at point marked "1" being a point on a large rock in the center of the Irisan River in the subprovince of Benguet at the bridge site over said river on the Baguio-San Fernando Road thence S. 19° 53' E. 7 332.9 meters to point 2 a tripod on a knoll of the Baguio-Santo Tomas ridge; S. 79° 14' E. 6 880.6 meters to point 3 a tripod on a small wooded mountain west of the Kias trail; N. 10' 12' E. 2 193.2 meters to point 4 a tripod on a wooded ridge; N. 7° 35' W. 3 920 meters to point 5; N. 1 478 meters to point 6; W. 973 meters to point 7 being Pakdal triangulation station; S. 83° 58' W. 3 022 meters to point 8 on a bridge over a small creek on the Baguio-Trinidad Road; N. 58° 15' W. 1 364 meters to point 9 a tripod at the triangulation station known as "center"; and N. 86° 12' W. 4 010.6 meters to the point of beginning. [1963-2.] SECTION 2523 . Jurisdiction of City for Police Purposes . — The jurisdiction of the city for police purposes only shall extend over the barrios of San Pascual Taloy Tabaan Twin Peaks Saitan Cuenca San Luis Dagupan Maoasoas Ambangunan Pugo and Naga lisan and all settlements situated on Antamok and Bituan Creeks. Within the aforementioned barrios and settlements the justice of the peace court of the city shall have concurrent jurisdiction with the courts of justices of the peace of the municipalities within which the said barrios and settlements are situated to try crimes and misdemeanors committed therein. The court first taking jurisdiction of such an offense shall thereafter retain Copyright 2012 CD Technologies Asia Inc. and Accesslaw Inc. Philippine Law Encyclopedia 2011 758 General Provisions ARTICLE I
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page 107 Bombardier Inc. Annual Report 2003-04 12 ACCOUNTS PAYABLE AND ACCRUED LIABILITIES Product warranties Accounts payable and accrued liabilities were as follows as at January 31: Product warranties in the aerospace segment typically range from one to five years except for structural warranties which extend up to 20 years and from one to five years in the transportation segment. The following table summarizes product warranty activity during the year ended January 31 2004: 2004 2003 Bombardier Accounts payable $2 849 $3 233 Sales incentives and related provisions 1 575 1 127 Warranty provision 1 236 1 269 Accrued liabilities 1 178 1 243 Payroll related liabilities 477 481 Severance and other involuntary termination obligations 237 148 Interest payable 153 177 Other 963 816 8 668 8 494 BC Accounts payable and accrued liabilities 111 130 Interest payable 57 88 Income taxes payable 25 4 Other 139 190 332 412 $9 000 $8 906 AEROSPACE TRANSPORTATION TOTAL Balance as at January 31 2003 $ 312 $ 957 $1 269 Current expense 171 556 727 Changes in estimates 106 (24) 82 Cash paid (235) (574) (809) Effect of foreign currency exchange rate changes (9) (24) (33) Balance as at January 31 2004 $ 345 $ 891 $1 236
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Upgrading MySQL Binary or Package-based Installations on Unix/Linux deprecated or removed features and capabilities. Consequently SQL extracted from a previous MySQL release may require modification to enable a logical upgrade. To identify incompatibilities before upgrading to the latest MySQL 8.0 release perform the steps described in Section 2.11.5 “Preparing Your Installation for Upgrade” . To perform a logical upgrade: 1. Review the information in Section 2.11.1 “Before You Begin” . 2. Export your existing data from the previous MySQL installation: 3. Shut down the old MySQL server. For example: 4. Install MySQL 8.0. For installation instructions see Chapter 2 Installing and Upgrading MySQL . 5. Initialize a new data directory as described in Section 2.10.1 “Initializing the Data Directory” . For example: 6. Start the MySQL 8.0 server using the new data directory. For example: 7. Reset the root password: 289 Copy the temporary ’root’@’localhost’ password displayed to your screen or written to your error log for later use. mysqld_safe --user=mysql --datadir= /path/to/8.0-datadir & shell> mysql -u root -p Enter password: **** <- enter temporary root password mysql> ALTER USER USER() IDENTIFIED BY ’ your new password ’; mysqld --initialize --datadir= /path/to/8.0-datadir mysqladmin -u root -p shutdown mysqldump -u root -p --add-drop-table --routines --events --all-databases --force > data-for-upgrade.sql Use the --routines and --events options with mysqldump (as shown above) if your databases include stored programs. The --all-databases option includes all databases in the dump including the mysql database that holds the system tables. If you have tables that contain generated columns use the mysqldump utility provided with MySQL 5.7.9 or higher to create your dump files. The mysqldump utility provided in earlier releases uses incorrect syntax for generated column definitions (Bug #20769542). You can use the INFORMATION_SCHEMA.COLUMNS table to identify tables with generated columns. Important Note
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The variation of the functional with respect to the linear parameters a$_{n}$ and tan δ leads to the following equations To obtain the last equation the normalization relation of Eq. (9) has been used. From these two equations Ψ$_{c}$ and the first order estimate of the phase shift (tan δ ) 1 st can be determined. It should be noted that the first equation implies < Ψ$_{c}$ | H − E | Ψ$_{t}$ > = 0. Furthermore from the general relation for A in Eq. (4) and using the second equation in Eq. (16) the following integral relation results Replacing the two relations of Eq.(16) into the functional of Eq.(14) a second order estimate of the phase shift is obtained Multiplying Eq. (18) by A one gets On the other hand a first order estimate for the coefficient B can be obtained from the general relation in Eq. (4) i.e. Therefore replacing Eq.(20) in Eq.(19) a second order integral relation for B is obtained. The above results can be summarized as follow These equations extend the validity of the integral relations given in Eq.(6) for the exact wave functions to trial wave functions. To be noticed that F ˜ G are solutions of the Schr¨ odinger equation in the asymptotic region therefore ( H − E ) F → 0 and ( H − E ) ˜ G → 0 as the distance between the particles increases. As a consequence the decomposition of 7 B 2 nd = − m ℏ 2 < Ψ$_{t}$ | H − E | F > A = m ℏ 2 < Ψ$_{t}$ | H − E | ˜ G > [tan δ ] 2 nd = B 2 $^{nd}$/A . (21) m ℏ 2 [ < F | H − E | Ψ$_{t}$ > − < Ψ$_{t}$ | H − E | F > ] = B 1 st . (20) B 2 nd = B 1 st − m ℏ 2 < F | H − E | Ψ$_{t}$ > . (19) [tan δ ] 2 nd = (tan δ ) 1 st − m ℏ 2 < F | H − E | (1 /A )Ψ$_{t}$ > . (18) m ℏ 2 < Ψ$_{t}$ | H − E | ˜ G > = A . (17) < φ$_{n}$ | H − E | Ψ$_{t}$ > = 0 < ˜ G | H − E | Ψ$_{t}$ > = 0 . (16)
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BOARD OF DIRECTORS OFFICERS STOCK PRICE ANNUAL MEETING TRANSFER AGENT LEGAL COUNSEL INVESTORS’ INQUIRIES STOCK LISTING INDEPENDENT REGISTERED PUBLIC ACCOUNTING FIRM KPMG LLP 999 Waterside Drive Suite 2100 Norfolk VA 23510 Macon F. Brock Jr. Chairman H. Ray Compton Richard G. Lesser John F. Megrue J. Douglas Perry Chairman Emeritus Bob Sasser Thomas A. Saunders III Eileen R. Scott Thomas E.Whiddon Alan L.Wurtzel Dollar Tree’s common stock has been traded on the NASDAQ Stock Market under the symbol “DLTR” since our initial public offering on March 6 1995. The following table gives the high and low sales prices of our common stock for the fiscal years 2004 and 2003. Bob Sasser President and Chief Executive Officer Kent Kleeberger Chief Financial Officer James E. Fothergill Chief People Officer Raymond K. Hamilton Chief Information Officer Gary M. Philbin Senior Vice President Stores Arvil L. Priode Senior Vice President Merchandise Planning and Control Bob Rudman Chief Merchandising Officer Stephen W. White Chief Logistics Officer Frederick C. Coble Corporate Secretary Requests for interim and annual reports Forms 10-K or more information should be directed to: Shareholder Services Dollar Tree Stores Inc. 500 Volvo Parkway Chesapeake VA 23320 (757) 321-5000 Or from our company web site: www.DollarTree.com National City Bank Dept. 5352 Corporate Trust Operations P.O. Box 92301 Cleveland OH 44193-0900 Tel: 800-622-6757 Email: shareholder.inquiries@nationalcity.com You are cordially invited to attend our Annual Meeting of Shareholders which will be held at 10:00 a.m. on Thursday June 16 2005 at The Founders Inn Virginia Beach Virginia. Williams Mullen Hofheimer Nusbaum PC 999 Waterside Drive Suite 1700 Norfolk VA 23510 We intend to retain any future earnings for use in our business. Management does not anticipate paying cash dividends in the foreseeable future. Our credit facilities contain financial covenants that restrict our ability to pay dividends. HIGH LOW 2004 First Quarter $ 33.97 $ 26.82 Second Quarter 29.20 24.50 Third Quarter 29.28 22.29 Fourth Quarter 30.29 26.40 2003 First Quarter $ 26.16 $ 17.40 Second Quarter 37.62 24.82 Third Quarter 39.75 33.47 Fourth Quarter 38.74 27.36
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The preparation of the Company’s consolidated financial statements in accordance with IFRS requires management to make estimates judgments and assumptions that affect the application of accounting policies and the reported amounts of assets liabilities income and expenses in the consolidated financial statements and the disclosure of contingent assets and liabilities at the date of the consolidated financial statements. The Company reviews its estimates and assumptions on an ongoing basis and uses the most current information available and exercises careful judgment in making these estimates and assumptions. The main judgments that were used in preparing the Company’s consolidated financial statements relate to: The determination of CGUs was based on management’s judgment giving consideration to geographic proximity and shared risk exposure and risk management. Identifying events or changes in circumstances that may indicate or cause an asset’s carrying amount to exceed its recoverable amount requires judgment in assessing what events or circumstances would have such an impact. The main sources of estimation uncertainty in preparing the Company’s consolidated financial statements relate to: The valuation of the Company’s derivative instruments and certain other financial instruments requires estimation of the fair value of each instrument at the reporting date. Details of the basis on which fair values are estimated are provided in notes 14 and 29. Depreciation and amortization allocate the cost of assets and their components over their estimated useful lives on a systematic and rational basis. Estimating the appropriate useful lives of assets requires significant judgment and is generally based on estimates of the life characteristics of common assets. For determining purchase price allocations for business combinations the Company is required to estimate the fair value of acquired assets and obligations. Goodwill is measured as the excess of the fair value of the consideration transferred less the fair value of the identifiable assets acquired and liabilities assumed. Goodwill acquired in an acquisition is from the date of acquisition allocated to each of the CGUs that are expected to benefit from the acquisition. Estimates of fair value for the recoverable amount of CGUs undergoing impairment testing and for purchase price allocations for business combinations are primarily based on discounted cash flow projection techniques employing estimated future cash flows based on assumptions regarding the expected market outlook and cash flows from each CGU or asset. The cash flow estimates will vary with the circumstances of the particular assets or CGU and will be based on among other things the lives of the assets contract prices estimated future prices revenues and expenses including growth rates and inflation and required capital expenditures. Details of the key estimates used in assessing the recoverable amount of each CGU at the last impairment review date are provided in note 28. Market capitalization and comparative market multiples where available are used to corroborate management’s discounted cash flow projections. 93 Notes to the Consolidated Financial Statements (Tabular amounts in millions of Canadian dollars except share and per share amounts) CAPITAL POWER CORPORATION 3. Use of judgments and estimates: Critical judgments in applying accounting policies Non-financial assets Classification of arrangements which contain a lease Key sources of estimation uncertainty As noted in note 2(g) the Company has exercised judgment in determining whether the risks and rewards of its generation assets which are subject to a PPA are transferred to the contracted purchaser under the PPA in determining whether a lease exists and if so whether the lease should be treated as a finance or operating lease. Details of those PPAs which contain either finance or operating leases are provided in note 15. Financial instruments Non-financial assets
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their respective Coulomb radii. This effectively introduced a factor χ that increases with the total excitation energy thereby increasing the volume available to the fragments as the excitation energy increases. Recently we have used temperature-dependent fragment volumes V$_{j}$ obtained from self-consistent calculations of the structure of hot nuclei in the SMM[26]. In this case the normalization volume is temperature and configuration dependent and no longer reduces to χV$_{0}$ . We note that the reduction of the normalization volume due to exclusion of the fragment volumes can be justified in both the FBM and the SMM based on considerations similar to those used to obtain the van der Waals approximation to the equation of state of a near-ideal gas. Numerical calculations show the volume reduction to depend on both the masses and the number of fragments[32 33] but to be reasonably well described by the approximate form given above. The most important difference between the two models could be considered one of phi- losophy. The FBM is a model of nuclear decay while the SMM is an equilibrium statistical model whose configurations are identified with the fragmentation modes of the decaying nucleus. This difference is reflected in the fact that the SMM considers the configuration containing only one fragment the decaying nucleus that the FBM does not take into ac- count. This has been justified by characterizing the SMM decay as explosive and contrasting it to the slower compound nucleus (CN) decay which all residual fragments are assumed to undergo including the remaining fraction of the original (one-fragment) configuration after the initial fragmentation[22 23]. Unfortunately neither the FBM nor the SMM furnish decay widths or lifetimes that could be used to compare their characteristic time scales with those of CN decay. However one property accessible in both the FBM/SMM and the CN decay models is the average energy of the emitted particles. In the SMM it has been shown that collective flow due to radial expansion contributes little to the fragment energies [34]. The average relative asymptotic energy of the fragments of a two-body FBM/SMM decay (assuming fragment volumes independent of the temperature) can then be taken to be 3 T$_{0}$/ 2 + ˜ V$_{c}$ where ˜ V$_{c}$ is the energy gained due to the post-emission Coulomb repulsion of the two fragments. The Weisskopf approximation to CN emission of a particle of type c (two-body decay) furnishes a statistical weight that can be written as 2 πρ$_{0}$ ( ϵ$_{0}$ ) Γ$_{c}$ ( ϵ$_{0}$ ) = ∫ ∞ 0 dϵ$_{c}$ g$_{c}$ 2 µ$_{c}$ϵ$_{c}$ π ℏ 2 σ$_{c}$ ( ϵ$_{c}$ ) ρ$_{c}$ ( ε$_{0}$ − ϵ$_{c}$ − Q$_{c}$ ) (29) 12
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Year Ended December 31 2018 2017 2016 Net income $ 1 412 $ 1 282 $ 2 584 Other comprehensive income (loss) net of tax: Pension retiree medical and other postretirement benefits (117 ) (70 ) (358 ) Investments (3) (1) 7 Total other comprehensive loss net of tax (120 ) (71 ) (351 ) Total comprehensive income $ 1 292 $ 1 211 $ 2 233 See accompanying notes to consolidated financial statements. 82 AMERICAN AIRLINES GROUP INC. CONSOLIDATED STATEMENTS OF COMPREHENSIVE INCOME (In millions)
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84 UNITED TECHNOLOGIES CORPORATION NOTES TO CONSOLIDATED FINANCIAL STATEMENTS We provide service and warranty policies on our products and extend performance and operating cost guarantees beyond our normal service and warranty policies on some of our products particularly commercial aircraft engines. In addition we incur discretionary costs to service our products in connection with specific product performance issues. Liabilities for performance and operating cost guarantees are based upon future product performance and durability and are largely estimated based upon historical experience. Adjustments are made to accruals as claim data and historical experience warrant. The changes in the carrying amount of service and product warranties and product performance guarantees for the years ended December 31 2011 and 2010 are as follows: The following table summarizes the credit risk profile by creditworthiness category for aerospace long-term receivable balances at December 31 2011 and 2010: For 2011 the increase reflected within “Other” in the above table primarily related to the finalization of purchase accounting associated with the December 2010 acquisition of Clipper. In view of the risks and costs associated with developing new engines Pratt & Whitney has entered into certain collaboration arrangements in which sales costs and risks are shared. Sales generated from engine programs spare parts and aftermarket business under collaboration arrangements are recorded as earned in our financial statements. Amounts attributable to our collaborative partners for their share of sales are recorded as an expense in our financial statements based upon the terms and nature of the arrangement. Costs associated with engine programs under collaborative arrangements are expensed as incurred. Under these arrangements collaborators contribute their program share of engine parts incur their own production costs and make certain payments to Pratt & Whitney for shared or joint program costs. The reimbursement of the collaborators’ share of program costs is recorded as a reduction of the related expense item at that time. As of December 31 2011 the collaborators’ interests in all commercial engine programs ranged from 12% to 48% inclusive of a portion of Pratt & Whitney’s interests held by other participants. Pratt & Whitney is the principal participant in all existing collaborative arrangements. There are no individually significant collaborative arrangements and none of the partners exceed a 31% share in an individual program. In September 2011 Pratt & Whitney announced a new collaboration with JAEC and MTU to provide the PurePower PW1100G-JM engine for the Airbus A320neo program. Under the collaboration agreement MTU will hold an 18% share and be responsible for the engine’s low pressure turbine and We accrue for costs associated with guarantees when it is probable that a liability has been incurred and the amount can be reasonably estimated. The most likely cost to be incurred is accrued based on an evaluation of currently available facts and where no amount within a range of estimates is more likely the minimum is accrued. In accordance with the Guarantees Topic of FASB ASC we record a liability for the fair value of such guarantees in the balance sheet. We also have obligations arising from sales of certain businesses and assets including from representations and warranties and related indemnities for environmental health and safety tax and employment matters. The maximum potential payment related to these obligations is not a specified amount as a number of the obligations do not contain financial caps. The carrying amount of liabilities related to these obligations was $138 million and $139 million at December 31 2011 and 2010 respectively. For additional information regarding the environmental indemnifications see Note 17 to the Consolidated Financial Statements. * Represents IAE’s gross obligation; at December 31 2011 and 2010 our proportionate share of IAE’s obligations was 33%. NOTE 16: COLLABORATIVE ARRANGEMENTS (Dollars in millions) 2011 2010 Balance as of January 1 $ 1 136 $1 072 Warranties and performance guarantees issued 475 440 Settlements made (440) (379) Other 297 3 Balance as of December 31 $1 468 $ 1 136 NOTE 15: GUARANTEES We extend a variety of financial guarantees to third parties. As of December 31 2011 and 2010 the following financial guarantees were outstanding: 2011 2010 (Dollars in millions) Maximum Potential Payment Carrying Amount of Liability Maximum Potential Payment Carrying Amount of Liability IAE’s financing arrangements* (See Note 4) $989 $20 $992 $12 Commercial aerospace financing arrangements (See Note 4) 323 30 336 12 Credit facilities and debt obligations— unconsolidated subsidiaries (expire 2012 to 2034) 239 3 225 3 Performance guarantees 33 — 40 — Commercial customer financing arrangements — — 191 1 December 31 2011 December 31 2010 (Dollars in millions) Long-term trade accounts receivable Notes and leases receivable Long-term trade accounts receivable Notes and leases receivable A—(low risk collateralized / uncollateralized) $201 $ — $193 $ — B—(moderate risk collateralized / uncollateralized) 3 295 5 336 C—(high risk collateralized / uncollateralized) — 70 — 80 D—(in default uncollateralized) — — — — Total $204 $365 $198 $ 416
0financial_reports
Steam sales volumes increased 7.1 percent in 2003 compared with 2002 reflecting the impact of the cold weather in the 2003 winter period compared with the mild weather in the 2002 winter period. After adjusting for variations principally weather and billing days in each period and the August 2003 regional power outage steam sales increased 0.9 percent. Non-firm transportation of customer-owned gas to NYPA and electric generating plants decreased 34.8 percent in 2003 as compared with 2002 due to higher gas prices. In 2003 because of the relative prices of gas and fuel oil electric generating plants in the company’s gas service area utilized oil rather than gas for a significant portion of their generation. The decline in gas usage had minimal impact on earnings due to the application of a fixed demand charge for local transportation. At $1 billion taxes other than income taxes remain one of Con Edison of New York’s largest operating expenses. Con Edison of New York’s purchased gas cost increased $244 million in 2003 compared with 2002 due to higher unit costs and increased sales volumes for firm sales customers. Con Edison of New York’s gas operating income decreased $10 million in 2003 compared with 2002 reflecting primarily an increase in other operations and maintenance expense ($4 million – due primarily to a reduced net credit for pensions and other postretirement benefits) depreciation ($4 million) state and local taxes on revenues ($5 million) and income tax ($4 million). The increases in expenses were offset in part by higher net revenues (operating revenues less gas purchased for resale - $7 million). The principal components of and variations in taxes other than income taxes were: Con Edison of New York’s steam operating revenues increased $133 million and steam operating income decreased $1 million in 2003 compared with 2002. The higher revenues reflect high- er sales volumes due to the cold winter weather in 2003 as compared with the mild weather in 2002. The increase also includes higher fuel and purchased power costs ($124 million) in 2003 compared with 2002. The decrease in steam operating income reflects primarily higher income taxes ($10 million – due to higher taxable income and a lower level of removal costs in 2003) and operations and maintenance expense ($3 million – due to a reduced net credit for pensions and other postretire- ment benefits) offset in part by an increase in net revenues (operating revenues less fuel and purchased power costs) of $9 million and lower state and local taxes on steam revenues ($4 million). Con Edison of New York’s steam sales and deliveries in 2003 compared with 2002 were: Net interest charges decreased $16 million in 2003 compared with 2002 due primarily to the interest expense associated with a net federal income tax deficiency related to a prior period audit ($19 million) recorded in 2002. Other income (deductions) decreased $19 million in 2003 compared with 2002 reflecting $27 million of interest income on a federal income tax refund claim recorded in 2002 partially offset by an increase in income tax expense in 2003 as a result of the recognition in 2002 of income tax benefits relating to the September 2001 sale of the company’s nuclear generating unit. Effective January 2003 New York City increased Con Edison of New York’s annual property taxes by $94 million. Under the company’s rate agreements the company is deferring most of the property tax increase as a regulatory asset to be recovered fr om customers. Steam Other Income Net Interest Charges Taxes Other Than Income Taxes Millions of Pounds Twelve Months Ended December 31 December 31 Percent Description 2003 2002 Variation Variation General 729 600 129 21.5% Apartment house 7 845 7 022 823 11.7 Annual power 17 674 16 897 777 4.6 To t a l Sales 26 248 24 519 1 729 7.1% Increase/ (Millions of Dollars) 2003 2002 (Decrease) Pr operty taxes $1 651 $1 630 $21 State and local taxes related to revenue receipts 321 327 (6) Payr oll taxes 50 55 (5) Other taxes 18 28 (10) To tal $1 040(a) $1 040(a) $ - Con Edison Annual Report 2003 39 (a) Including sales tax on customers’ bills total taxes other than income taxes billed to (a) customers in 2003 and 2002 were $1 393 and $1 352 million respectively.
0financial_reports
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(Color online) Same as Fig. 5 but for $^{132}$Sn and $^{208}$Pb. FIG. 5: (Color online) The calculated single-particle energies for $^{16}$O and $^{40}$Ca by PC-PK1 in comparison with data [43] and those by DD-PC1 PC-F1 PC-LA and NL3*. 30
5scientific_articles
107 of 124 Construction of Giresun Wastewater Treatment Plant Tender Dossier Volume 3 Employer’s Requirements Section 8: Electrical Works 8.23.2 Tag numbering 8.23.3 Emergency control 8.23.4 Group control 8.23.5 Motor routine 1 8_Vol3_d4.3_Section 8 electrical works_en_GIR.rev8.doc A global function shall prevent more objects to start at the same time. The fault inputs will make the object go into fault. The actual fault will be indicated on the CMSsystem until the object is reset or as long as the fault is active. The object supervises that a running signal is coming within a specific time after a start command has been given. If the running signal is not present before the time has elapsed the object will go into fault and the supervision fault will be indicated. The function works both ways i.e. if the running signal is present when the start command is zero. It handles the following input signals or communication: The object can be in 3 different modes: The object is a standard motor routine handling motors with one direction. The group start object is a standard routine handling start/stop of a group of objects. (Ex. a pumping station includes all pumps level meters and automatic control) If appropriate an emergency control for a function should be developed. The contractor must analyse any risk and effects of any failures of the system. The automation shall react in an appropriate way of any failure such as: Individual signals and components are identified by means of tag numbers. Tag numbers must be unique and matching main station software as well as in electrical installations and documentation.  Missing/bad signal from a transmitter  Failure in a component  Auto  Manual (from local panel)  Operator (from operator station)  Auto  Thermal Faults  Moisture faults (if available)  Safety switch  Emergency stop  Actual current (motors with frequency and soft starter)  It handles the following output:  Start contactor
1government_tenders
63 US 7 511 179 B2 64 -continued -continued (S-80) (S-81) (S-82) (S-89) (S-90) (S-91) (S-92) (S-93) (S-94) (S-95) (S-96) (S-83) (S-84) (S-85) (S-86) (S-87) (S-88) (S-97) Q -cH > s x- I (CF2)1CF 2 H Q ’ -m s x- I (CF2)sCF 2 H Q -cH > s x- I CH2(CF2) 3 CF 3 Q -cH > s x- I CH2CF Q -cH > s x- I (CF2)1CF 3 (X) s I x- ccF2)6cFcF3 I CF 3 (X) s I x- ccF2J4cFcF3 I CF$_{3 }$ (X) s I x- cH2CCF2J3cF2H (X) s I x- cH2cF2H Q -cH > s x- I (CF2)sCF 3 (X) s I x- ccF2hCF2H Q -m s x- I CF$_{3 }$ (X) s I x- ccF2JscF2H (X) s I x- cH2CCF2J3cF3 (X) s I x- ccF2hCF3 s I x- cH2cH2ccF2)6cFcF3 I CF 3
4patents
Power Output: 100 hp continuous at 3200 rpm Displacement: 2.7 L Compression: 9:1 Weight: 210 lb Direct Drive Rear Light weight. Starter and 45 amp alternator Counterclockwise rotation Harmonic balancer Remanufactured case Remanufactured heads with new guides valves valve train intake Remanufactured cylinders New light weight aluminum cylinder - optional New high torque cam New CNC prop hub and safety shaft New Aeromax top cover and data plate Air cooled Six cylinders Dual ignition–single plug Normally aspirated CHT max: 475 F New forged pistons Balanced and nitrated crank shaft New hydraulic lifters New main/rod bearings New all replaceable parts New spark plug wiring harness Remanufactured dual ignition distributor with new points set and electronic module New oil pump New oil pan Engine service manual Aeromax 100 Engine Specifications Figure 11-20. Aeromax 100 engine specifications. Figure 11-21. Revmaster R-2300 engine. Figure 11-22. Hemispherical combustion chamber within the Revmaster R-2300 Heads. stroke crankshafts. The cylinder set also contains piston rings wrist pins and locks. The direct-drive R-2300 uses a dual CDI ignition with eight coil spark to eight spark plugs dual 20-amp alternators oil cooler and its proprietary Rev-Flo carburetor while introducing the longer cylinders that do not require spacers. The automotive-based bearings valves valve springs and piston rings (among others) make rebuilds easy and inexpensive. Great Plains Aircraft is one company that offers several configurations of the Volkswagen (VW) aircraft engine conversion. One very popular model is the front drive long block kits that offer a four-cycle four-cylinder opposed engine with horsepower ranges from approximately 60-100. [Figure 11-23] The long block engine kits which are the complete engine kits that are assembled in the field or can Great Plains Aircraft Volkswagen (VW) Conversions 11-15
2laws_and_regulations
Handling an Unexpected Halt of a Replica source to automatically identify and retrieve missing transactions. This option is set using a CHANGE REPLICATION SOURCE TO statement (from MySQL 8.0.23) or CHANGE MASTER TO statement (before MySQL 8.0.23). If the replica has multiple replication channels you need to set this option for each channel individually. For details of how GTID auto-positioning works see Section 17.1.3.3 “GTID Auto-Positioning” . When file position based replication is in use SOURCE_AUTO_POSITION=1 | MASTER_AUTO_POSITION=1 is not used and instead the binary log position or relay log position is used to control where replication starts. For a multithreaded replica setting relay_log_recovery = ON automatically handles any inconsistencies and gaps in the sequence of transactions that have been executed from the relay log. These gaps can occur when file position based replication is in use. (For more details see Section 17.5.1.34 “Replication and Transaction Inconsistencies” .) The relay log recovery process deals with gaps using the same method as the START REPLICA | SLAVE UNTIL SQL_AFTER_MTS_GAPS statement would. When the replica reaches a consistent gap-free state the relay log recovery process goes on to fetch further transactions from the source beginning at the replication SQL thread position. •Set relay_log_recovery = ON which enables automatic relay log recovery immediately following server startup. This global variable defaults to OFF and is read-only at runtime but you can set it to ON with the --relay-log-recovery option at replica startup following an unexpected halt of a replica. Note that this setting ignores the existing relay log files in case they are corrupted or inconsistent. The relay log recovery process starts a new relay log file and fetches transactions from the source beginning at the replication SQL thread position recorded in the applier metadata repository. The previous relay log files are removed over time by the replica’s normal purge mechanism. •Set relay_log_info_repository = TABLE which stores the replication SQL thread position in the InnoDB table mysql.slave_relay_log_info and updates it together with the transaction commit to ensure a record that is always accurate. This setting is the default from MySQL 8.0 and the FILE setting is deprecated. From MySQL 8.0.23 the use of the system variable itself is deprecated so omit it and allow it to default. If the FILE setting is used which was the default in earlier releases the information is stored in a file in the data directory that is updated after the transaction has been applied. This creates a risk of losing synchrony with the source depending at which stage of processing a transaction the replica halts at or even corruption of the file itself. With the setting relay_log_info_repository = FILE recovery is not guaranteed. •Set innodb_flush_log_at_trx_commit=1 which synchronizes the InnoDB logs to disk before each transaction is committed. This setting which is the default ensures that InnoDB tables and the InnoDB logs are saved on disk so that there is no longer a requirement for the information in the relay log regarding the transaction. Combined with the setting sync_relay_log=1 this setting further ensures that the content of the InnoDB tables and the InnoDB logs is consistent with the content of the relay log at all times so that purging the relay log files cannot cause unfillable gaps in the replica’s history of transactions in the event of an unexpected halt. •Set sync_relay_log=1 which instructs the replication I/O thread to synchronize the relay log to disk after each received transaction is written to it. This means the replica’s record of the current position read from the source’s binary log (in the applier metadata repository) is never ahead of the record of transactions saved in the relay log. Note that although this setting is the safest it is also the slowest due to the number of disk writes involved. With sync_relay_log > 1 or sync_relay_log=0 (where synchronization is handled by the operating system) in the event of an unexpected halt of a replica there might be committed transactions that have not been synchronized to disk. Such transactions can cause the recovery process to fail if the recovering replica based on the information it has in the relay log as last synchronized to disk tries to retrieve and apply the transactions again instead of skipping them. Setting sync_relay_log=1 is particularly important for a multi-threaded replica where the recovery process fails if gaps in the sequence of transactions cannot be filled using the information in the relay log. For a single-threaded replica the recovery process only needs to use the relay log if the relevant information is not available in the applier metadata repository. 3634
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Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de Fahrschüler-Ausbildungsordnung FahrschAusbO 2012 Ausfertigungsdatum: 19.06.2012 Vollzitat: "Fahrschüler-Ausbildungsordnung vom 19. Juni 2012 (BGBl. I S. 1318) die zuletzt durch Artikel 3 der Verordnung vom 16. November 2020 (BGBl. I S. 2704) geändert worden ist" Stand: Zuletzt geändert durch Art. 3 V v. 16.11.2020 I 2704 (+++ Textnachweis ab: 23.6.2012 +++) Auf Grund – des § 6 Absatz 3 § 11 Absatz 4 § 18 Absatz 4 des Fahrlehrergesetzes vom 25. August 1969 (BGBl. I S. 1336) die zuletzt durch Artikel 289 der Verordnung vom 31. Oktober 2006 (BGBl. I S. 2407) geändert worden sind verordnet das Bundesministerium für Verkehr Bau und Stadtentwicklung – des § 2 Nummer 1 des Fahrpersonalgesetzes in der Fassung der Bekanntmachung vom 19. Februar 1987 (BGBl. I S. 640) § 2 Nummer 1 zuletzt geändert durch Artikel 1 Nummer 1 des Gesetzes vom 6. Juli 2007 (BGBl. I S. 1270) verordnet das Bundesministerium für Verkehr Bau und Stadtentwicklung im Einvernehmen mit dem Bundesministerium für Arbeit und Soziales: § 1 Ziel und Inhalt der Ausbildung § 2 Art und Umfang der Ausbildung § 3 Allgemeine Ausbildungsgrundsätze § 4 Theoretischer Unterricht § 5 Praktischer Unterricht § 5a Praktische Ausbildung auf Kraftfahrzeugen mit Schaltgetriebe der Klasse B gemäß § 17a der Fahrerlaubnis-Verordnung § 5b Evaluierung § 6 Abschluss der Ausbildung § 7 Ausnahmen § 8 Ordnungswidrigkeiten § 9 Inkrafttreten Außerkrafttreten - Seite 1 von 36 - Inhaltsübersicht Eingangsformel Fußnote
2laws_and_regulations
P AR T I assessing the need for the valuation allowance we cannot assure you that we would not need to increase the valuation allowance to cover additional deferred tax assets that may not be realizable. Any increase in the valuation allowance could have a material adverse effect on our income tax provision and net income in the period in which such determination is made. We had a valuation allowance of NT$182 million (US$6.0 million) on our deferred tax asset balance as of December 31 2011. We do not have a full valuation allowance on the deferred tax asset as we believe these benefits will be partially realizable based on our projection of future operating income. If we experience a significant decrease in our future operating income our ability to realize the deferred tax assets could be negatively impacted and thus an increase in the valuation allowance might be required. Any tax credits arising from purchases of machinery equipment and technology research and development expenditures personnel training and investments in important technology based enterprises are recognized using the flow through method. Adjustments of prior years’ tax liabilities are added to or deducted from the current year’s tax provision. Under R.O.C. GAAP income taxes of 10% on undistributed earnings are recorded in the year of stockholders approval which is the year subsequent to the year the earnings are generated. Under US GAAP the 10% tax on unappropriated earnings is accrued during the period the earnings arise and adjusted to the extent that distributions are approved by the stockholders in the following year. Our Financial Reporting Obligations Effective from January 1 2007 we adopted a guidance prescribing the recognition threshold and measurement attribute for the financial statement recognition and measurement of a tax position taken or expected to be taken in a tax return under U.S. GAAP. This guidance also provides guidance on derecognition classification interest and penalties disclosure and transition. The evaluation of a tax position in accordance with this guidance is a two step process. The first step is recognition where we evaluate whether an individual tax position has a likelihood of greater than 50% of being sustained upon examination based on the technical merits of the position including resolution of any related appeals or litigation processes. For tax positions that are currently estimated to have a less than 50% likelihood of being sustained zero tax benefit is recorded. For tax positions that have met the recognition threshold in the first step we perform the second step of measuring the benefit to be recorded. The actual benefits ultimately realized may differ from the estimates. The adoption of this guidance did not have a material impact on our results of operation financial position and cash flows. We did not identify significant unrecognized tax benefits for the year ended December 31 2009 2010 and 2011. It is highly unlikely that we will incur any interests or penalties related to potential underpaid income tax expenses. Our ongoing financial reporting in our Form 20-F annual reports and interim financial reporting furnished to the SEC on Form 6-K had been based on U.S. GAAP through fiscal year 2007. Beginning with our first quarter interim financial report furnished on Form 6-K and our Form 20-F annual report for fiscal year 2008 we prepared our financial statements under R.O.C. GAAP with reconciliations to U.S. GAAP. A. Operating Results The following table sets forth our revenues operating costs and expenses income from operations and other financial data for the periods indicated. 74
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PLAYERS SECTION VI - WTA FINALS AND WTA ELITE TROPHY (b) the result of a default or retirement for which the defaulting or retiring player or team has won a set is two (2) sets won and one (1) set lost for the advancing player or team but games won or lost in such matches do not count in calculating the percentage of games won. ii. A player or team who retires during a round robin match because of illness or injury may continue in the competition if the Tournament Physician approves. iii. A player or team who withdraws from any round robin match is eliminated from the competition and a Finals Alternate or Finals Alternate Team will replace her or them. If no Finals Alternate or Finals Alternate Team is available as a replacement the non- withdrawing player or team in such match receives a walkover win for such match. b. Final Standings i. Greatest number of wins; then ii. Greatest number of matches played; then iii. Head-to-head results if only two (2) players or teams are tied; or iv. If three (3) players or teams are tied: (a) Highest percentage of sets won (the doubles match tie-break counts as one (1) set); if after the calculation two (2) players or teams remain tied head-to-head results; then (b) If after applying (a) all three (3) players or teams remain tied a player or team completing less than all three (3) round robin matches is automatically eliminated; if two (2) players or teams remain tied head-to-head results; then The first of the following methods that applies determines the final standings of each group in the round robin competition: (c) If after applying (a) and (b) all three (3) players or teams remain tied highest percentage of games won (the doubles match tie- break counts as one (1) game); if after the calculation two (2) players or teams remain tied head-to-head results; then (d) If after applying (a) (b) and (c) all three (3) players or teams remain tied the Porsche Race to Shenzhen Leaderboard. 91
3manuals
The mongo shell provides a JavaScript API for database operations. In the mongo shell db is the variable that references the current database. The variable is automatically set to the default database test or is set when you use the use <db> to switch current database. The following table displays some common JavaScript operations: Basic Shell JavaScript Operations MongoDB Documentation Release 3.0.4 For more information on performing operations in the shell see: Changed in version 2.2. The mongo shell provides most keyboard shortcuts similar to those found in the bash shell or in Emacs. For some functions mongo provides multiple key bindings to accommodate several familiar paradigms. The following table enumerates the keystrokes supported by the mongo shell: Keyboard Shortcuts • MongoDB CRUD Concepts (page 60) • Read Operations (page 60) • Write Operations (page 73) • js-administrative-methods 279 5.2. Administration Tutorials JavaScript Database Operations Description db.auth() If running in secure mode authenticate the user. coll = db.<collection> Set a specific collection in the current database to a vari- able coll as in the following example: coll = db.myCollection; You can perform operations on the myCollection using the variable as in the following example: coll.find(); find() Find all documents in the collection and returns a cursor. See the db.collection.find() and Query Docu- ments (page 96) for more information and examples. See Cursors (page 64) for additional information on cur- sor handling in the mongo shell. insert() Insert a new document into the collection. update() Update an existing document in the collection. See Write Operations (page 73) for more information. save() Insert either a new document or update an existing doc- ument in the collection. See Write Operations (page 73) for more information. remove() Delete documents from the collection. See Write Operations (page 73) for more information. drop() Drops or removes completely the collection. createIndex() Create a new index on the collection if the index does not exist; otherwise the operation has no effect. db.getSiblingDB() Return a reference to another database using this same connection without explicitly switching the current database. This allows for cross database queries. See How can I access different databases temporarily? (page 756) for more information.
3manuals
arXiv:1001.1226v2 [cond-mat.mtrl-sci] 21 Jan 2010 Realization of giant magnetoelectricity in helimagnets We show that low field magnetoelectric (ME) properties of helimagnets Ba 0 . 5 Sr 1 . 5 Zn 2 (Fe 1$_{−}$ x Al x ) 12 O 22 can be efficiently tailored by Al-substitution level. As x in- creases the critical magnetic field for switching electric polarization is systematically reduced from ∼ 1 T down to ∼ 1 mT and the ME susceptibility is greatly enhanced to reach a giant value of 2.0 × 10 4 ps/m at an optimum x = 0.08. We find that control of nontrivial orbital moment in the octahedral Fe sites through the Al-substitution is crucial for fine tuning of magnetic anisotropy and obtaining the conspicuously improved ME characteristics. PACS numbers: 75.80.+q 77.80.Fm 71.45.Gm 75.30.Gw Sae Hwan Chun 1 Yi Sheng Chai 1 Yoon Seok Oh 1 Deepshikha Jaiswal-Nagar 1 So Young Haam 1 Ingyu Kim 1 Bumsung Lee 1 Dong Hak Nam 1 Kyung-Tae Ko 2 Jae-Hoon Park 2 Jae-Ho Chung 3 and Kee Hoon Kim 1 $^{1}$FPRD Department of Physics and Astronomy Seoul National University Seoul 151-747 South Korea $^{2}$Department of Physics & Division of Advanced Materials Science POSTECH Pohang 790-784 South Korea $^{3}$Department of Physics Korea University Seoul 136-713 South Korea In recent years extensive researches on multiferroics have been performed with motivations to understand the nontrivial cross-coupling mechanism between magnetism and ferroelectricity as well as to search for new materials applicable in next-generation devices [1–8]. Numerous studies have focused particularly on the class of so-called magnetic ferroelectrics [1–3 9 10] in which ferroelec- tricity is induced by magnetic order through either in- verse Dzyaloshinskii-Moriya effects [6–8] or the exchange striction mechanism [10]. Although dramatic variation of electric polarization P with magnetic field B often re- alized in the magnetic ferroelectrics [3] might be useful for application the phenomena occur mostly at low tem- peratures [1 2 9 10] and related ME susceptibility is yet too small [5]. Hence it is a longstanding challenge in the research of multiferroics to improve both the operating temperature [11 12] and the ME sensitivity [13–15]. The hexaferrite Ba 0 . 5 Sr 1 . 5 Zn 2 Fe 12 O 22 (BSZFO) with helical spin order is currently a unique candidate that can show the B -induced ferroelectricity above room tempera- ture up to ∼ 340 K [12]. However at 300 K its ferroelec- tric (FE) phase is expected to emerge at B ∼ 1 T which is too high for memory applications. Moreover its ME coupling is rather weak; the MES α$_{ME}$ ≡ µ$_{0}$ dP dB at 30 K shows a maximum value of ∼ 1.3 × 10 3 ps/m at B ∼ 400 mT [12] which is one or two orders of magnitude smaller than the highest α$_{ME}$ ∼ 10 4 - 10 5 ps/m realized in hetero- geneous films [13] or strain-coupled composites [5 14]. When Zn is replaced by Mg to form a Mg 2 Y-type hex- aferrite Ba 2 Mg 2 Fe 12 O 22 the critical magnetic field for inducing P becomes extremely low ∼ 30 mT [15 16]. On the other hand a maximum operation temperature of the Mg 2 Y-type hexaferrite is expected to be lower than 195 K. Moreover a microscopic understanding for the low- ered critical magnetic field remains unclear. Therefore systematic studies are further required to understand the origin of the intricate ME effect and improve multiferroic properties in the hexaferrite system. In this letter we demonstrate that Al-substituted Single crystals of Ba 0 . 5 Sr 1 . 5 Zn 2 (Fe 1$_{−}$ $_{x}$Al$_{x}$ ) 12 O 22 were grown from Na 2 O-Fe 2 O 3 flux in air [17]. Crystals were cut into a rectangular form for electric polarization P measurements along the ab -plane while B was applied along the direction normal to the P vector in the ab - plane. Before the ME current measurements each spec- imen was electrically poled in its paraelectric state for BSZFO i.e. Ba 0 . 5 Sr 1 . 5 Zn 2 (Fe 1$_{−}$ $_{x}$Al$_{x}$ ) 12 O 22 greatly im- proves the multiferroic characteristics resulting in the highest α$_{ME}$ of single-phase multiferroics near-zero mag- netic field. We find that predominant substitution of Al ions into octahedral Fe sites with nontrivial orbital mo- ment is crucial for fine tuning of the magnetic anisotropy and thus for tailoring the ME coupling. FIG. 1. (a) Crystal structure of the Zn 2 Y type-hexaferrite Ba 0 . 5 Sr 1 . 5 Zn 2 (Fe 1$_{−}$ x Al x ) 12 O 22 that has alternating stacks of magnetic S and L blocks along the c -axis. Schematic illus- tration of rotating magnetic moments in the L ( ⃗ µ$_{L}$ ) and S blocks ( ⃗ µ$_{S}$ ) in the (b) helical ( x = 0.00) and (c) heliconical ( x = 0.08) phases under in-plane B = 0 T and 10 mT. ⃗ k 0 is the spin modulation wave vector parallel to [001]. (c) (b) [100] [010] [001] (a) S$_{4}$ L$_{3}$ S$_{3}$ S$_{2}$ S$_{1}$ L$_{2}$ L$_{1}$ S$_{2}$ S$_{1}$ L$_{2}$ L$_{1}$ tetrahedral site octahedral off-centered octahedral x = 0.00 x = 0.08 B = 0 B = 10 mT P = 0 P ≠ 0 B = 0 B = 10 mT k$_{0}$ S$_{2}$ S$_{1}$ L$_{2}$ L$_{1}$ µ$_{S}$ µ$_{L}$ P = 0 P = 0 k$_{0}$ k$_{0}$ k$_{0}$ Ba$_{0.5}$Sr$_{1.5}$Zn$_{2}$(Fe$_{1-}$$_{x}$$_{ }$Al$_{x}$)$_{12}$O$_{22}$
5scientific_articles
[0049] FIG. 5 illustrates an example user interface displaying a visualization of a data graph such as a provenance chain. A user may select a node with the data graph (for example via an input device) to view additional information of the node (features of the node). Furthermore a user can query or filter on these features. For example in FIG. 5 a user can query or filter on an entity identifier (stock keeping unit (SKU)) 505 a stage identifier 510 (for example manufacturing packaging and assembly) a supplier identifier 515 and a date range 520. As noted above in some embodiments additional features are available for use in querying filtering and pivoting that were identified through the expansion process such as for example country of origin weather traffic and the like. Accordingly using this expanded information a user can query on a particular country manufacturing facility temperature air quality employee satisfaction and the like. Also in some embodiments a user can access information regarding the source of particular data included in the provenance chain such as viewing whether information was included in the original provenance chain or was inferred and a source where the data (inferred or otherwise) was retrieved or generated from (including for example details of equipment used to by the source a location of the source a certification level of the source the date the source was last accessed or last updated an algorithm used to generate the data). For example when the provenance chain includes temperature information details regarding the sensors used to detect the temperatures (make or model) and the location of such sensors may be accessible through the provenance chain. [0050] Accordingly embodiments described herein create navigable data graphs such as provenance chains that rather than being limited to arbitrary spaces or dimensions that are limited based on direct data recorded for an entity are dynamic and include expanded information from various often disconnected data sources to improve the completeness and usefulness of the data graph to a end user. For example when a provenance chain relates to a product an expanded version of this chain generated using the methods and systems described herein may allow a user to not only trace a detected contamination back to source but also identify other products that may have been effected as well as identify causes for the contamination such as particular weather conditions working conditions or the like. In particular as described above the systems and methods identify various dimensions that a data graph may be rendered in or related to and collect the information needed to provide such a rendering from one or more data sources. These relationships (dimensions) are stored with the data graph which allows a user to quickly and efficiently (in terms of computing resource and bandwidth usage) query filter pivot and generally
4patents
5 Supplemental cash flow information (note 17) See accompanying notes to combined financial statements. H&R REAL ESTATE INVESTMENT TRUST H&R FINANCE TRUST Combined Statements of Cash Flows (In thousands of dollars) Years ended December 31 2010 and 2009 2010 2009 Cash provided by (used in): Operations: Net earnings 172 348 $ 86 525 $ Items not affecting cash: Rent amortization (notes 13 and 24) 3 912 3 931 Depreciation and amortization (notes 15 and 24) 125 175 130 409 Gain on sale of income properties (note 24) (3 576) (10 649) Gain on extinguishment of debt (note 3) (17 296) - Impairment loss on income properties (note 3) 14 862 14 764 Future income tax recovery (note 23) (123 303) (9 613) Unrealized (gain) loss on derivative instruments (notes 7 9(b) and 19(c)) 5 521 (3 463) Loss on repayment of debentures (note 8(f)) 38 834 - Effective interest rate accretion (notes 14 and 24) 11 453 5 844 Unrealized loss on foreign exchange 6 779 20 487 Unit-based compensation (note 11(a)) 1 225 535 Net earnings attributable to non-controlling interest (note 10) 6 421 3 670 Change in other non-cash operating items (note 17) 822 (3 499) 243 177 238 941 Financing: Bank indebtedness 75 485 (99 374) Mortgages payable: New mortgages payable 35 831 82 134 Principal repayments (107 273) (143 553) Proceeds from issuance of debentures payable (notes 8(d) and 8(e)) 445 924 510 352 Redemption of warrants (note 8(f)) - (185 714) Repayment of debentures payable (note 8(f)) (227 752) - Proceeds from issuance of units net 14 829 13 781 Distributions to unitholders (note 11(b)) (99 426) (93 811) Distributions to non-controlling interest (note 10) (4 282) (3 915) 133 336 79 900 Investments: Properties under development (463 362) (313 511) Income properties: Net proceeds on disposition of income properties 22 183 96 258 Acquisitions (note 3) (80 422) - Capital expenditures (15 371) (10 090) Mortgages and amounts receivable 60 789 15 821 Restricted cash (note 5) 895 (15 497) (475 288) (227 019) Increase (decrease) in cash and cash equivalents (98 775) 91 822 Cash and cash equivalents beginning of year (notes 6 and 24) 109 505 17 683 Cash and cash equivalents end of year (notes 6 and 24) 10 730 $ 109 505 $
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Chapter 6. Modules 44 Python Tutorial Release 3.9.5 6.2 Standard Modules 6.1.3 “Compiled” Python files To speed up loading modules Python caches the compiled version of each module in the$_{__pycache__}$ directory under the name$_{module.}$ version .pyc where the version encodes the format of the compiled file; it generally contains the Python version number. For example in CPython release 3.3 the compiled version of spam.py would be cached as __pycache__/spam.cpython-33.pyc . This naming convention allows compiled modules from different releases and different versions of Python to coexist. Python checks the modification date of the source against the compiled version to see if it’s out of date and needs to be recompiled. This is a completely automatic process. Also the compiled modules are platform-independent so the same library can be shared among systems with different architectures. Python does not check the cache in two circumstances. First it always recompiles and does not store the result for the module that’s loaded directly from the command line. Second it does not check the cache if there is no source module. To support a non-source (compiled only) distribution the compiled module must be in the source directory and there must not be a source module. Some tips for experts: Python comes with a library of standard modules described in a separate document the Python Library Reference (“Library Reference” hereafter). Some modules are built into the interpreter; these provide access to operations that are not part of the core of the language but are nevertheless built in either for efficiency or to provide access to operating system primitives such as system calls. The set of such modules is a configuration option which also depends on the underlying platform. For example the$_{winreg}$ module is only provided on Windows systems. One particular module deserves some attention: $_{sys}$ which is built into every Python interpreter. The variables$_{sys.ps1}$ and sys.ps2 define the strings used as primary and secondary prompts: These two variables are only defined if the interpreter is in interactive mode. The variable$_{sys.path}$is a list of strings that determines the interpreter’s search path for modules. It is initialized to a default path taken from the environment variable$_{PYTHONPATH}$ or from a built-in default if$_{PYTHONPATH}$ is not set. You can modify it using standard list operations: >>> import sys >>> sys.path.append( '/ufs/guido/lib/python ') >>> import sys >>> sys.ps1 '>>> ' >>> sys.ps2 '... ' >>> sys.ps1='C>' C> print('Yuck!') Yuck! C> • There is more detail on this process including a flow chart of the decisions in PEP 3147 • The module$_{compileall}$ can create .pyc files for all modules in a directory. • A program doesn’t run any faster when it is read from a$_{.pyc}$ file than when it is read from a$_{.py}$file; the only thing that’s faster about$_{.pyc}$ files is the speed with which they are loaded. • You can use the$_{-O}$or$_{-OO}$switches on the Python command to reduce the size of a compiled module. The$_{-O}$ switch removes assert statements the -OO switch removes both assert statements and __doc__ strings. Since some programs may rely on having these available you should only use this option if you know what you’re doing. “Optimized” modules have an$_{opt-}$ tag and are usually smaller. Future releases may change the effects of optimization.
3manuals
SYSTEM TRANSMISSION LINES AND FACILITY SITING TITLE TO PROPERTY CONSTRUCTION PROGRAM POTENTIAL UNINSURED LOSSES ITEM 3. LEGAL PROCEEDINGS For a discussion of material legal proceedings see Note 6 - Commitments Guarantees and Contingencies included in the 2019 Annual Report for additional information. Some potential losses or liabilities may not be insurable or the amount of insurance carried may not be sufficient to meet potential losses and liabilities including liabilities relating to damage to AEP’s generation plants and costs of replacement power. Unless allowed to be recovered through rates future losses or liabilities which are not completely insured could reduce net income and impact the financial conditions of AEP and other AEP System companies. For risks related to owning a nuclear generating unit see the “Nuclear Contingencies” section of Note 6 - Commitments Guarantees and Contingencies included in the 2019 Annual Report for additional information. With input from its state utility commissions the AEP System continuously assesses the adequacy of its transmission distribution generation and other facilities to plan and provide for the reliable supply of electric power and energy to its customers. In this assessment process assumptions are continually being reviewed as new information becomes available and assessments and plans are modified as appropriate. AEP forecasts approximately $6.3 billion of construction expenditures for 2020. Capital expenditures related to North Central Wind Energy Facilities are excluded from this budgeted amount. Estimated construction expenditures are subject to periodic review and modification and may vary based on the ongoing effects of regulatory constraints environmental regulations business opportunities market volatility economic trends weather and the ability to access capital. See the “Budgeted Capital Expenditures” section of Management’s Discussion and Analysis of Financial Condition and Results of Operations included in the 2019 Annual Report for additional information. Laws in the states of Arkansas Indiana Kentucky Louisiana Michigan Ohio Tennessee Texas Virginia and West Virginia require prior approval of sites of generating facilities and/or routes of high-voltage transmission lines. AEP has experienced delays and additional costs in constructing facilities as a result of proceedings conducted pursuant to such statutes and in proceedings in which AEP’s operating companies have sought to acquire rights-of-way through condemnation. These proceedings may result in additional delays and costs in future years. The AEP System’s generating facilities are generally located on lands owned in fee simple. The greater portion of the transmission and distribution lines of the AEP System has been constructed over lands of private owners pursuant to easements or along public highways and streets pursuant to appropriate statutory authority. The rights of AEP’s public utility subsidiaries in the realty on which their facilities are located are considered adequate for use in the conduct of their business. Minor defects and irregularities customarily found in title to properties of like size and character may exist but such defects and irregularities do not materially impair the use of the properties. AEP’s public utility subsidiaries generally have the right of eminent domain which permits them if necessary to acquire perfect or secure titles to or easements on privately held lands used or to be used in their utility operations. Legislation in Ohio and Virginia has restricted the right of eminent domain previously granted for power generation purposes. 48
0financial_reports
¯ ψ ϵ For small ϵ the solid free-energy density can be well ap- proximated by only considering the contribution of the 〈 111 〉 and 〈 200 〉 RLVs. Accordingly the crystal density field is expanded in the form where we have used the fact that all density waves have the same amplitude in the crystal ( | A$_{i}$ | = A$_{s}$ and | B$_{i}$ | = B$_{s}$ ) and the magnitude of the principal RLVs are unity in our dimensionless units so ( q = 1 $_{/}$√$_{3). The parameters}$ A$_{s}$ and B$_{s}$ are solved by substituting Eq. (27) into Eqs. (19) and (20) and by minimizing the resulting free-energy F with respect to A$_{s}$ and B$_{s}$ . This minimization yields the solid free energy density where A$_{s}$ and B$_{s}$ are themselves functions of ¯ ψ . The co- existence densities ¯ ψ$_{s}$ and ¯ ψ$_{l}$ are computed numerically using the standard common tangent construction which consists of equating the chemical potentials f ′ $_{s}$( ¯ ψ$_{s}$ ) = f ′ $_{l}$( ¯ ψ$_{l}$ ) = µ$_{E}$ and grand potentials f$_{s}$ ( ¯ ψ$_{s}$ ) − µ$_{E}$ ¯ ψ$_{s}$ = f$_{l}$ ( ¯ ψ$_{l}$ ) − µ$_{E}$ ¯ ψ$_{l}$ of the two phases. It is also necessary to compute the solid free-energy curve for bcc since the latter can have a lower free-energy than fcc for some re- gions of the phase diagram. The bcc free-energy density was obtained by expanding the crystal density field us- ing a one-mode approximation which only involves 〈 110 〉 RL Vs as in Ref. [14] and substituting this expansion into the t wo-mode model defined by Eqs. (19) and (20). An example of the phase diagram for R$_{1}$ = 0 . 05 is sho wn in Fig. 1 where we also show for completeness the hexagonal and stripe phases. As desired we obtain a large ϵ range of fcc-liquid coexistence. For small ϵ how- ever bcc becomes favored over fcc. A common tangent construction using fcc and bcc free-energy curves shows that the density range of bcc-fcc coexistence is extremely narrow for small values of ϵ and cannot be resolved on the scale of Fig. 1. As will be explained later in sec- tion III C the range of ϵ where bcc is favored depends on the value of R$_{1}$ . In the limit R$_{1}$ ≫ 1 the two-mode model reduces to the standard one-mode model after a simple rescaling of parameters which can be easily seen by comparing Eqs. (20) and (25). Hence increasing R$_{1}$ reduces the contribution of the second mode. Conversely reducing R$_{1}$ increases the contribution of this mode and tends to favor the fcc structure which extends to smaller ϵ for smaller R$_{1}$ . In the extreme case where R$_{1}$ = 0 the region of fcc-liquid coexistence extends all the way to vanishingly small ϵ as shown in Fig. 2. Student Version of MATLAB The phase diagram of the two-mode PFC model is ob- tained by computing the free-energy density as a func- tion of the mean density ¯ ψ in solid and liquid denoted by f$_{s}$ ( ¯ ψ ) and f$_{l}$ ( ¯ ψ ) respectively and then using a stan- dard common tangent construction to obtain equilibrium values of ¯ ψ in solid ( ¯ ψ$_{s}$ ) and liquid ( ¯ ψ$_{l}$ ). Since the density is constant in the liquid f$_{l}$ is ob- tained directly from Eq. (20) FIG. 1: Phase diagram of the two-mode PFC model for R$_{1}$ = 0 . 05 computed using two-mode and one-mode expansions of the crystal density field for fcc and bcc respectively. Tuesday January 5 2010 FIG. 2: Phase diagram of the two-mode PFC model showing only the fcc-solidus and liquidus for the case R$_{1}$ = 0 where fcc-liquid coexistence extends to vanishingly small ϵ . B. Phase diagram ψ ( ⃗ r ) ≈ ¯ ψ + ∑ ⃗ K$_{i}$ = 〈 111 〉$^{A$_{i}$}$ e i ⃗ K$_{i}$ · ⃗ r + ∑ ⃗ K$_{j}$ $^{′}$= 〈 200 〉$^{B$_{j}$}$ e i ⃗ K$_{j}$ $^{′}$· ⃗ r ≈ ¯ ψ + 8 A$_{s}$ cos qx cos qy cos qz +2 B$_{s}$ (cos 2 qx + cos 2 qy + cos 2 qz ) (27) f$_{s}$ ( ¯ ψ$_{s}$ ) = 4 ( − ϵ + 3 ¯ ψ 2 $_{s}$) A 2 s + 3 ( − ϵ + 3 ¯ ψ 2 s + R$_{1}$ 9 ) B 2 s +72 ¯ ψ$_{s}$A 2 $_{s}$B$_{s}$ + 144 A 2 $_{s}$B 2 s + 54 A 4 s + 45 2 B 4 s − ϵ 2 ¯ ψ 2 s + R$_{1}$ 2 ¯ ψ 2 s + 8 9 ¯ ψ 2 s + 1 4 ¯ ψ 4 $_{s}$ (28) f$_{l}$ ( ¯ ψ$_{l}$ ) = − ( ϵ − 16 9 − R$_{1}$ ) ¯ ψ 2 l 2 + ¯ ψ 4 l 4 . (26) − 0.3 − 0.25 − 0.2 − 0.15 − 0.1 − 0.05 0 0 0.05 0.1 0.15 ¯ ψ ϵ fcc liquid 5
5scientific_articles
Aug. 27 2020 3 US 2020/0268679 Al [0024] The nanoparticles can have a Z-average particle size of from 10 nm to 1000 nm from 25 nm to 1200 nm from 50 nm to 500 nm from 75 nm to 400 nm from 100 nm to 350 nm from 100 nm to 250 nm or from 100 nm to 150 nm. The nanoparticles can have a polydispersity index (PDI) of from 0.06 to 0.5 from 0.07 to 0.34 from 0.08 to 0.27 from 0.1 to 0.2 or from 0.12 to 0.18. [0025] The API and a supplemental hydrophobic com› pound can be co-encapsulated in the nanoparticles. For example the supplemental hydrophobic compound can be a therapeutic an imaging agent or an agrochemical com› pound. [0026] The API can include gentamycin polymyxin B mastoporan 7 sub5 LL37 colistin ecumicin OZ439 oval› bumin or lysozyme. The API can include an antimicrobial small molecule or example an antimicrobial small mol› ecule having a molecular weight of less than 1000 Da. The API can include an aminoglycoside for example a 4 6- disubstituted deoxystreptamine trisaccharide. The API can include an oligopeptide such as a linear oligopeptide or a cyclic oligopeptide which can have a molecular weight of from 1000 Da to 2000 Da. The API can include a protein such as an anionic protein or a cationic protein which can have a molecular weight of greater than 2000 Da. [0027] The IP reagent can include sodium dodecyl sulfate (SDS) sodium decyl sulfate (DS) sodium dodecylbenzene sulfonate (DBS) sodium myristate (MA) sodium oleate (OA) pamoic acid disodium salt (PA) vitamin E succinate or sodium dextran sulfate (DXS). The counterion can include dodecyl hydrogen sulfate decyl hydrogen sulfate dodecylbenzene sulfonic acid myristic acid oleic acid pamoic acid vitamin E succinic acid or dextran hydrogen sulfate. The counterion can include a fatty acid an alkyl hydrogen sulfate an alkylsulfonic acid or an alkyl quater› nary ammonium cation. [0028] The polymer can include hydroxypropyl methyl› cellulose acetate succinate (HPMCAS) polystyrene-block› polyethylene glycol (PS-b-PEG) or polycaprolactone› block-polyethylene glycol (PCL-b-PEG). The polymer can include a block copolymer for example an amphiphilic block copolymer. The block copolymer can have a molecu› lar weight of about 10 kDa or less. BRIEF DESCRIPTION OF THE DRAWINGS [0029] FIG. 1 illustrates the Mechanism of ion pairing› based Flash NanoPrecipitation. FNP of pre-ion paired APL Hydrophilic active pharmaceutical ingredients are created as a hydrophobic salt by pre-pairing the API with a hydropho› bic counterion. Pre-ion pairedAPis are dissolved in organic solvent alongside an amphiphilic block-copolymer and rap› idly micromixed against water. Hydrophobic API ion pairs precipitate into NCs and self-assemble into NCs. FNP with in situ ion pairing. Hydrophilic APis are dissolved in water and rapidly micromixed against organic solvent containing a hydrophobic API counterion and an amphiphilic block› copolymer. Ion pairing of the API occurs during mixing producing a hydrophobic API ion pair that precipitates in the presence of an amphiphilic block-copolymer resulting in the formation of NCs. [0030] FIG. 2 shows the chemical structure of gentamicin (at top) and polymyxin B (at bottom) hydrophilic active pharmaceutical ingredients tested within the study presented herein. Gentamicin (Log P=-4.21) is an aminoglycoside having a molecular weight of 478 Da that functions by [0038] FIG. 7A provides a graph showing release rates (fraction released as a function of time) of polymyxin B NCs when using 1: 1 API to IP charge ratio for the IPs sodium dodecyl sulfate (SDS) sodium dodecylbenzene sulfonate (DBS) and sodium oleate (OA). [0037] FIG. 6C provides a graph of size distributions of NPs formed with in situ ion pairing of polymyxin B using the IPs sodium dodecyl sulfate (SDS) sodium dodecylben› zene sulfonate (DBS) pamoic acid disodium salt (PA) and sodium oleate (OA). Compositions of NC formulations are given in Table 1. [0036] FIG. 6B provides a graph of size distributions of NPs formed using polymyxin B as a pre-formed API:IP complex using the IPs sodium dodecyl sulfate (SDS) decyl sulfate (DS) sodium dodecylbenzene sulfonate (DBS) and pamoic acid disodium salt (PA). Compositions of NC for› mulations are given in Table 1. [0035] FIG. 6A provides a graph of size distributions of NPs formed using gentamycin as a pre-formed API:IP complex using the IPs sodium dodecyl sulfate (SDS) decyl sulfate (DS) sodium dodecylbenzene sulfonate (DBS) and pamoic acid disodium salt (PA). Compositions of NC for› mulations are given in Table 1. [0034] FIG. SB provides a graph illustrating the modeling of API precipitation conditions by utilizing equation (10). The fraction of API that is precipitated with varying satu› ration solubilities of the API:IP complex and by varying the amount of API in the reaction. The amounts of API and IP included in the reaction are at a one to one ratio. [API]$_{0 }$ has dimensions of M. Precipitation yields can be increased by decreasing complex saturation solubility by increasing com› plexation strength or by increasing the concentration of the reaction. [0033] FIG. SA provides a graph illustrating the modeling of API precipitation conditions by utilizing equation (10). The fraction of API that is precipitated with varying satu› ration solubilities of the API:IP complex and with varying tendencies of complex formation ( complexation strength) is shown. Saturation solubility is noted with [API:IP]sat and has units of mo! L- 1 . Complexation strength is noted with Ks and has dimensions of mo1- 1 L- 1 . The amounts of API and IP included in the reaction are at a one-to-one ratio at 1 M. [0032] FIG. 4 provides a graph presenting the results of screening of ion pair (IP) properties for FNP-based NC assembly with polymyxin. The physical properties (pKa and c Log P) of ion pairs that failed to precipitate APis (dia› monds) that precipitated APis but failed to produce NCs (circles) and that precipitated APis and produced NCs (squares) are shown. The following IPs that precipitated APis and produced NCs are labeled: sodium oleate (OA) pamoic acid disodium salt (PA) sodium dodecylbenzene sulfonate (DBS) and sodium dodecyl sulfate (SDS). [0031] FIG. 3 shows ion pairs screened and tested within the study presented herein. A wide variety of anionic salts were used and paired against gentamicin and polymyxin B. Salts that could precipitate APis into NCs in the FNC process are named in bold. Salts that precipitated APis out of water but not into NCs in the FNC process are italicized. inhibiting protein synthesis. Polymyxin B (Log P=-5.62) is a macrocyclic cationic peptide having a molecular weight of 1302 Da that functions by forming pores on cell membranes. Both gentamicin and polymyxin B are active against gram› negative bacteria.
4patents
Nov. 24 2016 US 2016/0342090 Al 16 -continued 0 j: j: a O 0 Rx Rx ~o ~ 0 -continued
4patents
expect. Loss of the alternator or generator causes the loadmeter to indicate zero. incorporated to prevent excessive voltage which may damage the electrical components. The bus bar serves to distribute the current to the various electrical com- ponents of the helicopter. Electrical switches are used to select electrical compo- nents. Power may be supplied directly to the component or to a relay which in turn provides power to the component. Relays are used when high current and/or heavy electrical cables are required for a particular com- ponent which may exceed the capacity of the switch. A battery is mainly used for starting the engine. In addition it permits limited operation of electrical components such as radios and lights without the engine running. The battery is also a valuable source of standby or emergency electrical power in the event of alternator or generator failure. Circuit breakers or fuses are used to protect various electrical components from overload. A circuit breaker pops out when its respective component is overloaded. The circuit breaker may be reset by pushing it back in unless a short or the overload still exists. In this case the circuit breaker continues to pop indicating an elec- trical malfunction. A fuse simply burns out when it is overloaded and needs to be replaced. Manufacturers usually provide a holder for spare fuses in the event one has to be replaced in flight. Caution lights on the instru- ment panel may be installed to show the malfunction of an electrical component. An ammeter or loadmeter is used to monitor the electrical current within the system. The ammeter reflects current flowing to and from the battery. A charging ammeter indicates that the battery is being charged. This is normal after an engine start since the battery power used in starting is being replaced. After the battery is charged the ammeter should sta- bilize near zero since the alternator or generator is supplying the electrical needs of the system. A dis- charging ammeter means the electrical load is exceeding the output of the alternator or generator and the battery is helping to supply electrical power. This may mean the alternator or generator is mal- functioning or the electrical load is excessive. A loadmeter displays the load placed on the alternator or generator by the electrical equipment. The RFM for a particular helicopter shows the normal load to Most helicopters other than smaller piston powered helicopters incorporate the use of hydraulic actuators to overcome high control forces. [Figure 5-13] A typi- cal hydraulic system consists of actuators also called 5-9 Figure 5-13. A typical hydraulic system for helicopters in the light to medium range is shown here. HYDRAULICS Pressure Return Supply ScupperGLYPH<.notdef> Drain Vent Reservoir Pump PressureGLYPH<.notdef> RegulatorGLYPH<.notdef> Valve QuickGLYPH<.notdef> Disconnects Filter SolenoidGLYPH<.notdef> Valve ServoGLYPH<.notdef> Actuator GLYPH<.notdef> LateralGLYPH<.notdef> Cyclic ServoGLYPH<.notdef> Actuator GLYPH<.notdef> Fore andGLYPH<.notdef> AftGLYPH<.notdef> Cyclic ServoGLYPH<.notdef> Actuator GLYPH<.notdef> Collective PilotGLYPH<.notdef> Input RotorGLYPH<.notdef> Control
2laws_and_regulations
US 20180235218Al c19) United States c12) Patent Application Publication Linke et al. c10) Pub. No.: US 2018/0235218 Al (43) Pub. Date: Aug. 23 2018 (54) DISINFECTANT HAVING ORGANIC ACIDS (71) Applicant: Bode Chemie GmbH Hamburg (DE) (72) Inventors: Christophe Linke Hamburg (DE); Herta Gerdes Hamburg (DE) (73) Assignee: Bode Chemie GmbH Hamburg (DE) (21) Appl. No.: 15/751 974 (22) PCT Filed: Aug. 11 2016 (86) PCT No.: PCT /EP2016/069115 § 371 (c)(l) (2) Date: Feb. 12 2018 (51) Int. Cl. (52) U.S. Cl. CPC .......... A0lN 37102 (2013.01); A0JN 2300/00 (2013.01); A0lN 37136 (2013.01); A0lN 37110 (2013.01) Aug. 18 2015 (DE) ..................... 10 2015 113 641.1 The invention relates to an aqueous disinfectant for disin› fecting inanimate surfaces a concentrate for producing the GO application solution and the use of the disinfectant to eliminate microorganisms. The combination of a plurality of organic acids according to the invention is surprisingly a synergistic composition and enables adequate germicidal action. Surprisingly adequate microbicidal effectiveness against a broad spectrum of microorganisms can thereby be achieved in a short exposure time without further active ingredients. A0lN 37102 A0lN 37110 A0lN 37136 (2006.01) (2006.01) (2006.01) Publication Classification (57) ABSTRACT (30) Foreign Application Priority Data
4patents
Old Glory flew proudly over the last of the 2 985- foot suspension cables installed in the final phase of construction of the Williamsburg Bridge in December 1903. Today the very same flag commands a place of honor in Dime Savings’ executive offices. tk + * en ae KKK TORO Ik oe eaen es KKK kk KR oo eae a. oe eee eee oe es eee oe oe ee ss KOKI
0financial_reports
MongoDB Documentation Release 3.0.4 MongoDB Enterprise Features Auditing Additional Information Changes Affecting Compatibility Storage Engine Change Storage Engine to WiredTiger sections in Upgrade MongoDB to 3.0 (page 810) See also: Data Files Must Correspond to Configured Storage Engine The files in the dbPath directory must correspond to the configured storage engine (i.e. --storageEngine ). mongod will not start if dbPath contains data files created by a storage engine other than the one specified by --storageEngine . WiredTiger and Driver Version Compatibility For MongoDB 3.0 deployments that use the WiredTiger storage engine the following operations return no output when issued in previous versions of the mongo shell or drivers: Use the 3.0 mongo shell or the 3.0 compatible version (page 808) of the official drivers when connecting to 3.0 mongod instances that use WiredTiger. The 2.6.8 mongo shell is also compatible with 3.0 mongod instances that use WiredTiger. Chapter 12. Release Notes 804 • db.getCollectionNames() • db.collection.getIndexes() • show collections • show tables Auditing (page 330) in MongoDB Enterprise can filter on any field in the audit message (page 424) including the fields returned in the param (page 425) document. This enhancement along with the auditAuthorizationSuccess parameter enables auditing to filter on CRUD operations. However enabling auditAuthorizationSuccess to audit of all authorization successes degrades performance more than auditing only the authorization failures. Compatibility Changes in MongoDB 3.0 The following 3.0 changes can affect the compatibility with older ver- sions of MongoDB. See Release Notes for MongoDB 3.0 (page 785) for the full list of the 3.0 changes. Configuration File Options Changes With the introduction of additional storage engines in 3.0 some configuration file options have changed: 3.0 mongod instances are backward compatible with existing configuration files but will issue warnings when if you attempt to use the old settings. Previous Setting New Setting storage.journal.commitIntervalMs storage.mmapv1.journal.commitIntervalMs storage.journal.debugFlags storage.mmapv1.journal.debugFlags storage.nsSize storage.mmapv1.nsSize storage.preallocDataFiles storage.mmapv1.preallocDataFiles storage.quota.enforced storage.mmapv1.quota.enforced storage.quota.maxFilesPerDB storage.mmapv1.quota.maxFilesPerDB storage.smallFiles storage.mmapv1.smallFiles
3manuals
Note 3 - Investments - Continued 157 Shown below are our financial instruments that either meet the accounting requirements that allow them to be offset in our balance sheets or that are subject to an enforceable master netting arrangement or similar agreement. Our accounting policy is to not offset these financial instruments in our balance sheets. Net amounts disclosed below have been reduced by the amount of collateral pledged to or received from our counterparties. December 31 2020 Gross Amount Gross Amount Not of Recognized Gross Amount Net Amount Offset in Balance Sheet Financial Offset in Presented in Financial Cash Net Instruments Balance Sheet Balance Sheet Instruments Collateral Amount (in millions of dollars) Financial Assets: Derivatives $ 19.8 $ — $ 19.8 $ (10.1) $ (8.7) $ 1.0 Securities Lending 96.6 — 96.6 (79.0) (17.6) — Total $ 116.4 $ — $ 116.4 $ (89.1) $ (26.3) $ 1.0 Financial Liabilities: Derivatives $ 59.7 $ — $ 59.7 $ (59.0) $ — $ 0.7 Securities Lending 17.6 — 17.6 (17.6) — — Total $ 77.3 $ — $ 77.3 $ (76.6) $ — $ 0.7 December 31 2019 Gross Amount Gross Amount Not of Recognized Gross Amount Net Amount Offset in Balance Sheet Financial Offset in Presented in Financial Cash Net Instruments Balance Sheet Balance Sheet Instruments Collateral Amount (in millions of dollars) Financial Assets: Derivatives $ 27.5 $ — $ 27.5 $ (4.0) $ (23.5) $ — Securities Lending 176.4 — 176.4 (176.4) — — Total $ 203.9 $ — $ 203.9 $ (180.4) $ (23.5) $ — Financial Liabilities: Derivatives $ 34.6 $ — $ 34.6 $ (31.3) $ — $ 3.3 NOTES TO CONSOLIDATED FINANCIAL STATEMENTS - Continued Unum Group and Subsidiaries
0financial_reports
EP 2 100 016 B1 € ‘Old ayam -InpjaL1oy SLamUnpjaLOy| 9
4patents
2 FIG. 1: (Color online) The Bi$_{2}$Ti$_{2}$O$_{6}$O ′ crystal structure is shown in (a) with 50% thermal ellipsoids representing the atomic displacement parameters from Rietveld refinement at 14 K. The two sublattices are corner-sharing TiO$_{6}$ octahedra (blue) and corner-sharing O $^{′}$Bi$_{4}$ tetrahedra (orange). Bi and O ′ are on ideal positions. Bi cations (black) appear as discs due to their displacement normal to the O $^{′}$–Bi–O′ bond. This disorder can be modeled using six-fold-split Bi and four-fold- split O ′ as shown in (b) (only the O $^{′}$Bi$_{4}$ is sublattice shown). are perforce associated with non-cubic symmetries. 12 Diffuse intensity in electron diffraction patterns of re- lated compounds including Bi$_{2}$Ru$_{2}$O$_{7}$ Bi$_{2}$InNbO$_{7}$ and Bi$_{2}$ScNbO$_{7}$ may indicate short-range correlations in the Bi displacements. 13–15 If Bi displacements cooperatively order with each other they must do so only over short ranges. Crystallographic analysis based on Bragg scat- tering leaves a void in the ability to probe such short- range order as analyses are predicated on the existence of long-range order. Consequently studies of displacive disorder on the A site via Rietveld refinement or Fourier maps can produce a model of the average electron or nu- clear distributions but each A site has an identical cloud of intensity. 16 We investigate models where the correlated motion of atoms on the A sites reproduces the atomistic pairwise distances between individual atoms. This description is provided by an appropriate Fourier transform of the total scattering function S ( Q ) to provide a normalized pair dis- tribution function (PDF). 17 18 In this study the PDF and the Bragg profile are used as experimental constraints in a large-box (11 000 atom) model of Bi$_{2}$Ti$_{2}$O$_{6}$O ′ to ob- tain using reverse Monte-Carlo (RMC) analysis a con- sistent picture of the the coordination tendencies of all atoms. Many of these models are combined and used as a set of atomic positions for further analysis. RMC com- pares the experimental and computed (based on atom po- sitions in the simulation box) D ( r ) and S ( Q ) while ran- domly relaxing atomic positions. The method is similar to Metropolis Monte Carlo except that the fit to data χ $^{2}$ instead of a potential energy function is minimized. 19–21 There are many approaches to describing the behav- ior and correlations of atomic positions as obtained from large-box models of structure. Some examples include the use of quadrupolar moments of octahedra to de- scribe LaMnO$_{3}$ 22 of contour plots of bond angles in cristobalite 23 and the use of bond valence analysis to obtain valence states from a statistical analysis of metal- oxygen positions. 24 25 Here we analyze the local geom- etry using simple metrics then present the continuous symmetry measures (CSM) 26–28 of polyhedra from RMC simulations. The CSM model provides a quantitative measure of a polyhedron’s distortion in the form of a “distance” from ideality. A key advantage of CSM is its ability to compare shapes in different compounds. 28 The CSM has been used to correlate deviations from ideal tetrahedra in silicates as a function of applied pressure 29 and to analyze second-order Jahn-Teller systems across a variety of crystal structures. 30 In these cases the CSM was considered for the average crystallographic stucture e.g. one where polyhedra possess a single CSM value. Here we extend CSM to large-box modeling by calculat- ing it for every O $^{′}$Bi$_{4}$ tetrahedron in the RMC supercell obtaining distributions rather than single values. The key finding to emerge from this study is that dis- placements from ideal atomic positions in Bi$_{2}$Ti$_{2}$O$_{6}$O ′ and in particular the nature of the O $^{′}$Bi$_{4}$ tetrahedra in- dicate a tendency for Bi to lie in a disordered ring around Synthesis and a detailed average structural analysis of the sample used in this study (including verification of purity) has been reported by Hector and Wiggin. 9 Briefly a basic solution of titanium metal with hydrogen peroxide and ammonia was added to an acidic solution of bismuth nitrate pentahydrate and nitric acid. The resulting pre- cipitate was filtered washed with a dilute ammonia solu- tion dried at 50 $^{◦}$C and calcined in air for 16 h at 470$^{◦}$C. Time-of-flight (TOF) neutron powder diffraction on sam- ples held in vanadium cans was collected at the NPDF instrument at Los Alamos National Laboratory at 298 K the ideal position with some preference for near-neighbor Bi-Bi ordering. This reaffirms the case that even when probed microscopically Bi$_{2}$Ti$_{2}$O$_{6}$O ′ is ice-like in its dis- order. We emphasize that in drawing the analogy with ice we do not suggest the existence of ice-rules of the Bernal-Fowler 31 type in these systems. II. METHODS
5scientific_articles
{ ˜ g$_{4}$ ˜ h$_{3}$ } = 0. Let h ′ 1 = ˜ h$_{2}$ ˜ h$_{4}$ = IXXXX h ′ 2 = ˜ h$_{1}$ h ′ 3 = ˜ h$_{4}$ and h ′ 4 = ˜ h$_{1}$ ˜ h$_{3}$ = XXXXI . Then we have [ g ′ $_{i}$ g ′ $_{j}$] = 0 for all i j [ f ′ $_{i}$ f ′ $_{j}$] = 0 for all i j { g ′ $_{i}$ f ′ i } = 0 for all i [ g ′ $_{i}$ f ′ $_{j}$] = 0 for i = j. Hence we have introduced 4 simplified generators such that there are 4 symplectic pairs. Observe that if any one of the simplified generators h ′ $_{1}$ h ′ $_{2}$ h ′ $_{3}$ h ′ 4 is removed and c = 3 the minimum distance instantly drops to 2. If two simplified generators h ′ $_{1}$ h ′ 2 or h ′ $_{1}$ h ′ 4 or h ′ $_{2}$ h ′ 3 are removed and c = 2 the minimum distance further decreases to 1. ✷ According to [10] given a parity-check matrix ˆ H of an [ n k d ] classical binary linear code an [[ n 2 k + c − n d ; c ]] EAQEC code can be constructed from a simplified check matrix H ′ defined as where the number of ebits c required for this EAQEC code is given by (14). The family of EAQEC codes in Theorem 2 can also be obtained by this construction. When c = n − k the quantum singleton bound (11) becomes H ′ =   $^{O}$ ˆ H ˆ H O    (19) n − k ≥ d − 1 which is exactly the same as the classical singleton bound. However there are no nontrivial classical binary codes achieve the singleton bound from [14]. 20
5scientific_articles
Tendering will then display a button ‘submit your tender’ and you will be able to access the e-Submission. The e- Submission “ quick guide for economic operators ” is available after logging in with your EU Login password. In the e-Submission application fill in and upload all necessary fields and documents as appropriate. All tenders must be clear complete and consistent with all the requirements laid down in the tender specifications including: For detailed instructions on how to submit your tender consult the Quick Reference Guide for Economic Operators where you will find: The following documents must be signed and dated during the creation of your tender in e-Submission: Please make sure all required documents and evidence are submitted with your tender . Documents to be signed and dated while creating your Tender Information to be filled in • Declaration on honour(s). All members of a joint tender including subcontractors must sign and date the declaration on Exclusion criteria. Only the leader in a joint tender must sign and date the declaration on Selection criteria. The declaration on honour(s) must be converted to PDF format and then signed by the authorised representatives with advanced electronic signature based on qualified certificates or by hand. • Technical requirements to use e-Submission • Step-by-step guide to help you submit your tender • Important advices and information on how to get technical support • Signed declaration on Honour on Exclusion criteria. All members of a joint tender including subcontractors – if applicable – must upload the signed and dated declaration on honour on exclusion criteria using the template available here. • Signed declaration on Honour on Selection criteria. In case of a joint offer from a group of economic operators such declaration should be completed by the leading partner using the template available here. • Exclusion criteria . If requested in the tender specifications the tenderer and all members of a joint tender including subcontractors – if applicable – must provide the documentary evidence for exclusion criteria. • Selection criteria. If requested in the tender specifications the tenderer and all members of a joint tender including subcontractors – if applicable – must provide the documentary evidence for selection criteria. • Technical tender. It must address all the requirements laid down in the tender specifications. • Financial tender The complete financial tender including the breakdown of the price as provided in the tender specifications. 32
1government_tenders
3 4 5 6 7 8 20 40 60 80 100 GLYPH<AY> GLYPH<B4>GLYPH<BC>GLYPH<B5> GLYPH<AM> GLYPH<B4>GLYPH<BC>GLYPH<B5> FIG. 11: The regions of the Casimir repulsion (above the solid line) and attraction (below the solid line) in the [ ε (0) µ (0)]-plane. See text for further discussion. 41
5scientific_articles
Interpolation Takeoff Charts Density Altitude Charts Figure 11-21. Interpolating charts. Not all of the information on the charts is easily extracted. Some charts require interpolation to find the information for specific flight conditions. Interpolating information means that by taking the known information a pilot can compute intermediate information. However pilots sometimes round off values from charts to a more conservative figure. and read the approximate density altitude. The approximate density altitude in thousands of feet is 7 700 feet. Takeoff charts are typically provided in several forms and allow a pilot to compute the takeoff distance of the aircraft with no flaps or with a specific flap configuration. A pilot can also compute distances for a no flap takeoff over a 50 foot obstacle scenario as well as with flaps over a 50 foot obstacle. The takeoff distance chart provides for various aircraft weights altitudes temperatures winds and obstacle heights. Using values that reflect slightly more adverse conditions provides a reasonable estimate of performance information and gives a slight margin of safety. The following illustration is an example of interpolating information from a takeoff distance chart. [Figure 11-21] Use a density altitude chart to figure the density altitude at the departing airport. Using Figure 11-22 determine the density altitude based on the given information. Refer to Figure 11-23 . This chart is an example of a combined takeoff distance graph. It takes into consideration pressure altitude temperature weight wind and obstacles all on one chart. First find the correct temperature on the bottom left side of the graph. Follow the line from 22 °C straight up until it intersects the 2 000 foot altitude line. From that point draw a line straight across to the first dark reference line. Continue to draw the line from the reference point in a diagonal direction following the surrounding lines until it intersects the corresponding weight line. From the intersection of 2 600 pounds draw a line straight across until it reaches the second reference line. Once again follow the lines in a diagonal manner until it reaches the six knot headwind mark. Follow First compute the pressure altitude conversion. Find 30.10 under the altimeter heading. Read across to the second column. It reads “–165.” Therefore it is necessary to subtract 165 from the airport elevation giving a pressure altitude of 5 718 feet. Next locate the outside air temperature on the scale along the bottom of the graph. From 70° draw a line up to the 5 718 feet pressure altitude line which is about two- thirds of the way up between the 5 000 and 6 000 foot lines. Draw a line straight across to the far left side of the graph Sample Problem 1 Sample Problem 2 To find the takeoff distance for a pressure altitude of 2 500 feet at 20 °C average the ground roll for 2 000 feet and 3 000 feet. 1 115 + 1 230 = 1 173 feet 2 11-20 Pressure Altitude...............................................2 000 feet OAT..........................................................................22 °C Takeoff Weight.............................................2 600 pounds Headwind...............................................................6 knots Obstacle Height.......................................50 foot obstacle Airport Elevation...............................................5 883 feet OAT...........................................................................70 °F Altimeter...........................................................30.10 "Hg Flaps 10° ns TAKEOFF DISTANCE Full throttle prior to brake release itio MAXIMUM WEIGHT 2 400 LB Cond Paved level runway Zero wind Weight (lb) Lift AT Takeoff speed KIAS Press ALT (ft) 0 °C 10 °C 20 °C 30 °C 40 °C Total feet to clear Grnd roll Total feet to clear Grnd roll Grnd roll Total feet to clear Grnd roll Total feet to clear Grnd roll Total feet to clear off 50 ft 50 ft OBS (ft) 50 ft OBS (ft) (ft) 50 ft OBS (ft) 50 ft OBS (ft) 50 ft OBS 2 400 51 56 S.L. 795 1 460 860 1 570 925 1 685 995 1 810 1 945 1 065 1 000 875 1 605 940 1 725 1 015 1 860 1 090 2 000 2 155 1 170 2 000 3 000 960 1 055 1 770 1 960 1 035 1 140 1 910 2 120 1 115 1 230 2 060 2 295 1 200 1 325 2 220 2 480 2 395 2 685 1 290 1 425 4 000 1 165 2 185 1 260 2 365 1 355 2 570 1 465 2 790 3 030 1 575 5 000 6 000 1 285 1 425 2 445 2 755 1 390 1 540 2 660 3 015 1 500 1 665 2 895 3 300 1 620 1 800 3 160 3 620 3 455 3 990 1 745 1 940 7 000 1 580 3 140 1 710 3 450 1 850 3 805 2 000 4 220 - - - - - - 8 000 1 755 3 615 1 905 4 015 2 060 4 480 - - - - - ­
2laws_and_regulations
statements of cash flows For the year ended 31 July 2012 Group pArent note 2012 nZ$’000 2011 nZ$’000 2012 nZ$’000 2011 nZ$’000 Cash flows from operating activities Cash was provided from: Receipts from customers 345 974 306 618 - - Dividends received - - 20 000 20 000 Income tax received - - 257 - Interest received 131 179 - - 346 105 306 797 20 257 20 000 Cash was applied to: Payments to suppliers and employees 291 626 246 063 1 567 1 477 Income tax paid 16 002 14 175 - 2 875 Interest paid 5 949 6 785 - - 313 577 267 023 1 567 4 352 net cash inflow from operating activities 6 32 528 39 774 18 690 15 648 Cash flows from investing activities Cash was provided from: Proceeds from sale of property plant and equipment 32 - - - 32 - - - Cash was applied to: Purchase of property plant and equipment 12 17 868 11 188 - - Purchase of intangibles 13 3 985 676 - - 21 853 11 864 - - net cash (outflow) from investing activities (21 821) (11 864) - - Cash flows from financing activities Cash was provided from: Proceeds of loan advances 206 226 240 223 1 331 4 351 206 226 240 223 1 331 4 351 Cash was applied to: Dividends paid 20 000 20 000 20 000 20 000 Repayment of loan advances 199 040 248 177 - - 219 040 268 177 20 000 20 000 net cash inflow / (outflow) from financing activities (12 814) (27 954) (18 669) (15 649) net increase / (decrease) in cash held (2 107) (44) 21 (1) Opening cash and cash equivalents 3 574 4 736 5 6 Effect of foreign exchange rates 344 (1 118) - - Closing cash 7 1 811 3 574 26 5 34 annual report 2012 kAThMANdu
0financial_reports
Offering Great Products and Ser vices We experienced excellent growth in 2003 in our short messaging service or SMS with revenues for the service growing 270 percent over 2002 to $17 million. Our next step into data is easy edge SM a robust wireless-data product that offers customers access to more than 150 downloadable applications including games news sports information ringtones and stock quotes. We introduced easy edge SM only after a trial run in one of our markets – to ensure that it was a service our customers would want and value. We learned the importance of getting everything right before we launched. That meant having the back-office support in place having applications that were easy to use and making sure our associates knew every aspect of the new product to best support our customers. So we gave each of our associates an easy edge SM enabled handset. We asked them to use it and understand all of its capabilities. Now all of our associates can effectively communi- cate the features and benefits of easy edge SM service to current and potential customers. Supporting versatile powerful digital products such as easy edge SM requires a state-of-the-art reliable and expand- able network. At the end of 2003 we had upgraded more than 75 percent of our wireless network to CDMA 1X technology a three-year initiative we began in 2002. CDMA 1X offers customers access to data speeds the delivery of information and improves the quality of the wire- less experience. We believe CDMA is technology of the future for the wireless industry and that’s one of the reasons we’ve chosen it for our network. We’re on target to complete the conversion process on time and under budget by the end of 2004. Besides upgrading the network technology we improved our market coverage by adding more than 500 cell sites to the network in 2003 making it stronger than ever. We also opened a new network operations center in Schaumburg Ill. to provide more support for our network. 9 We’re excited about the successful launch of our most advanced data product easy edge SM .
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Annex 1 Information about the Service Contract [Annex to be completed by the Contractor] Information about the Service Contract Reference number and date of the Service Contract <Contracting Authority’s reference of the Contract> Service contract title Country Contractor <full name and address of the Contractor as per the Service Contract> Legal basis for the Contract Start date of the Contract End date of the Contract Maximum Contract value <amount in Art.(3) of the Special Conditions of the Service Contract> Total amount of the invoice and invoice date <provide the total amount as per the Contractor’s invoice subject of this verification and the invoice date> Total amount invoiced to the Contracting Authority to date <provide the total amount invoiced by the Contractor the number of invoices and the invoice dates and references> Total amount received to date by the Contractor from Contracting Authority <Total amount received as per dd.mm.yyyy> Contracting Authority [ To be completed only if the Contracting Authority is not the European Investment Bank Provide the name position/title phone and E-mail of the contact person at the Contracting Authority.] European Investment Bank <provide the name position/title phone and E-mail of the contact person > Auditor <Name and address of the audit firm and names/positions of the auditors > Page 4 of 16
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04-HP-876_firstsection.qxd 12/15/04 2:41 PM Page 9 Years Ended September 30 2004 2003 2002 SUMMARY OF CONSOLIDATED STATEMENTS OF INCOME*† Operating Revenues 593 326 507 331 523 803 Operating Costs 416 631 345 537 361 669 Depreciation ① 145 941 82 513 61 447 Operating Income 30 754 79 281 100 687 Income from Investments 27 602 7 953 28 076 Interest Expense 12 695 12 289 980 General and Administrative Expense 37 661 41 003 36 563 Income from Continuing Operations 4 359 17 873 53 706 Net Income 4 359 17 873 63 517 Diluted Earnings Per Common Share: Income from Continuing Operations .09 .35 1.07 Net Income .09 .35 1.26 *$000’s omitted except per share data. ① 2004 includes an asset impairment charge of $51 516 † All data excludes discontinued operations except net income. SUMMARY FINANCIAL DATA* Cash** 65 296 38 189 46 883 Working Capital** 185 983 110 848 105 852 Investments 161 532 158 770 150 175 Property Plant and Equipment Net** 998 674 1 058 205 897 445 Total Assets 1 406 844 1 417 770 1 227 313 Long-term Debt 200 000 200 000 100 000 Shareholders’ Equity 914 110 917 251 895 170 Capital Expenditures 88 972 246 301 312 064 *$000’s omitted. ** Excludes discontinued operations. RIG FLEET SUMMARY Drilling Rigs – United States Land – FlexRigs 48 43 26 United States Land – Conventional 39 40 40 United States Offshore Platform 11 12 12 International 32 32 33 Total Rig Fleet 130 127 111 Rig Utilization Percentage – United States Land – FlexRigs 99 97 96 United States Land – Conventional 73 67 78 United States Land – All Rigs 87 81 84 United States Offshore Platform 48 51 83 International 54 39 51 Financial & O perating Review
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Performance Goals — Fiscal 2011 Second Half The revenue performance goal is based on the Company’s reported GAAP revenue. The Non-GAAP Operating Margin performance goal is based on the Company’s actual non-GAAP operating margin which it calculates by excluding from GAAP operating income stock compensation expense restructuring-related charges acquisition-related expenses litigation settlement gains and losses and certain deferred executive compensation. The Non-GAAP Gross Margin performance goal is based on the Company’s actual non-GAAP gross margin which it calculates by excluding from GAAP gross profit stock compensation expense restructuring-related charges and acquisition-related expenses. The Customer Satisfaction performance goal is based on the Company’s actual performance with respect to both the timeliness of shipments to customers and reduction in returned products over a specified period of time. The Cash performance goal is based on the Company’s cash generated during the six month period as measured by the number of times that inventory is turned over during the period. The Units Shipped performance goal is based on the aggregate number of certain specified products shipped by the Company over a specified period of time. The Design Win performance goal is based on the total number and the quality or difficulty of achievement of a pre-established list of design/ installation projects awarded to or contracted by the Company. Where the table above indicates that a performance goal was based on the achievement of the goal by a business unit the performance goal was defined in the same manner but only the results of the applicable business unit were taken into account in setting the achievement levels and measuring performance. In determining the weightings between performance goals for each Named Executive Officer the Compensation Committee’s aim was to align the short-term incentive compensation of each Named Executive Officer with the performance goals that the executive could most impact. For instance the performance goals for the Chief Executive Officer Vice-President and Chief Financial Officer and Senior Vice President Worldwide Operations were designed to focus such executives on improving the Company’s competitive position and achieving profitable growth overall. The performance goals for the Executive Vice President and General Manager Front-End Solutions and Executive Vice President and General Manager High Performance Analog were designed to focus such executive on business unit performance (i.e. securing design wins for new products and expansion of the customer base). The Compensation Committee then determines with respect to each performance goal the “threshold ” “target” and “maximum” levels of achievement which correspond to the matching descriptions set forth above. For Company performance goals the levels of achievement will be consistent across the executives to which such goals apply. The Compensation Committee sets the performance goals weightings and “threshold ” “target” and “maximum” levels of achievement on a semi-annual basis. Page 42 Skyworks / Proxy Statement Revenue Non-GAAP Operating Margin % Non- GAAP Gross Margin % Customer Satisfaction Metric Design Win Metric President and Chief Executive Officer; Vice President and Chief Financial Officer . . . 30% 40% N/A 10% 20% Executive Vice President and General Manager Front-End Solutions ......... 20%(based on 40% (20% based N/A N/A 40% business unit) on corporate and 20% based on business unit) Executive Vice President and General Manager High Performance Analog .... 20%(based on 40% (20% based N/A 10% 30% business unit) on corporate and 20% based on business unit) Senior Vice President Worldwide Operations ......................... 30% N/A 40% 10% 20%
0financial_reports
MOVADO GROUP INC. 45 disclosure of contingent assets and liabilities at the date of the financial statements and the reported amounts of revenues and expenses during the reporting period. Actual results could differ from those estimates. Under a series of share repurchase authorizations approved by the Board of Directors the Company has maintained a discretionary buy-back program throughout fiscal 2001. Share repurchases under the repurchase program amounted to $7.3 million $17.6 million and $0.6 million in fiscal 2001 2000 and 1999 respectively. As of January 31 2001 the Company had authorization to repurchase shares up to an additional $4.5 million against an aggregate authorization of $30 million. During fiscal 1999 the Company repurchased $2.3 million of stock under a 400 000 share repurchase program that had been authorized by the Board of Directors in March 1998. This program had been put in place to mitigate the dilutive impact of employee compensation programs. In June 1998 the Financial Accounting Standards Board issued Statement of Financial Accounting Standards (SFAS) No. 133 “Accounting for Derivative Instruments and Hedging Activities ” as amended which is effective for the company as of February 1 2001. SFAS 133 requires that an entity recognizes all derivatives as either assets or liabilities measured at fair value. Changes in derivative fair values will either be recognized in earnings as offsets to the changes in fair value of related hedged assets liabilities and firm commitments or for forecasted transactions deferred and recorded as a component of other stockholders’ equity until the hedged transactions occur and are recognized in earnings. The ineffective portion of a hedging derivative’s change in fair value will be immediately recognized in earnings. Adoption of this statement is not expected to materially impact the Company’s financial statements. In December 1999 the Securities and Exchange Commission “SEC” issued Staff Accounting Bulletin No. 101 “SAB 101” “Revenue Recognition in Financial Statements.” SAB 101 summarizes certain of the SEC’s views in applying accounting principles generally accepted in the United States to revenue recognition in financial statements. The Company adopted the guidence of this bulletin during fiscal 2001 which had no material impact on the Company’s revenue recognition policy. Certain prior year amounts have been reclassified to conform to the fiscal 2001 presentation. Reclassification New Accounting Standards Stockholders’ Equity
0financial_reports
. . . . . . . . . T/T$_{c}$ − 1 T ( K ) Lovesey and Engdahl Mode coupling 4 FIG. 4: (Color online.) Relaxation rate as a function of tem- perature in the paramagnetic regime for pure EuO (solid cir- cles) and (b) Eu 0 . 994 Gd 0 . 006 O (dots). The predicted relax- ation rates for T > T C according to Ref. 15 (numerical cal- culation: thick solid line purple; critical regime using experi- mental values of correlation length: thick dashed line purple) and Ref. 16 (dotted line blue) are also shown. cooling to T$_{C}$ from about 0.3 K above it; this is also not observed in our data. Magnetic polaron formation has been detected using Raman scattering [28] in a narrow range ( ≈ 20 K) above T$_{C}$ . It may be that the forma- tion of magnetic polarons modifies the relaxation in this regime from that which would be expected from theory perhaps by providing an additional relaxation channel for the muon which masks the critical slowing down pre- dicted by the theory and hence the absence of the diver- gence in λ . We note that a similar absence of a divergence in λ is observed in EuB$_{6}$ [29] in which magnetic polarons have been found [28]. In conclusion we have identified the muon site in EuO and estimated the hyperfine field. Our results confirm long-range order which is relatively insensitive to low doping of Gd. The measured λ in the paramagnetic state agrees quite well with the theory of Lovesey and Engdahl but the available theories fail in the critical regime pos- sibly due to magnetic polaron formation. We thank EPSRC (UK) for financial support and Alex Amato for experimental assistance. Part of this work was performed at the Swiss Muon Source Paul Scherrer Institute Villigen Switzerland. [3] P. Sinjukow and W. Nolting Phys. Rev. B 68 125107 (2003). [2] Y. Shapira S. Foner and T. B. Reed Phys. Rev. B 8 2299 (1973). [1] B. T. Matthias R. M. Bozorth and J. H. van Vleck Phys. Rev. Lett. 7 160 (1961). ∗ Electronic address: s.blundell@physics.ox.ac.uk [29] M. L. Brooks T. Lancaster S. J. Blundell W. Hayes F. L. Pratt and Z. Fisk Phys. Rev. B 70 020401(R) (2004). [28] C. S. Snow S. L. Cooper D. P. Young Z. Fisk A. Comment and J.-P. Ansermet Phys. Rev. B 64 174412 (2001). [27] A. D. Bruce and A. Aharony Phys. Rev. B 10 2078 (1974). [26] J. Als-Nielsen O. W. Dietrich W. Kunnmann and L. Passell Phys. Rev. Lett. 27 741 (1971). [25] V.G. Storchak O.E. Parfenov J.H. Brewer P.L. Russo S.L. Stubbs R.L. Lichti D.G. Eshchenko E. Morenzoni V.P. Zlomanov A.A. Vinokurov and V.G. Bamburov Physica B 404 899 (2009). [24] V.G. Storchak O.E. Parfenov J.H. Brewer P.L. Russo S.L. Stubbs R.L. Lichti D.G. Eshchenko E. Morenzoni T.G. Aminov V.P. Zlomanov A.A. Vinokurov R.L. Kallaher and S. von Moln´ ar Phys. Rev. B 80 235203 (2009). [23] V. G. Storchak J. H. Brewer D. J. Arseneau S. L. Stubbs O. E. Parfenov D. G. Eshchenko E. Morenzoni and T. G. Aminov Phys. Rev. B 79 193205 (2009). [22] D.G. Eshchenko V.G. Storchak E. Morenzoni and D. Andreica Physica B 404 903 (2009). [21] A. Kasuya and M. Tachiki Phys. Rev. B 8 5298 (1973). [20] S. J. Blundell Physica B 404 581 (2009). [19] A. Comment J.-P. Ansermet C. P. Slichter H. Rho C. S. Snow and S. L. Cooper Phys. Rev. B 72 014428 (2005). [18] P. Dalmas de R´eotier and A. Yaouanc J. Phys. C 9 9113 (1997). [17] S. F. J. Cox J. Phys. C 20 3187 (1987); S. J. Blundell Contemp. Phys. 40 175 (1999). [16] A. Yaouanc P. Dalmas de R´eotier and E. Frey Phys. Rev. B 47 796 (1993). [15] S. W. Lovesey and E. Engdahl J. Phys.: Condens. Mat- ter 7 769 (1995). [14] S. W. Lovesey and E. B. Karlsson and K. N. Trohidou J. Phys.: Condens. Matter 4 2043 (1992); S. W. Lovesey K. N. Trohidou and E. B. Karlsson J. Phys.: Condens. Matter 4 2061 (1992). [13] H. G. Bohn W. Zinn B. Dorner and A. Kollmar Phys. Rev. B 22 5447 (1980). [12] A. Mauger and C. Godart Phys. Rep. 141 51 (1986). [11] Ven-Chung Lee and L. Liu Phys. Rev. B 30 2026 (1984). [10] H. Miyazaki T. Ito H. J. Im S. Yagi M. Kato K. Soda and S. Kimura Phys. Rev. Lett. 102 227203 (2009). [9] O. W. Dietrich J. Als-Nielsen and L. Passell Phys. Rev. B 14 4923 (1976); J. Als-Nielsen O. W. Dietrich and L. Passell Phys. Rev. B 14 4908 (1976); L. Passell O. W. Dietrich and J. Als-Nielsen Phys. Rev. B 14 4897 (1976). [8] A. Schmehl et al. Nat. Mat. 6 882 (2007). [7] P. G. Steeneken L. H. Tjeng I. Elfimov G. A. Sawatzky G. Ghiringhelli N. B. Brookes and D.-J. Huang Phys. Rev. Lett. 88 047201 (2002). [6] K. Sattler and H. C. Siegmann Phys. Rev. Lett. 29 1565 (1972). [5] K. J. Hubbard and D. G. Schlom J. Mater. Res. 11 2757 (1996). [4] J. B. Torrance M. W. Shafer and T. R. McGuire Phys. Rev. Lett. 29 1168 (1972).
5scientific_articles
TM 1-320 4 AIR CORPS U seful.-Crew and passengers oil and fuel ballast other than emergency ordnance and portable equipment. Nose heavy.-Condition of an airship which when at rest in still air trims with its axis inclined down by the bow. The term "bow heavy" is preferred to "nose heavy" in describing airships. Oscillation stable.-Oscillation whose amplitude does not increase. Oscillation ~tnstable .-O sc illation whose amplitude incres.ses con› tinuously until an attitude is reached from which there is no tendency to return toward the original attitude the motion becom- . ing a steady divergence. P erformance CM’I’CUJteristics (airship) .-In general: Maximum speed at various altitudes. Maximum altitude attainable with definite weight relations and ballonet volume (if fitted). Endurance at full and half power. Static ceiling. Dynamic lift under specified conditions. Pitch of propeller: Etfective.-Distance which aircraft advances along its flight path for one revolution of propeller. Its symbol is pa. Geomet rical.-Distance which an element of a propeller would advance in one revolution if it were moving along a helix of slope equal to its blade angle. Mean geometrical.- Mean of the geometrical pitches of the sev› eral elements. I ts symbol is p$_{0}$ • Standard.-Geometrical pitch taken at two-thirds of thE’ radius. Also called "nominal pitch." Its symbol is Ps• Ze1’0 th?’U8t.-Distance which propeller would have to advance in one revolution in order that there might be no thrust. Also called "experimental mean pitch." Its symbol is pv. Zero torque.-Distance which propeller would have to advance in one revolution in order that the torque might be zero. Its symbol is Pa• Pitch mtio.-Ratio of the pitch (geometrical unless otherwise stated) to the diameter pj D. Pitch speed.-Product of mean geometrical pitch by number of revo› lutions of propeller in unit time that is the speed aircraft would make if there were no slip. Propeller area proje~ted.-Total area in the plane perpendicular to: propeller shaft swept by propeller except portion covered by the boss and that swept by root of the blade. This portion is usually taken as extending 0.2 of maximum radius from axis of the shaft. 8
2laws_and_regulations
result that second sound is the dominant excitation in S ( q ω ) and mainly involves a pure oscillation of the condensate in the presence of a static thermal component [3 4]. However first and second sound in a strongly interacting Bose gas are similar to those in a Fermi gas near unitarity (see figure 7). We thank Lev Pitaevskii for useful comments. E.T. was supported by nsf-dmr 0907366 and ARO W911NF-08-1-0338. H.H. and X.-J.L. were supported by ARC and NSFC. S.S. acknowledges the support of the EuroQUAM FerMix program. A.G. was supported by NSERC and CIFAR. At low temperatures Goldstone phonons determine the thermodynamics of both super- fluid $^{4}$He and Fermi gases. For phonons with velocity c the free energy F and normal fluid density ρ$_{n}$$_{0}$ are given by [41] (Recall that we have set ℏ = k$_{B}$ = 1) and Using (A1) it is straightforward to show that and In arriving at these expressions the temperature dependence of the Goldstone phonon ve- locity c has been ignored. P$_{0}$ is the pressure in the ground state. These results can be combined to give 25 ¯ c$_{p}$ = ¯ c$_{v}$ − T ( ∂ ¯ s ∂ρ ) T ( ∂P ∂T ) ρ ( ∂P ∂ρ ) − 1 T = ¯ c$_{v}$ + 4 π $^{4}$T 7 45 $^{2}$ρ$^{2}$c$^{6}$v 2 T [ 1 + 3 ρ c ( ∂c ∂ρ ) T ] 2 (A6) ¯ c$_{v}$ = 2 π $^{2}$T 3 15 ρc 3 . (A5) P = − ( ∂F ∂V ) T N = P$_{0}$ + π $^{2}$T 4 90 c 3 [ 1 + 3 ρ c ( ∂c ∂ρ ) T N ] (A4) ¯ s$_{0}$ = − 1 mN ( ∂F ∂T ) V N = 2 π $^{2}$T 3 45 ρc 3 (A3) ρ$_{n}$$_{0}$ = 2 π $^{2}$T 4 45 c 5 . (A2) F = F$_{0}$ − V π $^{2}$T 4 90 c 3 (A1) Appendix A: Phonon thermodynamics at low temperatures Acknowledgments
5scientific_articles
Measure lining wear here Housing Disk #40 twist drill (0.098 inches in diameter) used as visual reference Lining 13-68 Figure 13-115. A #40 twist drill laid next to the brake lining indicates when the lining needs to be changed on a Cleveland brake. Figure 13-113. Brake lining wear on a Goodyear brake is ascertained by measuring the wear pin of the automatic adjuster. Figure 13-114. The distance between the brake disc and the brake housing measured with the brakes applied is a means for determining brake lining wear on some brakes. Bleeding Master Cylinder Brake Systems Air in the Brake System Many brake assemblies contain a built-in wear indicator pin. Typically the exposed pin length decreases as the linings wear and a minimum length is used to indicate the linings must be replaced. Caution must be used as different assemblies may vary in how the pin measured. On the Goodyear brake described above the wear pin is measured where it protrudes through the nut of the automatic adjuster on the back side of the piston cylinder. [Figure 13-113] The Boeing brake illustrated in Figure 13-88 measures the length of the pin from the back of the pressure plate when the brakes are applied (dimension L). The manufacturer’s maintenance information must be consulted to ensure brake wear pin indicators on different aircraft are read correctly. On many other brake assemblies lining wear is not measured via a wear pin. The distance between the disc and a portion of the brake housing when the brakes are applied is sometimes used. As the linings wear this distance increases. The manufacturer specified at what distance the linings should be changed. [Figure 13-114] On Cleveland brakes lining wear can be measured directly since part of the lining is usually exposed. The diameter of a number 40 twist drill is approximately equal to the minimum lining thickness allowed. [Figure 13-115] Multiple disc brakes typically are checked for lining wear by applying the brakes and measuring the distance between the back of the pressure plate and the brake housing. [Figure 13-116] Regardless of the method particular to each brake regular monitoring and measurement of brake wear ensures linings are replaced as they become unserviceable. Linings worn beyond limits usually require the brake assembly to be removed for replacement. Brake systems with master cylinders may be bled by gravity or pressure bleeding methods. Follow the instructions in the aircraft maintenance manual. To pressure bleed a brake system from the bottom up a pressure pot is used. [Figure 13-117] This is a portable tank that contains a supply The presence of air in the brake system fluid causes the brake pedal to feel spongy. The air can be removed by bleeding to restore firm brake pedal feel. Brake systems must be bled according to manufacturers’ instructions. The method used is matched to the type of brake system. Brakes are bled by one of two methods: top down gravity bleeding or bottom up pressure bleeding. Brakes are bled when the pedals feel spongy or whenever the brake system has been opened.
2laws_and_regulations
16 Dialog Semiconductor Plc | Annual report and accounts 2012 | Section 2 | Business review Our products and key customers Our power management audio and display semiconductor solutions are designed for portable devices including smartphones tablets Ultrabooks™ ebooks MP3 MP4 and other media players. Mobile solutions Dialog focuses on three major sectors: mobile connectivity and automotive and industrial. Dialog replaces discrete power management components with highly integrated single chip solutions that provide design simplicity reduce energy usage save board space for other components and lower the overall bill of materials. Dialog’s Power Management Integrated Circuits (PMICs) are fully configurable which means they can be programmed to meet the exact voltage and current needs of every component. Effective power management in many portable devices presents an increasingly complex array of design challenges. Smartphones tablets and Ultrabooks™ increasingly need to be able to run high definition video games GPS maps and audio content and connect via high speed 4G LTE and legacy 3G networks Wi-Fi and short-range wireless stands like Bluetooth. 4G LTE for example requires a lot more processing power to decode far greater amounts of data in the wireless spectrum. At the same time consumers demand displays that are brighter bigger and incorporate touch functionality and in the future haptic feedback. Each of these features is a major battery drain creating a need for effective power management technologies. Multicore devices delegate simple tasks to one core while directing more complex power- hungry tasks to the other core. Each of the quad- or octal-core application processors needs to be powered up and down into and out of sleep state in particular sequences. Dialog’s solutions excel at handling this power management complexity. Dialog’s charging solutions for lithium ion battery systems support faster charging more safely and from a wider variety of sources. With a long legacy of delivering different power management designs for world-leading mobile phone manufacturers and portable consumer OEMs we seek to optimise all aspects of the design including electrical thermal and mechanical packaging considerations. These designs offer sophisticated integration with multiple power management and analog functions on the chip including programmable high-performance LDOs (low dropout voltage regulators) high-efficiency DC-DC voltage converters intelligent battery charging circuits software programmable LED drivers sensor ADCs USB interfaces and multichannel audio capabilities. In 2012 Dialog launched a new class of power management product – DA9063 – our fourth generation of advanced system PMIC and flagship product targeting high-end multicore- based applications. A second member of the family – DA9021 – addresses lower power cost-sensitive applications. Our configurable PMICs enable late changes in board-level designs as additional functionality that is added into smartphone platforms during the R&D process. As a platform-based PMIC can support multiple phone designs Dialog helps its customers reduce inventories and respond to the consumer market’s need for volume flexibility. Dialog’s Audio CODECs filter out extreme background noise and increase the fidelity of the sound through advanced echo cancellation and DSP (Digital Signal Processing) technology that delivers a rich deep base and clear high frequencies even in noisy environments. This is complemented by amplifier technology to improve audio quality through the headphones and speakers. In 2012 Dialog launched a new class of power management product – DA9063 – our fourth generation of advanced system power management integrated circuit (PMIC). Dialog replaces discrete power management components with highly integrated single chip solutions that provide design simplicity reduce energy usage save board space for other components and lower the overall bill of materials. From left:
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REPORT OF INDEPENDENT REGISTERED PUBLIC ACCOUNTING FIRM Management’s Responsibility for the Consolidated Financial Statements Auditor’s Responsibility Opinion Other Matter To the Board of Directors and Shareholders of Brookfield Asset Management Inc. We have audited the accompanying consolidated financial statements of Brookfield Asset Management Inc. and subsidiaries (the “Company”) which comprise the consolidated balance sheets as at December 31 2013 and December 31 2012 and the consolidated statements of operations consolidated statements of comprehensive income consolidated statements of changes in equity and consolidated statements of cash flows for the years then ended and the notes to the consolidated financial statements. Management is responsible for the preparation and fair presentation of these consolidated financial statements in accordance with International Financial Reporting Standards as issued by the International Accounting Standards Board and for such internal control as management determines is necessary to enable the preparation of consolidated financial statements that are free from material misstatement whether due to fraud or error. Our responsibility is to express an opinion on these consolidated financial statements based on our audits. We conducted our audits in accordance with Canadian generally accepted auditing standards and the standards of the Public Company Accounting Oversight Board (United States). Those standards require that we comply with ethical requirements and plan and perform the audit to obtain reasonable assurance about whether the consolidated financial statements are free from material misstatement. An audit involves performing procedures to obtain audit evidence about the amounts and disclosures in the consolidated financial statements. The procedures selected depend on the auditor’s judgment including the assessment of the risks of material misstatement of the consolidated financial statements whether due to fraud or error. In making those risk assessments the auditor considers internal control relevant to the entity’s preparation and fair presentation of the consolidated financial statements in order to design audit procedures that are appropriate in the circumstances. An audit also includes evaluating the appropriateness of accounting policies used and the reasonableness of accounting estimates made by management as well as evaluating the overall presentation of the consolidated financial statements. We believe that the audit evidence we have obtained in our audits is sufficient and appropriate to provide a basis for our audit opinion. In our opinion the consolidated financial statements present fairly in all material respects the financial position of Brookfield Asset Management Inc. and subsidiaries as at December 31 2013 and December 31 2012 and their financial performance and their cash flows for the years then ended in accordance with International Financial Reporting Standards as issued by the International Accounting Standards Board. We have also audited in accordance with the standards of the Public Company Accounting Oversight Board (United States) the Company’s internal control over financial reporting as of December 31 2013 based on the criteria established in Internal Control – Integrated Framework (1992) issued by the Committee of Sponsoring Organizations of the Treadway Commission and our report dated March 28 2014 expressed an unqualified opinion on the Company’s internal control over financial reporting. Toronto Canada March 28 2014 Chartered Professional Accountants Chartered Accountants Licensed Public Accountants 80 BROOKFIELD ASSET MANAGEMENT
0financial_reports
(1) Area (2) Street to be temporarily stopped up (3) Extent of temporary stopping up Footpath ADD/12/2 Between points P2 and T2 (on sheet 22). Footpath ADD/11/1 Between P1 and P2 (on sheet 23). Parishes of Addington and Winslow Verney Road Between points T9 and T10 (on sheets 22) and between points T11 T12 and T13 (on sheets 22 and 23). Parish of Winslow Footpath WIS/5/1 Between points P2 and T1 (on sheet 23). Furze Lane Between points T1 and T2 (on sheet 24). Footpath WIS/6/1 Between points P4 P1 and T7 (on sheet 24). Footpath WIS/6/2 Within Order limits (on sheet 24). Footpath WIS/6/9 Between points P4 and P5 Buckingham Road Between points T3 and T4 (on sheet 24). Great Horwood Road Between points T5 and T6 (on sheet 24 and 25). Parishes of Winslow and Little Horwood Horwood Road Between points T1 T2 and T3 (on sheets 85 and 26). Parish of Swanbourne Footpath SWA/17/1 Within Order limits (on sheets 27 and 28). Footpath SWA/1/1 Within Order limits (on sheet 28). Footpath SWA/1/2 Within Order limits (on sheet 28). Station Road Between points T6 and T7 (on sheet 28). Footpath SWA/20/1 Between points P11 and P12 (on sheet 29). Parishes of Swanbourne and Mursley Station Road Between points T5 and T3 (on sheets 28 and 29). Parish of Little Horwood Footpath LHO/27/1 Between points T2 and P10 (on sheets 28 and 29). Footpath LHO/20/1 Between points P1 and P5 (on sheet 30). 80
2laws_and_regulations
or to the system of equations γ · φ = ε$_{1}$ (16) γ ′ k · φ = iε$_{2}$$_{k}$ k = 1 ... d. 3 Solutions to the convolution equations: iden- tification and well-posedness 3.1 Identification For identification the supports of the functions in the equations play an important role. Recall that for a continuous function ψ ( x ) on R d support is defined as the set W =supp( ψ ) such that Support of a continuous function is an open set. Since generalized functions can be considered as functionals on the space S support of a generalized function b ∈ S ∗ is defined as follows (Schwartz 1966 p. 28). Denote by ( b ψ ) the value of the functional b for ψ ∈ S. Consider open sets W with the property that for any ψ ∈ S : supp( ψ ) = W the value of the functional ( b ψ ) = 0; then define the null set for b as the union ψ ( x ) =     a = 0 for x ∈ W 0 for x ∈ R $^{d}$\ W. 26
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(e) Where the person concerned travels by car travel expenses are reimbursed on the basis of the first class rail fare excluding any supplements. The person is requested to provide supporting documents as to the actual price of a first class rail ticket for the journey in question at the occasion the person is participating in. (f) Where the distance by rail exceeds 400 km or where the route includes a sea crossing the cost of travel by air will be reimbursed on the basis of the fare in economy class or if that is not available business class. (g) Taxi fares are not reimbursed. In addition the contracting authority reimburses travel outside Union territory if it has given its prior written approval for the expenses. II.24.4 The contracting authority reimburses subsistence expenses on the basis of a daily subsistence allowance as follows: (a) For journeys of less than 200 km for a return trip no subsistence allowance is payable. (b) The reimbursement of accommodation is based on the actual costs of accommodation on production of an original invoice up to the ceiling as indicated in Annex XVI per necessary overnight stay related to the tasks executed. Accommodation must be arranged and paid directly by the contractor. (c) A flat rate daily allowance as specified in Annex XVI shall be reimbursed for days during which the tasks are executed. This amount covers all expenses at the place where the tasks related to the contract are executed including the costs of meals and local transport (including taxi). (d) A daily allowance for up to two days may be paid for extra overnight stays necessary to qualify for a reduced transport fare through e.g. a stay over from Saturday to Sunday provided the reduction amounts at least to the extra allowance paid. II.24.5 The contracting authority reimburses the cost of shipment of equipment or unaccompanied luggage only if it has given its prior written approval for the expense. 40
1government_tenders
CREATE TABLESPACE Statement INITIAL_SIZE (described in the following item) is 256 MB and whose EXTENT_SIZE is 128M has just two extents and so can be used to store data from at most two different disk data table partitions. You can see how many extents remain free in a given data file by querying the INFORMATION_SCHEMA.FILES table and so derive an estimate for how much space remains free in the file. For further discussion and examples see Section 26.3.15 “The INFORMATION_SCHEMA FILES Table” . The INITIAL_SIZE parameter sets the total size in bytes of the data file that was specific using ADD DATATFILE . Once this file has been created its size cannot be changed; however you can add more data files to the tablespace using ALTER TABLESPACE ... ADD DATAFILE . INITIAL_SIZE is optional; its default value is 134217728 (128 MB). On 32-bit systems the maximum supported value for INITIAL_SIZE is 4294967296 (4 GB). Has no effect in any release of MySQL NDB Cluster 8.0 regardless of the storage engine used. As of MySQL 8.0.16 if the ENCRYPTION clause is not specified the default_table_encryption setting controls whether encryption is enabled. The ENCRYPTION clause overrides the default_table_encryption setting. However if the table_encryption_privilege_check variable is enabled the TABLE_ENCRYPTION_ADMIN privilege is required to use an ENCRYPTION clause setting that differs from the default_table_encryption setting. A keyring plugin must be installed and configured before an encryption-enabled tablespace can be created. When a general tablespace is encrypted all tables residing in the tablespace are encrypted. Likewise a table created in an encrypted tablespace is encrypted. For more information see Section 15.13 “InnoDB Data-at-Rest Encryption” 2601 • ENGINE : Defines the storage engine which uses the tablespace where engine_name is the name of the storage engine. Currently only the InnoDB storage engine is supported by standard MySQL •The ENCRYPTION clause enables or disables page-level data encryption for an InnoDB general tablespace. Encryption support for general tablespaces was introduced in MySQL 8.0.13. • COMMENT : Currently ignored by MySQL; reserved for possible future use. Has no effect in any release of MySQL 8.0 or MySQL NDB Cluster 8.0 regardless of the storage engine used. • WAIT : Currently ignored by MySQL; reserved for possible future use. Has no effect in any release of MySQL 8.0 or MySQL NDB Cluster 8.0 regardless of the storage engine used. • NODEGROUP : Currently ignored by MySQL; reserved for possible future use. Has no effect in any release of MySQL 8.0 or MySQL NDB Cluster 8.0 regardless of the storage engine used. • MAX_SIZE : Currently ignored by MySQL; reserved for possible future use. Has no effect in any release of MySQL 8.0 or MySQL NDB Cluster 8.0 regardless of the storage engine used. • AUTOEXTEND_SIZE : Ignored by MySQL prior to MySQL 8.0.23; From MySQL 8.0.23 defines the amount by which InnoDB extends the size of the tablespace when it becomes full. The setting must be a multiple of 4MB. The default setting is 0 which causes the tablespace to be extended according to the implicit default behavior. For more information see Section 15.6.3.9 “Tablespace AUTOEXTEND_SIZE Configuration” . • INITIAL_SIZE : This option is specific to NDB and is not supported by InnoDB where it fails with an error.
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4 particle descriptions. In conclusion we have shown that a quantum- statistical model of nuclear matter that includes the formation of clusters at densities below nuclear satura- tion describes quite well the low-density symmetry en- ergy which was extracted from the analysis of heavy-ion collisions. Within such a theoretical approach the com- position and the thermodynamic quantities of nuclear matter can be modeled in a large region of densities temperatures and asymmetries that are required e.g. in supernova simulations. Acknowledgement : This research was supported by the DFG cluster of excellence “Origin and Structure of the Universe” by CompStar a Research Networking Pro- gramme of the European Science Foundation by US De- partment of Energy contract No. DE-AC02-06CH11357 (TK) and grant No. DE-FG03-93ER40773 (Texas A& M) and by Robert A. Welch Foundation grant No. A0330 (JBN). DB acknowledges support from the Polish Min- istry for Research and Higher Education grant No. N N 202 2318 37 and from the Russian Fund for Basic Re- search grant No. 08-02-01003-a. that the underlying RMF model for the quasiparticle de- scription with n$_{0}$ = 0 . 149 fm $^{$_{−}$3}$ E$_{sym}$ ( n$_{0}$ ) = 32 . 73 MeV gives a reasonable behavior at high density similar to the MDI x =0 parametrization. We thus see that our approach successfully interpolates between the cluster- ing phenomena at low density and a realistic description around normal density. In the right panel of Fig. 2 we compare to the ex- perimental results full (red) circles (Tab. I col. 6) in an expanded low-density region. Besides the MDI parametrization we show the QS results [8] for T =1 4 and 8 MeV which are in the range of the temperatures in the experiment. The QS results including cluster forma- tion agree well with the experimental data points as seen in detail in Fig. 1. We conclude that medium-dependent cluster formation has to be considered in theoretical mod- els to obtain the low-density dependence of the symmetry energy that is observed in experiments. The temperatures and densities of columns 2 and 3 in Tab. I will be modified if medium effects on the light clusters are taken into account [24]. We have carried out a self-consistent determination of the temperatures T sc and densities n sc taking into account the medium- dependent quasiparticle energies as specified in Ref. [12] (columns 9 and 10 of Tab. I). Compared to the Albergo method results [20] the temperatures T sc are about 10 % lower. Significantly higher values are obtained for the in- ferred densities n sc which are more sensitive to the inclu- sion of medium effects. We have also calculated the free and internal symmetry energies corresponding to these self-consistent values of T sc and n sc according to Ref. [8] (columns 11 and 12 of Tab. I). These results are also shown in the right panel of Fig. 2 as open (purple) cir- cles. The resultant internal symmetry energies are 15 to 20 % higher than the QS model values for T and n given in columns 2 and 3 in Tab. I. We have restricted our present work to that region of the phase diagram where heavier clusters with A > 4 are not relevant. The generalization of the given approach to account for clusters of arbitrary size would lead to an improvement in the low-density low-temperature re- gion when nuclear statistical equilibrium is assumed. Al- ternatively one can introduce the formation of heavier nuclei in the presence of a nucleon and cluster gas cf. Refs. [25 26]. The simplest approach to model the formation of heavy clusters is to perform inhomogeneous mean-field calcu- lations in the Thomas-Fermi approximation assuming spherical Wigner-Seitz cells. In Fig. 2 (left panel) pre- liminary results for the zero-temperature symmetry en- ergy of such a calculation is shown by the long-dashed line using the same RMF parametrization as for the QS approach introduced above; for details see Ref. [27]. The symmetry energy in this model approaches a finite value at zero density in contrast to the behavior of the MDI parametrizations and conventional single-nucleon quasi- [1] J. M. Lattimer and M. Prakash Phys. Rept. 442 109 (2007). [2] G. Watanabe et al. Phys. Rev. Lett. 103 121101 (2009). [3] P. Danielewicz Nucl. Phys. A 727 233 (2003). [4] B. A. Li et al. Phys. Rept. 464 113 (2008). [5] C. Fuchs and H. H. Wolter Eur. Phys. J. A 30 5 (2006). [6] T. Kl¨ ahn et al. Phys. Rev. C 74 035802 (2006). [7] C. J. Horowitz and A. Schwenk Nucl. Phys. A 776 55 (2006). [8] S. Typel G. R¨ opke T. Kl¨ ahn D. Blaschke and H. H. Wolter Phys. Rev. C 81 015803 (2010). [9] J. P. Bondorf et al. Phys. Rept. 257 133 (1995). [10] M. Schmidt G. R¨ opke and H. Schulz Ann. Phys. (N.Y.) 202 57 (1990). [11] G. R¨ opke et al. Nucl. Phys. A 379 536 (1982); 424 594 (1984). [12] G. R¨ opke Phys. Rev. C 79 014002 (2009). [13] S. Typel Phys. Rev. C 71 064301 (2005). [14] H. R. Jaqaman Phys. Rev. C 38 1418 (1988). [15] H. Takemoto et al. Phys. Rev. C 69 035802 (2004). [16] V. Baran et al. Phys. Rept. 410 335 (2005). [17] M. B. Tsang et al. Phys. Rev. Lett. 102 122701 (2009). [18] S. Wuenschel et al. Phys. Rev. C 79 061602(R) (2009). [19] C. Sfienti et al. Phys. Rev. Lett. 102 152701 (2009) [20] S. Kowalski et al. Phys. Rev. C 75 014601 (2007). [21] S. Albergo et al. Nuovo Cimento A 89 1 (1985) [22] M. B. Tsang et al. Phys. Rev. Lett. 86 5023 (2001). [23] L. W. Chen et al. Phys. Rev. Lett. 94 032701 (2005); Phys. Rev. C 76 054316 (2007). [24] S. Shlomo et al. Phys. Rev. C 79 034604 (2009). [25] J. M. Lattimer et al. Nucl. Phys. A 535 331 (1991). [26] H. Shen et al. Nucl. Phys. A 637 435 (1998). [27] S. Typel et al. in preparation.
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Privilege Grant Table Column Context CREATE USER Create_user_priv Server administration CREATE VIEW Create_view_priv Views DELETE Delete_priv Tables DROP Drop_priv Databases tables or views DROP ROLE Drop_role_priv Server administration EVENT Event_priv Databases EXECUTE Execute_priv Stored routines FILE File_priv File access on server host GRANT OPTION Grant_priv Databases tables or stored routines INDEX Index_priv Tables INSERT Insert_priv Tables or columns LOCK TABLES Lock_tables_priv Databases PROCESS Process_priv Server administration PROXY See proxies_priv table Server administration REFERENCES References_priv Databases or tables RELOAD Reload_priv Server administration REPLICATION CLIENT Repl_client_priv Server administration REPLICATION SLAVE Repl_slave_priv Server administration SELECT Select_priv Tables or columns SHOW DATABASES Show_db_priv Server administration SHOW VIEW Show_view_priv Views SHUTDOWN Shutdown_priv Server administration SUPER Super_priv Server administration TRIGGER Trigger_priv Tables UPDATE Update_priv Tables or columns USAGE Synonym for “no privileges” Server administration Privileges Provided by MySQL The following table shows the dynamic privilege names used in GRANT and REVOKE statements along with the context in which the privilege applies. Table 6.3 Permissible Dynamic Privileges for GRANT and REVOKE 1188 Privilege Context APPLICATION_PASSWORD_ADMIN Dual password administration AUDIT_ADMIN Audit log administration BACKUP_ADMIN Backup administration BINLOG_ADMIN Backup and Replication administration BINLOG_ENCRYPTION_ADMIN Backup and Replication administration CLONE_ADMIN Clone administration CONNECTION_ADMIN Server administration
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For I$_{sat}$ = 0 . 15 W/cm $^{2}$ the data shown in Fig. 3 is con- sistent with an average intensity ¯ I ≈ 500 W/cm $^{2}$. 3 the excited $^{2}$P$_{1}$$_{/}$$_{2}$ state and performing the rotating-wave approximation the resonant Rabi frequency of Raman transitions between the qubit states is given by a sum over all spectral components of the comb teeth as indi- cated in Fig. 1 ($_{ℏ}$ = 1): In order to entangle multiple ions we first address the motion of the ion by resolving motional sideband tran- sitions. As depicted in Fig. 2 the pulse train is split into two perpendicular beams with wavevector difference k along the x − direction of motion. Their polarizations are mutually orthogonal to each other and to a weak magnetic field that defines the quantization axis [20]. We control the spectral beatnotes between the combs by sending both beams through AO modulators (driven at frequencies ν$_{1}$ and ν$_{2}$ ) imparting a net offset frequency of Δ ω/ 2 π = ν$_{1}$ − ν$_{2}$ between the combs. For instance in order to drive the first upper/lower sideband transi- tion we set | 2 πjν$_{R}$ + Δ ω | = ω$_{0}$ ± ω$_{t}$ with j an integer and ω$_{t}$ the trap frequency. In order to see how the side- bands are spectrally resolved we consider the following Hamiltonian of a single ion and single mode of harmonic motion interacting with the Raman pulse train: where µ is the dipole matrix element between the ground and excited electronic states E$_{k}$ ≡ ν$_{R}$ ˜ f (2 πkν$_{R}$ ) and q is an integer. In the approximate expression above the sum is replaced by an integral and each pulse is de- scribed by f ( t ) = $^{√}$π/ 2 E$_{0}$ sech( πt/τ ) with τ ≪ T where Ω$_{0}$ = ( ν$_{R}$τ ) | µE$_{0}$ | $^{2}$/ Δ = sγ $^{2}$/ 2Δ is the time-averaged res- onant Rabi frequency of the pulse train and s = ¯ I/I$_{sat}$ is the average intensity ¯ I = ν$_{R}$cϵ$_{0}$/ 2 ∫ dt | f ( t ) | 2 scaled to the $^{2}$S$_{1}$$_{/}$$_{2}$ ↔ $^{2}$P$_{1}$$_{/}$$_{2}$ saturation intensity. Note the net transi- tion rate is suppressed unless the single-pulse bandwidth is large compared to the hyperfine frequency ( ω$_{0}$τ ≪ 1) in which case Ω ≈ Ω$_{0}$. In our experiments ω$_{0}$τ ≈ 0 . 08. Ω = | µ | 2 ∑ l E$_{l}$E$_{l}$$_{−}$$_{q}$ Δ ≈ Ω$_{0}$$^{(}$ ω$_{0}$τ e ω$_{0}$τ/ 2 − e − ω$_{0}$τ/ 2 ) (2) H$_{eff}$ = ω$_{t}$a $^{†}$a + ω$_{0}$ 2 σ$_{z}$ + θ$_{p}$ 2 ∑ n δ ( t − nT ) $^{(}$σ$_{+}$ e i ( k ˆ x +Δ ωt ) + σ$_{−}$e − i ( k ˆ x +Δ ωt ) $^{)}$ (3) N − 1 ∑ n =0 Q$_{n}$ ≈ iη sin Nϑ$_{r}$/ 2 sin ϑ$_{r}$/ 2 e iϑ$_{r}$ ( N − 1) / $^{2}$σ$_{+}$ a + h.c. (7) V = exp [ − iH$_{0}$T ] exp$^{[}$ − iθ$_{p}$ 2 $^{(}$σ$_{+}$ e ik ˆ x + σ$_{−}$e − ik ˆ x ) ] (4) to satisfy the resonance condition for the red sideband ϑ$_{r}$ ≡ ( ω$_{0}$ + Δ ω − ω$_{t}$ ) T = 2 πj where j is an integer then the sum in Eq. (5) is approximately given by where θ$_{p}$ = Ω T is the change in the Bloch angle due to a single pulse σ$_{z}$ is the Pauli-z operator σ$_{±}$ are raising and lowering operators ˆ x is the x − position operator of the trapped ion a † and a are the raising and lowering operators of the x − mode of harmonic motion and the q parameter has been assumed to not be an integer or half- integer. In the interaction picture the evolution operator after N pulses is given by V $^{N}$ where The coefficient in Eq. (7) is the same as the field ampli- tude created by a diffraction grating of N slits whose narrow peaks have an amplitude equal to N . In the limit ω$_{t}$T ≪ 1 the other terms in Eq. (5) that drive the carrier and other sideband transitions can be neglected when N ≫ ( ω$_{t}$T η ) − $^{1}$. This is analogous to the de- structive interference of amplitudes away from the bright peaks in a diffraction grating. For ω$_{t}$/ 2 π = 1 . 64 MHz T = 12 . 4 ns and η = 0 . 1 the sidebands are well-resolved when N ≫ 80. and H$_{0}$ = ω$_{t}$a $^{†}$a + 1 / 2( ω$_{0}$ + Δ ω ) σ$_{z}$ . The time evolution operator is given by where D ( α ) = exp[ αa † − α $^{∗}$a ] is the harmonic oscil- lator displacement operator in phase space and η = k $^{√}$$_{ℏ}$/ 2 mω$_{t}$ is the Lamb-Dicke parameter. In the Lamb-Dicke regime η $^{√}$〈 a $^{†}$a 〉 + 1 ≪ 1 we can write D ( iηe iω$_{t}$$^{nT}$) ≈ 1 + iη ( e iω$_{t}$$^{nT}$a † + e − iω$_{t}$$^{nT}$a ) turning the sum in Eq. (5) into a geometric series. If for exam- ple the offset frequency between the combs Δ ω is tuned For many applications in quantum information the motional modes of the ion must be cooled and initial- ized to a nearly pure state. Fig. 4 shows that the pulsed laser can also be used to carry out the standard tech- niques of sideband cooling [20] to prepare the ion in the motional ground state with near unit fidelity. The set-up also easily lends itself to implementing a two-qubit entan- gling gate by applying two fields whose frequencies are symmetrically detuned from the red and blue sidebands [21 22]. By simultaneously applying two modulation fre- Q$_{n}$ ≡ σ$_{+}$e i ( ω$_{0}$ +Δ ω ) $^{nT}$D ( iηe iω$_{t}$$^{nT}$) + h.c. (6) V N = exp[ − iH$_{0}$NT ]( ˆ I − i θ$_{p}$ 2 N − 1 ∑ n =0 Q$_{n}$ + O ( θ 2 $_{p}$)) (5)
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Figure 3-11. Stabilator components. Landing Gear The Powerplant Figure 3-12. Types of landing gear: floats (top) skis (middle) and wheels (bottom). The powerplant usually includes both the engine and the propeller. The primary function of the engine is to provide the power to turn the propeller. It also generates electrical power provides a vacuum source for some flight instruments and in most single-engine airplanes provides a source of heat for the pilot and passengers. [Figure 3-13] The engine is covered by a cowling or a nacelle which are both types of covered housing. The purpose of the cowling or nacelle is to streamline the flow of air around the engine and to help cool the engine by ducting air around the cylinders. is a rotating airfoil that produces thrust through aerodynamic action. A high-pressure area is formed at the back of the propeller’s airfoil and low pressure is produced at the face of the propeller similar to the way lift is generated by an airfoil used as a lifting surface or wing. This pressure differential develops thrust from the propeller which in turn pulls the airplane forward. Engines may be turned around to be pushers with the propeller at the rear. There are two significant factors involved in the design of a propeller that impact its effectiveness. The angle of a The propeller mounted on the front of the engine translates the rotating force of the engine into thrust a forward acting force that helps move the airplane through the air. A propeller Airplanes with conventional landing gear are sometimes referred to as tailwheel airplanes. When the third wheel is located on the nose it is called a nosewheel and the design is referred to as a tricycle gear. A steerable nosewheel or tailwheel permits the airplane to be controlled throughout all operations while on the ground. Most aircraft are steered by moving the rudder pedals whether nosewheel or tailwheel. Additionally some aircraft are steered by differential braking. Wheeled landing gear consists of three wheels—two main wheels and a third wheel positioned either at the front or rear of the airplane. Landing gear with a rear mounted wheel is called conventional landing gear. The landing gear is the principal support of the airplane when parked taxiing taking off or landing. The most common type of landing gear consists of wheels but airplanes can also be equipped with floats for water operations or skis for landing on snow. [Figure 3-12] 3-7 Antiservo tab Stabilator pivot point
2laws_and_regulations
We may be adversely impacted by new laws regulations or policies of governmental organizations related to increased fuel economy standards and reduced greenhouse gas emissions or changes in existing ones. The markets and customers we serve are subject to a substantial amount of government regulation which often dif fers by state region and country. Government regulations and proposals for additional regulation are advanced primarily out of concern for the environment (including concerns about the possibility of global climate change and its impact) and ener gy independence. We anticipate that the number and extent of these regulations and the costs to comply with them will increase significantly in the future. In the U.S. vehicle fuel economy and greenhouse gas emissions are regulated under a harmonized national program administered by the National Highway Traffic Safety Administration and the Environmental Protection Agency. Other governments in the markets we serve are also creating new policies to address these same issues including the European Union Brazil China and India. These government regulatory requirements could significantly af fect our customers by altering their global product development plans and substantially increasing their costs which could result in limitations on the types of vehicles they sell and the geographical markets they serve. Any of these outcomes could adversely af fect our financial position and results of operations. We have taken and continue to take cost-reduction actions. Although our process includes planning for potential negative consequences the cost-reduction actions may expose us to additional production risk and could adversely affect our sales profitability and ability to attract and retain employees. We have been reducing costs in all of our businesses and have discontinued product lines exited businesses consolidated manufacturing operations and positioned operations in lower cost locations. The impact of these cost-reduction actions on our sales and profitability may be influenced by many factors including our ability to successfully complete these ongoing ef forts our ability to generate the level of cost savings we expect or that are necessary to enable us to ef fectively compete delays in implementation of anticipated workforce reductions decline in employee morale and the potential inability to meet operational targets due to our inability to retain or recruit key employees. Dana Holding Corporation is a holding company. Our subsidiaries conduct all of our operations and own substantially all of our assets. Our cash flow and our ability to meet our obligations depend on the cash flow of our subsidiaries. In addition the payment of funds in the form of dividends intercompany payments tax sharing payments and otherwise may be subject to restrictions under the laws of the countries of incorporation of our subsidiaries or the by-laws of the subsidiary. Labor stoppages or work slowdowns at Dana key suppliers or our customers could result in a disruption in our operations and have a material adverse effect on our businesses. We operate as a holding company and depend on our subsidiaries for cash to satisfy the obligations of the holding company. We and our customers rely on our respective suppliers to provide parts needed to maintain production levels. We all rely on workforces represented by labor unions. Workforce disputes that result in work stoppages or slowdowns could disrupt operations of all of these businesses which in turn could have a material adverse ef fect on the supply of or demand for the products we supply our customers. We could be adversely affected if we are unable to recover portions of commodity costs (including costs of steel other raw materials and energy) from our customers. We continue to work with our customers to recover a portion of our material cost increases. While we have been successful in the past recovering a significant portion of such cost increases there is no assurance that increases in commodity costs will not adversely impact our profitability in the future. We could be adversely affected if we experience shortages of components from our suppliers or if disruptions in the supply chain lead to parts shortages for our customers. A substantial portion of our annual cost of sales is driven by the purchase of goods and services. To manage and minimize these costs we have been consolidating our supplier base. As a result we are dependent on single sources of supply for some components of our products. We select our suppliers based on total value (including price delivery and quality) taking into consideration their production capacities and financial condition and we expect that they will be able to support our needs. Company-Specific Risk Factors 7
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FIG. 3: Photomicrograph of unstable flow in the second expansion for a concentration of 64 ppm high molecular weight (18 × 10 6 Da) polyacrylamide polymer added. It is apparent that large instabilities are excited that display a dominant scale set by the microchannel. Dashed outlines indicate field of view and microchannel outline; the 160 µ m long solid line indicates where the space-time diagram slice was taken for the expansion regions. The instabilities in the constriction regions can also be seen here at the sides of the image; regions are centered for data collecting. the limited bandwidth visual evidence (see Fig. 3) that large scale instabilities dominate the instability spectrum. The lack of enhanced diffusion confirms that small scale instabilities below the camera resolution are not excited to a significant extent. Finding the first moment mixing index M1 for concentrations of 0 ppm 32 ppm and 64 ppm as the fluid moves downstream reveals that absolute mixing is reduced in viscoelastic solutions relative to the polymer-free sample; Fig. 7. We also observe an increase in the rate of change in mixing downstream for viscoelastic solutions. By looking at the flow at different constriction units (N=2 4 8) the mixing length is calculated and we find a mild decrease with raising polymer concentration; the mixing length reduces from 4.5 for 0 ppm to 4.2 for 32 ppm and finally 3.2 for 64 ppm. For diffusion from an ideal sharp 2D interface [28] changing viscosity simply shifts calculated M1 by a constant for our parameters indicating that the change in mixing length can be attributed to the action of instabilities. For an uniform microchannel we calculate [28] M1 values roughly twice as large as we observe for polymer-free solutions in our channels corrugated with constriction/expansions. This enhanced mixing has been previously observed for electro-osmotic flows through con- 8
5scientific_articles
contracts and other assets ($8 million) and the write-off of capitalized software costs arising from a decision to change a technology platform ($2 million). A summary of the restructuring costs and other charges recorded in the fourth quarter of 2001 is detailed as follows: resulting lease expense due to the consolidation of facilities will be paid over the respective lease terms through 2012. Further detail regarding the charges is shown below: The remaining liability related to the workforce reduction and fundings under guarantees will be substantially paid by the end of 2002. The amounts related to the space reduction and OPERATING PROFIT IMPACT NON-OPERATING IMPACT Marriott International Inc. 2001 Annual Report 12 Total corporate Corporate Provision for Interest expenses and expenses loan losses income interest ($ in millions) Severance $ 4 $— $— $ 4 Facilities exit costs 14 — — 14 Total restructuring costs 18 — — 18 Reserves for guarantees and loan losses — 43 6 49 Impairment of technology-related investments and other 22 — — 22 Total $40 $43 $ 6 $89 Senior Full- Select- Extended- Living Distribution Service Service Stay Timeshare Services Services Total ($ in millions) Severance $ 7 $ 1 $ 1 $2 $— $1 $ 12 Facilities exit costs — — 5 — — 1 6 Development cancellations and elimination of product line 19 4 5 — 60 — 88 Total restructuring costs 26 5 11 2 60 2 106 Reserves for guarantees and loan losses 30 3 3 — — — 36 Accounts receivable – bad debts 11 1 — — 2 3 17 Write-down of properties held for sale 9 4 — — — — 13 Impairment of technology-related investments and other 8 — 2 — — — 10 Total $84 $13 $16 $2 $62 $5 $182 Cash Restructuring costs payments in and other charges Non-cash fourth quarter liability at Total charge charge 2001 December 28 2001 ($ in millions) Severance $ 16 $ 2 $6 $ 8 Facilities exit costs 20 — 2 18 Development cancellations and elimination of product line 88 88 — — Total restructuring costs 124 90 8 26 Reserves for guarantees and loan losses 85 52 — 33 Accounts receivable – bad debts 17 17 — — Write-down of properties held for sale 13 13 — — Impairment of technology-related investments and other 32 31 — 1 Total $271 $203 $8 $60
0financial_reports