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4 of 124 Construction of Giresun Wastewater Treatment Plant Tender Dossier Volume 3 Employer’s Requirements Section 08: Electrical Works 8.20 Network Firewall (firewall) .................................................................................................. 91 8.20.1 General .................................................................................................................................. 91 8.20.2 Properties of Industrial Firewall............................................................................................ 92 8.21 Hardware requirements ......................................................................................................... 93 8.21.1 General .................................................................................................................................. 93 8.21.2 Monitoring station................................................................................................................. 93 8.21.3 Monitor.................................................................................................................................. 95 8.21.4 Report and Graphical Printer ................................................................................................ 95 8.21.5 Laptop Monitoring Station.................................................................................................... 96 8.22 Communication Network ...................................................................................................... 97 8.22.1 Data Handling ....................................................................................................................... 97 8.22.2 Data Presentation .................................................................................................................. 98 8.22.3 Maintenance application ....................................................................................................... 99 8.22.4 Flow pictures......................................................................................................................... 101 8.22.5 Alarm Handling..................................................................................................................... 102 8.22.6 Configuration ........................................................................................................................ 104 8.23 Application Programs Functions.......................................................................................... 104 8.23.1 General .................................................................................................................................. 104 8.23.2 Tag numbering ...................................................................................................................... 105 8.23.3 Emergency control ................................................................................................................ 105 8.23.4 Group control ........................................................................................................................ 106 8.23.5 Motor routine 1 ..................................................................................................................... 106 8.23.6 Motor routine 1-1 .................................................................................................................. 106 8.23.7 Motor routine 2 ..................................................................................................................... 107 8.23.8 Motor valve routine 1............................................................................................................ 107 8.23.9 Motor valve routine 1-1 ........................................................................................................ 108 8.23.10 Standard regulator (Controller) ............................................................................................. 109 8.23.11 Status/alarm handling 1......................................................................................................... 109 8.23.12 System alarm......................................................................................................................... 109 8.23.13 Instruments............................................................................................................................ 109 8.24 Tests ...................................................................................................................................... 110 8.24.1 Handling of Deviations ......................................................................................................... 110 8.24.2 Electrical - General ............................................................................................................... 110 8.24.3 Panel factory test ................................................................................................................... 111 8.24.4 Automation............................................................................................................................ 113 8.24.5 Usability ................................................................................................................................ 113 8.24.6 Installation and start up ......................................................................................................... 113 8_Vol3_d4 3_Section 8 electrical works_en_GIR rev6.doc | government_tenders |
x ′′ + 5( x 2 − 1) x ′ + x = 5 cos(2 . 467 t ) } B$_{1}$ Y ′ = 1 . 5 [tanh( Y ) − 0 . 25 K − (4 / 3) Y ] + 0 . 0045 x ( t ) K ′ = tanh( Y ( t − τ )) − 0 . 5 $_{K.}$ (5.15) differential equations using the results of the paper [9]. In this section we will demonstrate numerically the formation of chaotic business cycles in the Kaldor-Kalecki model with time delay. Let us take into account the system Equation B$_{1}$ is the chaotic Van der Pol oscillator which is used as the generator system in (5.15). Van der Pol type equations have played a role in economic modelling [40 41 58]. It is shown by Parlitz and Lauterborn [69] that equation B$_{1}$ is chaotic through period-doubling cascade. The process of period- doubling is described by Thompson and Stewart [82]. This implies that there are infinitely many unstable periodic solutions of B$_{1}$ all with different periods. Due to the absence of stability any solution that starts near the periodic motions behaves irregularly . We will interpret the solution x ( t ) as an irregular productivity shock. System B$_{2}$ is the Kaldor-Kalecki model and it is the result of the perturbation of the model (3.10) of an aggregate economy with a productivity shock. We will observe numerically the appearance of a chaotic business cycle and in particular the entrainment by chaos of the limit cycle of system (3.10) in the next simulations. Let us take τ = 5 . 5 in B$_{2}$ so that the system possesses an orbitally stable limit cycle in the absence of perturbation [87]. We make use of the solution x ( t ) of B$_{1}$ with x (0) = 1 . 1008 x $^{′}$(0) = − 1 . 5546 and present in Figure 11 the solution of B$_{2}$ with the initial condition Y ( t ) = u ( t ) and K ( t ) = v ( t ) for t ∈ [ − τ 0] where u ( t ) = − 0 . 057 and v ( t ) = 0 . 063 are constant functions. Figure 11 reveals that the dynamics of B$_{2}$ exhibits chaotic business cycles. This result shows that our theory of chaotic business cycles can be extended to systems with time delay. Figure 11: The appearance of chaotic business cycle in the Kaldor-Kalecki model B$_{2}$. −0.15 −0.1 −0.05 0 0.05 0.1 0.15 −0.2 −0.15 −0.1 −0.05 0 0.05 0.1 0.15 0.2 Y K 17 | scientific_articles |
6.3 Without prejudice to the contracting authority’s other rights under Articles I.16 and II.18 of the FWC if the contractor fails to meet his obligations the specific contract with the contracting authority may be terminated in accordance with Article II.7 of the General Conditions of the FWC. This clause applies throughout the term of the specific contract. 7.1 Performance guarantee 7.2 Retention Money Guarantee 8.1 Any communication under this specific contract shall be made in accordance with Article I.8 of the FWC. $^{ }$8.2 The persons responsible for the implementation of this specific contract 31 ARTICLE 8: GENERAL ADMINISTRATIVE PROVISIONS ARTICLE 7: GUARANTEES $^{ }$[Not applicable] [or] [This contract is subject to a performance guarantee of [ complete ] % of the price of the contract [excluding travel expenses] ]. The contractor (or leader in the case of a joint tender) must provide a performance guarantee in the form of a financial guarantee for EUR [ amount in figures and in words] in accordance with the conditions laid down in Article II.21.5. The guarantee must be released [ 30 ] [ 60 ] [ 90 ] days after the final approval of the services.] [Retention money guarantee is not applicable to this specific contract.] [This contract is subject to a retention money guarantee of [complete] % of the price of the contract [excluding travel expenses]]. [Option 1: Retention money guarantee by deduction] [The guarantee is constituted by deduction of this amount on payments. It will be withheld for up to [30] [60] [90] days after the final approval of the service.] [Option 2: Retention money guarantee by financial guarantee] [The contractor (or leader in the case of a joint tender) must provide a retention money guarantee in the form of a financial guarantee for EUR [a mount in figures and in words] in accordance with the conditions laid down in Article II.21.5. The guarantee must be released [30] [60] [90] days after the final approval of the services.] | government_tenders |
What We Covered In this book we covered 24 of the most popular patterns from Kubernetes grouped as the following: Like all good things this book has come to an end. We hope you have enjoyed read‐ ing this book and that it has changed the way you think about Kubernetes. We truly believe Kubernetes and the concepts originating from it will be as fundamental as object-oriented programming concepts are. This book is our attempt to create the Gang of Four Design Patterns but for container orchestration. We hope this is not the end but the beginning for your Kubernetes journey; it is so for us. Happy kubectl-ing. Final Words • Foundational patterns represent the principles that containerized applications must comply with in order to become good cloud-native citizens. Regardless of the application nature and the constraints you may face you should aim to fol‐ low these guidelines. Adhering to these principles will help ensure that your applications are suitable for automation on Kubernetes. • Behavioral patterns describe the communication mechanisms and interactions between the Pods and the managing platform. Depending on the type of the workload a Pod may run until completion as a batch job or be scheduled to run periodically. It can run as a daemon service or singleton. Picking the right man‐ agement primitive will help you run a Pod with the desired guarantees. • Structural patterns focus on structuring and organizing containers in a Pod to satisfy different use cases. Having good cloud-native containers is the first step but not enough. Reusing containers and combining them into Pods to achieve a desired outcome is the next step. • Configuration patterns cover customizing and adapting applications for different configuration needs on the cloud. Every application needs to be configured and no one way works for all. We explore patterns from the most common to the most specialized. • Advanced patterns explore more complex topics that do not fit in any of the other categories. Some of the patterns such as Controller are mature—Kubernetes itself is built on it—and some are still new and might change by the time you read this book. But these patterns cover fundamental ideas that cloud-native developers should be familiar with. 238 | Afterword | manuals |
Housing Crank Pinion Dial Float Float Cover glass Gasket Pointer magnet Tank + A B F DC power Tank resistor N S E Float 14-38 Figure 14-69. A DC electric fuel quantity indicator uses a variable resistor in the tank unit which is moved by a float arm. Figure 14-68. Simple mechanical fuel indicators used on light aircraft with fuel tanks in close proximity to the pilot. Digital indicators are available that work with the same variable resistance signal from the tank unit. They convert the variable resistance into a digital display in the cockpit instrument head. [Figure 14-70] Fully digital instrumentation systems such as those found in a glass cockpit aircraft convert the variable resistance into a digital signal to be processed in a computer and displayed on a flat screen panel. Electric fuel quantity indicators are more common than mechanical indicators in modern aircraft. Most of these units operate with direct current (DC) and use variable resistance in a circuit to drive a ratiometer-type indicator. The movement of a float in the tank moves a connecting arm to the wiper on a variable resistor in the tank unit. This resistor is wired in series with one of the coils of the ratiometer-type fuel gauge in the instrument panel. Changes to the current flowing through the tank unit resistor change the current flowing through one of the coils in the indicator. This alters the magnetic field in which the indicating pointer pivots. The calibrated dial indicates the corresponding fuel quantity. [Figure 14-69] Figure 14-67. A float-type sight gauge fuel quantity indicator. | laws_and_regulations |
Event Scheduler Configuration •In MySQL an event is uniquely identified by its name and the schema to which it is assigned. •An event performs a specific action according to a schedule. This action consists of an SQL statement which can be a compound statement in a BEGIN ... END block if desired (see Section 13.6 “Compound Statement Syntax” ). An event’s timing can be either one-time or recurrent . A one-time event executes one time only. A recurrent event repeats its action at a regular interval and the schedule for a recurring event can be assigned a specific start day and time end day and time both or neither. (By default a recurring event’s schedule begins as soon as it is created and continues indefinitely until it is disabled or dropped.) •Users can create modify and drop scheduled events using SQL statements intended for these purposes. Syntactically invalid event creation and modification statements fail with an appropriate error message. A user may include statements in an event’s action which require privileges that the user does not actually have . The event creation or modification statement succeeds but the event’s action fails. See Section 25.4.6 “The Event Scheduler and MySQL Privileges” for details. If a repeating event does not terminate within its scheduling interval the result may be multiple instances of the event executing simultaneously. If this is undesirable you should institute a mechanism to prevent simultaneous instances. For example you could use the GET_LOCK() function or row or table locking. The default definer of an event is the user who created the event unless the event has been altered in which case the definer is the user who issued the last ALTER EVENT statement affecting that event. An event can be modified by any user having the EVENT privilege on the database for which the event is defined. See Section 25.4.6 “The Event Scheduler and MySQL Privileges” . •Many of the properties of an event can be set or modified using SQL statements. These properties include the event’s name timing persistence (that is whether it is preserved following the expiration of its schedule) status (enabled or disabled) action to be performed and the schema to which it is assigned. See Section 13.1.3 “ALTER EVENT Statement” . •An event’s action statement may include most SQL statements permitted within stored routines. For restrictions see Section 25.8 “Restrictions on Stored Programs” . 25.4.2 Event Scheduler Configuration Events are executed by a special event scheduler thread ; when we refer to the Event Scheduler we actually refer to this thread. When running the event scheduler thread and its current state can be seen by users having the PROCESS privilege in the output of SHOW PROCESSLIST as shown in the discussion that follows. The global event_scheduler system variable determines whether the Event Scheduler is enabled and running on the server. It has one of these 3 values which affect event scheduling as described here. The default is ON . When the Event Scheduler is ON the event scheduler thread is listed in the output of SHOW PROCESSLIST as a daemon process and its state is represented as shown here: • ON : The Event Scheduler is started; the event scheduler thread runs and executes all scheduled events. mysql> SHOW PROCESSLIST\G *************************** 1. row *************************** Id: 1 User: root Host: localhost db: NULL Command: Query Time: 0 4738 | manuals |
EUOSHA/2021/OP/F/SE/0142 Overall management incl. identification and invitation of journalists and experts Kick-off meeting for definition of topic and key messages elaboration of concept • Kick-off meeting between the EU-OSHA’s national partner and the Contractor’s national partner should determine the overall approach and concept of the round table (including its focus topic and key messages); • Concept to be elaborated including a structure and agenda of the roundtable with suggestions of spokespersons /experts and journalists. • Planning grid to do list template and other resources should be provided by Contractor headquarters. EU-OSHA’s national partner to provide the Contractor’s national partner with OSH related background information relevant for the main topic of the round table; • The insurance will be arranged via a framework contract with an insurance company through the Contractor; • The Contractor’s national partner must identify key media/journalists from general and specialised media (national and regional); • Final list of suggested media/journalists should be approved by the EU-OSHA’s national partner; • The Contractor’s national partner could assist EU-OSHA's national partner in identifying the experts; • National and regional media should be approached to ensure broad and sufficient media coverage. EU-OSHA’s national partner should advise if any specific media is desired; • The Contractor’s national partner is responsible for the layout design and text of the invitation; • Invitations should include main information on subject of the round table including attending spokespersons agenda address of venue/e-platform contact details etc.; • EU-OSHA’s national partner has to approve the draft invitations in a timely manner; • Invitation template has to be made available by Contractor headquarters. Final invitations should be uploaded to EU-OSHA’s online collaborative tool by Contractor headquarters. • Invitation’s branding should respect EU-OSHA's campaign/project design and includes the national logo of EU-OSHA any other relevant logo and the EU-OSHA’s national partner's institution; • Invitations to be sent out via e-mail by the Contractor’s national partner; 61 Identification invitation and briefing of journalists/experts | government_tenders |
Nov. 17 2016 25 US 2016/0334706 Al 0 OH 0 [{Yo ~’ v::;? y ’so 0 F2 0 C (o Y’so -continued -continued [0086] The ammonium salt (B) may be any of arbitrary combinations of cations with anions both as exemplified above. [0087] The ammonium salt (B) may be synthesized by any organic chemistry procedures well known to the artisan in the art. For example the desired compound may be synthe› sized by mixing a cation-containing compound and an anion-containing compound in an organic solvent/water two-layer system effecting ion exchange reaction therebe› tween and extracting the organic layer. With respect to the ion exchange reaction reference may be made to JP-A 2007-145797 for example. The cation moiety may be pur› chased in the market or synthesized by reaction of a tertiary amine compound with an alkyl halide for example. The anion moiety may be purchased in the market or synthesized by any well-known procedures. In particular with respect to the anion moiety of the compound having formula (5) reference may be made to JP-A 2007-145797 and JP-A 2009-258695 for example. [0088] The resist composition of the invention is success› ful in improving several lithography properties typically sensitivity and resolution while maintaining excellent LER. [0089] Although the reason is not well understood it is presumed that the addition of ammonium salt (B) has a good influence. Since the ammonium salt (B) has an anion struc› ture which is a conjugated base of strong acid and a cation moiety which is a quaternary ammonium salt it is not decomposed under the action of light or heat in the lithog› raphy process. As used herein the strong acid refers to a compound having an acidity sufficient to cleave an acid labile group in the base resin. On the other hand the PAG generates an acid upon exposure. It is believed that part of the generated acid undergoes salt exchange reaction with the ammonium salt (B). That is the acid generated by the PAG acts on the ammonium salt at a different site and the counter | patents |
Table of Contents protectionism U.S. relations with the governments of the foreign countries in which we operate foreign regulatory requirements or changes in such requirements changes in local health care payment systems and health care delivery systems local product preferences and requirements longer payment terms for account receivables than we experience in the U.S. difficulty in establishing staffing and managing foreign operations changes to international trade agreements and treaties changes in tax laws weakening or loss of the protection of intellectual property rights in some countries and import or export licensing requirements. The success of our operations outside the United States also depends in part on our ability to make necessary infrastructure enhancements to among other things our production facilities and sales and distribution networks. These and other factors may adversely impact our ability to pursue our growth strategy in these markets. In addition our international operations are governed by the U.S. Foreign Corrupt Practices Act and similar anti-corruption laws outside the U.S. Global enforcement of anti-corruption laws has increased substantially in recent years with more enforcement proceedings by U.S. and foreign governmental agencies and the imposition of significant fines and penalties. While we have implemented policies and procedures to enhance compliance with these laws our international operations which often involve customer relationships with foreign governments create the risk that there may be unauthorized payments or offers of payments made by employees consultants sales agents or distributors. Any alleged or actual violations of these laws may subject us to government investigations and significant criminal or civil sanctions and other liabilities and negatively affect our reputation. Changes in U.S. policy regarding international trade including import and export regulation and international trade agreements could also negatively impact our business. The U.S. has imposed tariffs on steel and aluminum as well as on goods imported from China and certain other countries which has resulted in retaliatory tariffs by China and other countries. Additional tariffs imposed by the U.S. on a broader range of imports or further retaliatory trade measures taken by China or other countries in response could result in an increase in supply chain costs that we may not be able to offset or that otherwise adversely impact our results of operations. The United Kingdom’s (“UK”) departure from the European Union (“EU”) (commonly known as “Brexit”) has created uncertainties affecting business operations in the UK the EU and a number of other countries including with respect to compliance with the regulatory regimes regarding the labeling and registration of the products we sell in these markets. The UK formally left the EU on January 31 2020. Pursuant to the withdrawal arrangement agreed between the UK and the EU there is a transition period through December 31 2020 for the parties to negotiate their future trading relationship. During this transition period the UK continues to follow the EU’s rules and its trading relationship with the EU remains the same. While we have taken proactive steps to mitigate any disruption to our operations we could face increased costs volatility in exchange rates market instability and other risks depending on the outcome of the negotiations regarding the future EU/UK trading relationship. We sell products to researchers at pharmaceutical and biotechnology companies academic institutions government laboratories and private foundations. Research and development spending of our customers can fluctuate based on spending priorities and general economic conditions. A number of these customers are also dependent for their funding upon grants from U.S. government agencies such as the U.S. National Institutes of Health (“NIH”) and agencies in other countries. The level of government funding of research and development is unpredictable. For instance there have been instances where NIH grants have been frozen or otherwise unavailable for extended periods. The availability of governmental research funding may be adversely affected by economic conditions and governmental spending reductions. Any reduction or delay in governmental funding could cause our customers to delay or forego purchases of our products. Our ability to compete effectively depends upon our ability to attract and retain executives and other key employees. Competition for experienced employees particularly for persons with specialized skills can be Reductions in customers’ research budgets or government funding may adversely affect our business. We need to attract and retain key employees to be competitive. 13 | financial_reports |
(2008). [12] T. K¨ okler K. G´ oral “Production of cold molecules via magnetically tunable Feshbach reso- nances” Rev. Mod. Phys. 78 1311 (2006). [13] J.L. Hall L. Hollberg T. Baer H.G. Robinson “Optical heterodine saturation spectroscopy” Appl. Phys. Lett. 39 680 (1981). [14] T. Suzuki M. Hirai M. Katsuragawa “Octave-spanning raman comb with carrier envelope offcet control” Phys. Rev. Lett. 101 243602 (2008). 14 | scientific_articles |
transfer [Eq. (9)] and thus the logarithmic falloff from pQCD quantum loops will dominate in this regime. It is interesting to illustrate what one expects in an augmented model which contains the standard pQCD contributions. We can use the similarity of the AdS coupling to the effective charge α$_{g}$$_{1}$ at small scales as guide on how to join the perturbative and nonperturbative regimes. The fit to the data α fit g 1 from Ref. [39] agrees with pQCD at high momentum. Thus the α$_{g}$$_{1}$ ( Q $^{2}$) coupling provides a guide for the analytic form of the coupling over all Q $^{2}$. We write The β function for the nonperturbative effective coupling obtained from the LF holo- graphic mapping in a positive dilaton-modified AdS background is The solid line in Fig. 2 corresponds to the light-front holographic result Eq. (12). Near Q$_{0}$ ≃ 2 κ ≃ 1 GeV we can interpret the results as a transition from the nonperturbative IR domain to the quark and gluon degrees of freedom in the perturbative UV regime. The transition momentum scale Q$_{0}$ is compatible with the momentum transfer for the onset of scaling behavior in exclusive reactions where quark counting rules are observed. [16] For example in deuteron photo-disintegration the onset of scaling corresponds to momentum transfer of 1.0 GeV to the nucleon involved. [41] Dimensional counting is built into the AdS/QCD soft and hard-wall models since the AdS amplitudes Φ( z ) are governed by their V. HOLOGRAPHIC β FUNCTION α AdS Modified g $_{1}$( Q $^{2}$) = α AdS g 1 ( Q $^{2}$) g$_{+}$ ( Q $^{2}$) + α fit g 1 ( Q $^{2}$) g − ( Q $^{2}$) . (11) Here α AdS g 1 is given by Eq. (9) with the normalization (10) [continuous line in Fig. 1] and α fit g 1 is the analytical fit to the measured coupling α$_{g}$$_{1}$ . [39] These couplings have the same normalization at Q 2 = 0 given by Eq. (10). We use the fit from [39] rather than using pQCD directly since the perturbative results are meaningless near or below the transition region and thus would not allow us to obtain a smooth transition and analytical expression of α$_{g}$$_{1}$ . In order to smoothly connect the two contributions (dot-dashed line in Fig. 1) we employ smeared step functions. For convenience we have chosen g ± ( Q $^{2}$) = 1 / (1+ e ± ( Q $^{2}$− Q 2 0 ) /τ $^{2}$) with the parameters Q 2 0 = 0 . 8 GeV 2 and τ 2 = 0 . 3 GeV $^{2}$. β AdS g 1 ( Q $^{2}$) = d d log Q $_{2}$α AdS g 1 ( Q $^{2}$) = πQ 2 4 κ 2 e − Q $^{2}$/ (4 κ $^{$^{2}$)}$. (12) 12 | scientific_articles |
Adjusted Earnings Cash from Continuing Operating Activities Crude Oil Average Realized Price 3 NGL Average Realized Price 3 Natural Gas Average Realized Price 3 9 ConocoPhillips 2014 ANNUAL REPORT 2012 2013 2014 105.98 103.51 92.94 0 10 20 30 40 (Dollars per Barrel) 12 11 2012 2013 2014 45.55 40.79 38.71 0 1 2 3 4 5 6 7 8 500 1000 1500 (Dollars per Barrel) 20 12 20 11 2012 2013 2014 5.38 6.00 6.48 0 2000 4000 6000 (Dollars per Thousand Cubic Feet) 2012 2013 2014 156 179 124 20 12 20 11 62% 58% 38% 42% (Percent) 0 50 100 150 200 2012 2013 2014 8 921 8 906 (MMBOE) 38% 62% 38% 62% 38% 62% 8 642 Liquids Natural Gas 56% 55% 53% 44% 45% 47% 0 20 40 60 80 100 2012 2013 2014 45% 1 527 55% 44% 1 502 56% 43% 1 540 57% Liquids Natural Gas (MBOED) 15 722 17 144 ($ Millions) 2012 2013 2014 16 918 5000 10000 15000 15 801 16 592 ($ Millions) 2012 2013 2014 13 458 ($ Millions) 6 734 7 061 2012 2013 2014 6 609 Capital Program 1 Total Production 2 Proved Reserves 3 Organic Reserve Replacement Ratio 4 | financial_reports |
of the aircraft. This will allow rotary wing takeoff performance with fixed wing cruise speeds. [Figure 15-3] The landing gear provides the mobility while on the ground and may be either conventional or tricycle. Conventional gear consists of two main wheels and one under the tail. The tricycle configuration also uses two mains with the third wheel under the nose. Early auto- gyros and several models of gyroplanes use conven- tional gear while most of the later gyroplanes incorporate tricycle landing gear. As with fixed wing aircraft the gyroplane landing gear provides the ground mobility not found in most helicopters. Wings may or may not comprise a component of the gyroplane. When used they provide increased per- formance increased storage capacity and increased stability. Gyroplanes are under development with wings that are capable of almost completely unload- ing the rotor system and carrying the entire weight Figure 15-3. The CarterCopter uses wings to enhance performance. WINGS LANDING GEAR 15-3 | laws_and_regulations |
SHOW Statements | jon@ghidora | myschema | +----------------+----------+ 1 row in set (0.00 sec) mysql> SHOW EVENTS\G *************************** 1. row *************************** Db: myschema Name: e_daily Definer: jon@ghidora Time zone: SYSTEM Type: RECURRING Execute at: NULL Interval value: 1 Interval field: DAY Starts: 2018-08-08 11:06:34 Ends: NULL Status: ENABLED Originator: 1 character_set_client: utf8mb4 collation_connection: utf8mb4_0900_ai_ci Database Collation: utf8mb4_0900_ai_ci To see events for a specific schema use the FROM clause. For example to see events for the test schema use the following statement: SHOW EVENTS FROM test; The LIKE clause if present indicates which event names to match. The WHERE clause can be given to select rows using more general conditions as discussed in Section 26.8 “Extensions to SHOW Statements” . SHOW EVENTS output has these columns: The name of the schema (database) to which the event belongs. The name of the event. The account of the user who created the event in ’ user_name ’@’ host_name ’ format. The event time zone which is the time zone used for scheduling the event and that is in effect within the event as it executes. The default value is SYSTEM . The event repetition type either ONE TIME (transient) or RECURRING (repeating). For a one-time event this is the DATETIME value specified in the AT clause of the CREATE EVENT statement used to create the event or of the last ALTER EVENT statement that modified the event. The value shown in this column reflects the addition or subtraction of any INTERVAL value included in the event’s AT clause. For example if an event is created using ON SCHEDULE AT CURRENT_TIMESTAMP + ’1:6’ DAY_HOUR and the event was created at 2018-02-09 14:05:30 the value shown in this • Execute At 2930 • Type • Time zone • Definer • Name • Db | manuals |
COMMANDER RESOURCES LTD. (An Exploration Stage Company) Notes to Financial Statements For the Years Ended December 31 2012 and 2011 (Expressed in Canadian dollars) 9. Exploration and Evaluation Assets (Continued) (f) Sabin Ontario (g) Other Properties i. Sarah Lake Labrador ii. Olympic and Rob Yukon iii. Tam British Columbia The Sabin copper-zinc property consists of 114 claims located in northwest Ontario. Ownership interests of Commander on the property vary from 58.5% to 100%. The Company owns several other properties in Canada in which it holds interests ranging from 10% to 100%. The Company has granted options on some of these properties. The carrying values of those properties included under Other Properties at December 31 2012 and 2011 is as follows: The Company owns a 48.2% interest in the Sarah Lake property. Donner Metals Ltd. owns 51.8% and is the operator of the property. Note Ownership% Metal 2012 2011 Labrador Properties Sally 100.00 Nickel 393 241 $ 393 241 $ Sandy 100.00 Nickel 39 736 27 482 Sarah Lake 9(g)(i) 48.20 Nickel 1 778 627 1 766 060 Yukon Olympic Rob 9(g)(ii) 100.00 Copper-Gold-Uranium 882 089 874 258 British Columbia Tam 9(g)(iii) 10.00 Copper - 9 524 NewBrunswick Nepisiguit/Stewart 9(g)(iv) 100.00 Copper-Zinc 1 128 853 1 126 894 Ontario Houghton Lake 9(g)(v) 15 000 - Matheson 9(h) 41.20 Gold - 15 685 McVean 9(h) 100.00 Gold - 9 835 Total Other Properties 4 237 546 $ 4 222 979 $ The Company owns 100% of the Olympic and Rob properties subject to a 1% NSR registered to Blackstone Ventures Inc. on the Rob property. The NSR may be reduced to 0.5% at any time for $1 million. The Olympic property is located within the boundary of the Peel Watershed Regional Land Use Plan and is subject to restrictions on certain mining activities. The final recommendations have not been completed by the regulatory authorities. Any adverse recommendations could lead to an impairment write-down of approximately $744 000. The Company owned a 10% carried interest in the property. Under an agreement dated February 13 2006 between the underlying owners and Teck Resources Limited (“Teck”) the Company is entitled to a 1.5% NSR of which $250 000 is payable as an advance royalty starting on December 31 2012. Teck and its partner Lorraine Copper Corp. now own 100% of the Tam property subject to a 3% NSR which is subject to a buy- down to 1% for $2 000 000. A $50 000 annual royalty payment is payable beginning December 31 2012 capped at $500 000 half of which is payable to the Company. - 22 - | financial_reports |
Daducci A. Gerhard S. Griffa A. Lemkaddem A. Cammoun L. Gigandet X. Meuli R. Hagmann P. Thiran J.-P. 2012. The connectome mapper: an open-source processing pipeline to map connectomes with mri. PLoS ONE 7 (12) e48121. Dall J. Christensen M. 2002. Random geometric graphs. Physical Review E 66 (1) 016121. de Reus M. A. van den Heuvel M. P. 2014. Simulated rich club lesioning in brain networks: a scaffold for communication and integration? Frontiers in Human Neuroscience 8 647. Destrieux C. Fischl B. Dale A. Halgren E. 2010. Automatic parcellation of human cortical gyri and sulci using standard anatomical nomenclature. Neuroimage 53 (1) 1–15. Ercsey-Ravasz M. Markov N. T. Lamy C. Van Essen D. C. Knoblauch K. Toroczkai Z. Kennedy H. 2013. A predictive network model of cerebral cortical connectivity based on a distance rule. Neuron 80 (1) 184–197. Fortunato S. 2010. Community detection in graphs. Physics Reports 486 (3) 75–174. Friedman E. J. Landsberg A. S. Owen J. Hsieh W. Kam L. Mukherjee P. 2015. Edge correlations in spatial networks. Journal of Complex Networks cnv015. Glasser M. F. Sotiropoulos S. N. Wilson J. A. Coalson T. S. Fischl B. Andersson J. L. Xu J. Jbabdi S. Webster M. Polimeni J. R. et al. 2013. The minimal preprocessing pipelines for the human connectome project. Neuroimage 80 105–124. 33 | scientific_articles |
reconstructed and are hence the most consistent connections across subjects whereas long-range connections are more prone to error. Also this method forces a user to choose somewhat ad hoc the threshold for including a con- nection in the group-average matrix. Instead we use an alternative method for generating a group-average connectomes whose edge-length distribution matches that of the typical single-participant distribution (Miˇsi´ c et al. 2015). Briefly this method begins by first estimating the average number of connections of a given length in a typical participant’s connectome. Next all pairs of nodes sep- arated by a comparable distance are identified and from among this subset the most consistent connections are added to the group-average connectivity ma- trix. Repeating this process for all distances yields a representative connectome that matches almost exactly the typical edge length distribution but features only the most consistently expressed edges at each connection length. In this report we test the hypothesis that the human connectome emerges as a consequence of both topological and spatial constraints which we model as power-law functions. In doing so we assume that the material/metabolic cost of fiber tracts can be equated to Euclidean distance separating its endpoints rather than the actual integrated length of the curved tract. The argument for doing so is threefold. First estimates of fiber length can only be obtained for completed streamlines meaning that no estimates exist for connections that were absent in the observed tractography data. In order to fill in the missing fiber lengths one can resort to fiber interpolation (i.e. using the distance/fiber length relationship of existing connections to estimate the fiber length of missing connections) which necessarily introduces an additional source of uncertainty. Second the relationship of fiber length and Euclidean distance is rather strong across our datasets: the amount of variance in fiber length accounted for by 24 5.5. CHUV Group-average matrix with fiber length - See Figures S10-S11 | scientific_articles |
Nov. 22 2018 39 US 2018/0335696 Al -continued -continued | patents |
Table of Contents 19. ACCUMULATED OTHER COMPREHENSIVE LOSS: Other comprehensive income (loss) attributable to CBI includes the following components: Before Tax Amount Tax (Expense) Benefit Net of Tax Amount (in millions) For the Year Ended February 28 2017 Other comprehensive income attributable to CBI: Foreign currency translation adjustments: Net loss $ (78.3) $ (0.7) $ (79.0) Reclassification adjustments 111.5 — 111.5 Net gain recognized in other comprehensive income 33.2 (0.7) 32.5 Unrealized loss on cash flow hedges: Net derivative loss (34.7) 11.7 (23.0) Reclassification adjustments 45.2 (14.1 ) 31.1 Net gain recognized in other comprehensive income 10.5 (2.4) 8.1 Unrealized gain on AFS debt securities: Net AFS debt securities gain 0.4 0.1 0.5 Reclassification adjustments — — — Net gain recognized in other comprehensive income 0.4 0.1 0.5 Pension/postretirement adjustments: Net actuarial gain 0.3 (0.1) 0.2 Reclassification adjustments 11.5 (0.1 ) 11.4 Net gain recognized in other comprehensive income 11.8 (0.2) 11.6 Other comprehensive income attributable to CBI $ 55.9 $ (3.2 ) $ 52.7 For the Year Ended February 28 2018 Other comprehensive income (loss) attributable to CBI: Foreign currency translation adjustments: Net gain $ 147.3 $ (1.6) $ 145.7 Reclassification adjustments — — — Net gain recognized in other comprehensive income 147.3 (1.6) 145.7 Unrealized gain on cash flow hedges: Net derivative gain 76.7 (21.5) 55.2 Reclassification adjustments (2.9 ) 0.2 (2.7 ) Net gain recognized in other comprehensive income 73.8 (21.3) 52.5 Unrealized loss on AFS debt securities: Net AFS debt securities loss — (0.2) (0.2) Reclassification adjustments — — — Net loss recognized in other comprehensive income — (0.2) (0.2) Pension/postretirement adjustments: Net actuarial loss (1.7) 0.6 (1.1) Reclassification adjustments — — — Net loss recognized in other comprehensive income (1.7) 0.6 (1.1) Other comprehensive income attributable to CBI $ 219.4 $ (22.5 ) $ 196.9 98 | financial_reports |
The MySQL Keyring 6. Log in to the HashiCorp Vault server and verify its status. 7. Set up HashiCorp Vault authentication and storage. 8. Add an AppRole security policy. Prepare the environment variables required for logging in as root: vault login s.vTvXeo3tPEYehfcd9WH7oUKz For the token value in that command substitute the content of the root token obtained previously during Vault initialization. Verify the Vault server status: vault status The output should contain these lines (among others): The operations described in this step are needed only the first time the Vault instance is run. They need not be repeated afterward. Enable the AppRole authentication method and verify that it is in the authentication method list: vault auth enable approle vault auth list Enable the Vault KeyValue storage engine: vault secrets enable -version=1 kv Create and set up a role for use with the keyring_hashicorp plugin (enter the command on a single line): vault write auth/approle/role/mysql token_num_uses=0 token_ttl=20m token_max_ttl=30m secret_id_num_uses=0 The operations described in this step are needed only the first time the Vault instance is run. They need not be repeated afterward. Prepare a policy that to permit the previously created role to access appropriate secrets. Create a new file named mysql.hcl with the following content: path "kv/mysql/*" { capabilities = ["create" "read" "update" "delete" "list"] 1424 Note Note ... Initialized true Sealed false ... | manuals |
STRUCTURE AND CORPORATE GOVERNANCE and systems of internal control of Reed Elsevier Group plc and Elsevier Reed Finance BV. The boards of Reed Elsevier PLC and Reed Elsevier NV have each adopted a schedule of matters which are required to be brought to them for decision. In relation to Reed Elsevier Group plc and Elsevier Reed Finance BV the boards of Reed Elsevier PLC and Reed Elsevier NV approve the strategy and the annual budgets and receive regular reports on the operations including the treasury and risk management activities of the two companies. Major transactions proposed by the boards of Reed Elsevier Group plc or Elsevier Reed Finance BV require the approval of the boards of both Reed Elsevier PLC and Reed Elsevier NV. The Reed Elsevier PLC and Reed Elsevier NV Audit Committees meet on a regular basis to review the systems of internal control of Reed Elsevier Group plc and Elsevier Reed Finance BV. Reed Elsevier NV regarding the remuneration of the executive directors of these companies. The fees of non-executive directors are determined by each of the boards as a whole. A Directors’ Remuneration Report which has been approved by the boards of Reed Elsevier Group plc Reed Elsevier PLC and Reed Elsevier NV appears on pages 29 to 38. This report also serves as disclosure of the directors’ remuneration and interests in shares of the two parent companies Reed Elsevier PLC and Reed Elsevier NV. Reed Elsevier Group plc has established a Strategy Committee comprising a majority of independent non- executive directors. The Committee is chaired by Morris Tabaksblat the other members being Crispin Davis Mark Elliott – appointed in April 2003 and David Reid – appointed in April 2003. The Committee met once during the year and there was full attendance. The Committee’s terms of reference include reviewing the major features of the strategy proposed by the Chief Executive Officer and subsequently recommending the proposed strategy to the board. The Committee is also responsible for reviewing any acquisition or investment which would have major strategic or structural implications for Reed Elsevier Group plc. The board of Reed Elsevier Group plc is responsible for the system of internal control of the Reed Elsevier publishing and information businesses while the boards of Elsevier Reed Finance BV are responsible for the system of internal control in respect of the finance group activities. The boards of Reed Elsevier Group plc and Elsevier Reed Finance BV are also responsible for reviewing the effectiveness of their system of internal control. The objective of these systems is to manage rather than eliminate the risk of failure to achieve business objectives. Accordingly they can only provide reasonable but not absolute assurance against material misstatement or loss. The boards of Reed Elsevier Group plc and Elsevier Reed Finance BV have implemented an ongoing process for identifying evaluating and managing the significant risks faced by their respective businesses. This process has been in place throughout the year ended 31 December 2003 and up to the date of the approvals of the Annual Reports and Financial Statements. Reed Elsevier PLC and Reed Elsevier NV participate in regular dialogue with institutional shareholders and presentations on the Reed Elsevier combined businesses are made after the announcement of the interim and full year results. The boards of Reed Elsevier PLC and Reed Elsevier NV commission periodic reports on the attitudes and views of the companies’ institutional shareholders and the results are the subject of formal presentations to the respective boards. A trading update is provided at the respective Annual General Meetings of the two companies and near the end of the financial year. The Annual General Meetings provide an opportunity for the boards to communicate with individual shareholders. The Chairman the Chief Executive Officer the Chief Financial Officer the Chairmen of the board committees other directors and a representative of the external auditor are available to answer questions from shareholders. The interim and annual results announcements and presentations together with the trading updates and other important announcements concerning Reed Elsevier are published on the Reed Elsevier website (www.reedelsevier.com). Reed Elsevier Group plc has an established framework of procedures and internal controls which is set out in a group Policies and Procedures Manual and with which the management of each business is required to comply. Group businesses are required to maintain systems of internal control which are appropriate to the nature and scale of their activities and address all significant operational and financial risks that they face. The board of Reed Elsevier Group plc has adopted a schedule of matters that are required to be brought to it for decision. Each business group has identified and evaluated its major risks the controls in place to manage those risks and the level of residual risk accepted. Risk management and control procedures are embedded into the operations of the The boards of Reed Elsevier PLC and Reed Elsevier NV exercise independent supervisory roles over the activities REED ELSEVIER ANNUAL REPORTS & FINANCIAL STATEMENTS 2003 25 Strategy Committee Operating companies Reed Elsevier Group plc INTERNAL CONTROL Parent companies RELATIONS WITH SHAREHOLDERS | financial_reports |
6 holds also for the thallium compounds. The former esti- mations are congruent with Uemura’s surmise [20] that SC charge carriers in layered cuprates are concentrated within slabs of width δ = c$_{int}$ . Table I shows results obtained using the foregoing as- sumptions together with the physical parameters in- volved in the calculation. In most cases we find rather satisfactory agreement between predicted and measured values of T$_{c}$ . We also find very good agreement between theoretical and experimental gap-to- T$_{c}$ ratios 2Δ$_{0}$ /k$_{B}$T$_{c}$ . Average theoretical and experimental such ratios presented in Table I are (2Δ$_{0}$ /k$_{B}$T$_{c}$ ) th ≃ 4 . 45 and (2Δ$_{0}$ /k$_{B}$T$_{c}$ ) exp ≃ 4 . 59 respectively. Both are consis- tent with the ratio 2Δ (2) 0 /k$_{B}$T$_{c}$ ≃ 4 . 28 predicted by the l = 2 BCS theory in (16). We have not attempted es- timate uncertainties of our theoretical results since the accumulated data of the physical parameters involved in the calculation particularly Δ$_{0}$ and λ$_{ab}$ show a wide scatter. Figure 1 is adapted from Ref.[37] and compares theoret- ical predictions (29) with experimental data as well as with data pertaining to higher doping regimes. We see that (29) gives an excellent fit to the experimental data. The same functional dependence has been observed in single YBCO crystals near the optimally-doped regime [41]. More recently Broun et al. [9] found that their samples of high-purity single-crystal YBCO followed the rule T$_{c}$ ∝ λ − 1 ab ∝ n 1 / 2 s ∝ ( p − p$_{c}$ ) 1 / 2 where the doping p is the number of holes per copper atom in the CuO$_{2}$ planes and p$_{c}$ the minimal doping for superconductivity onset. The measured value of the penetration length in YBCO crystals is an order of magnitude bigger than in thin films [9 41] so that the specific values of T$_{c}$ s de- rived from (28) are not in such good agreement as in the YBCO films. However one should expect variations of parameters such as the energy gap associated to crys- tals and film systems. It has been pointed out [37] that YBCO films seem to behave more like other cuprates such as BiSrCaCuO or LaSrCuO than do YBaCuO crys- tals . Furthermore a different approach [42] based on measurements of the lower critical magnetic field H$_{c}$$_{1}$ ( T ) for highly underdoped YBCO indicates that experimen- tal data may be consistently described only by assuming T$_{c}$ ∝ n 0 . 61 s in close agreement with studies mentioned above. We have shown that layered-cuprate HTSC can be de- scribed by means of an l -wave BCS theory for a quasi-2D BEC of Cooper pairs. The theory involves a linear as opposed to quadratic dispersion relation in their total or CM momenta. The theory yields a simple formula for the critical transition temperature T$_{c}$ with a functional relation T$_{c}$ ∝ 1 /λ$_{ab}$ ∝ n 1 / 2 s which applies to a variety of cuprate SCs over a wide range of dopings. Although this behavior apparently disagrees with the phenomenological Uemura relation T$_{c}$ ∝ 1 /λ 2 ab [20] different experimen- tal studies [9 37 41] show consistency with the inverse linear dependence of T$_{c}$ . Additional consistency is also seen with the reported dependence T$_{c}$ ∝ n 0 . 61 s arising from measurements of the lower critical magnetic field [42]. When averaged over a cylindrical Fermi surface the physical quantities involved in the theory show small dependence on the angular momentum state l . However the gap-to- T$_{c}$ ratio 2Δ$_{0}$ /k$_{B}$T$_{c}$ is closer to that predicted by the extended BCS theory for l = 2 than for l = 0. It is shown elsewhere [46] that all relevant 2D expressions derived here arise in the limit k$_{B}$T δ/ ℏ c$_{1}$ → 0 of a more general 3D BCS-BEC theory for layered materials. ∗ Permanent address. Theoretical values of T$_{c}$ for superconducting cuprates with different compositions have been also calculated using (28). Here we report on these seven layered-cuprate superconducting com- pounds: (La$_{.}$$_{925}$Sr$_{.}$$_{075}$)$_{2}$CuO$_{4}$; YBa$_{2}$Cu$_{3}$O$_{6}$$_{.}$$_{60}$; YBa$_{2}$Cu$_{3}$O$_{6}$$_{.}$$_{95}$; Tl$_{2}$Ba$_{2}$Ca$_{2}$Cu$_{2}$O$_{8}$; Tl$_{2}$Ba$_{2}$Ca$_{2}$Cu$_{3}$O$_{10}$; Bi$_{2}$Sr$_{2}$Ca$_{2}$Cu$_{3}$O$_{10}$; and Bi$_{2}$Sr$_{2}$CaCu$_{2}$O$_{8}$. Characteristic parameters for these materials were taken from tables compiled in Ref.[38] (see also [43–45]). Concerning the layer width δ no direct experimental data are available. We have employed results derived from energy band-structure calculations for cuprates. Contour plots [39 40] of the charge distribution for La$_{2}$CuO$_{4}$ YBa$_{2}$Cu$_{3}$O$_{7}$ and BiCa$_{2}$SrCu$_{2}$O$_{8}$ suggest that charge carriers in each of these systems are concentrated within slabs of average width δ ≃ 2 . 61 ˚ A 2 . 15 ˚ A and 2 . 28 ˚ A respectively about their CuO$_{2}$ planes. As c$_{int}$ denotes the average separation between adjacent CuO$_{2}$ planes it follows from crystallographic data [38] that the yttrium and bismuth compounds give δ ≃ 0 . 64 c$_{int}$ and 0 . 68 c$_{int}$ respectively. Taking into account that BiSr$_{2}$Ca$_{n}$Cu$_{n}$$_{+1}$O$_{6+}$$_{n}$ compounds possess the same layering scheme as their TlBa$_{2}$Ca$_{n}$Cu$_{n}$$_{+1}$O$_{6+}$$_{n}$ counter- parts [38] we assumed that the condition δ ≃ 0 . 68 c$_{int}$ Acknowledgments We thank M. Fortes S. Fu- jita L.A. P´erez and M.A. Sol´ıs for fruitful discus- sions. MdeLl thanks UNAM-DGAPA-PAPIIT (Mexico) IN106908 as well as CONACyT (Mexico) for partial sup- port. He thanks D.M. Eagles and R.A. Klemm for e- correspondence and is grateful to W.C. Stwalley for dis- cussions and the University of Connecticut for its hospi- tality while on sabbatical leave. VI. DISCUSSION AND CONCLUSIONS meV [38] and δ = 2 . 15 ˚ A [39 40] to get the relation T$_{c}$ = 16 . 79[( µm ) − $^{1}$K ] λ$_{ab}$ . (29) | scientific_articles |
Is the centrality dependence of the elliptic flow v 2 and of the average < p$_{T}$ > more than a Core-Corona Effect? J. Aichelin and K. Werner SUBATECH Laboratoire de Physique Subatomique et des Technologies Associ´ees Universit´e de Nantes - IN2P3/CNRS - Ecole des Mines de Nantes 4 rue Alfred Kastler F-44072 Nantes Cedex 03 France (Dated: August 17 2018) Recently we have shown that the centrality dependence of the multiplicity of different hadron species observed in RHIC and SPS experiments can be well understood in a simple model dubbed core-corona model. There it is assumed that those incoming nucleons which scatter only once produce hadrons as in pp collisions whereas those which scatter more often form an equilibrated source which decays according to phase space. In this article we show that also kinematical variables like v 2 /ϵ part ( N part ) as well as v i $_{2}$/ϵ part ( N part ) and < p i $_{T}$( N part ) > of identified particles are well described in this model. The correlation of < p i T > between peripheral heavy ion collisions and pp collisions for different hadrons reproduced in this model questions whether hydrodynamical calculations are the proper tool to describe non-central heavy ion collision. The model explains as well the centrality dependence of v 2 /ϵ part of charged particles considered up to now as an observable which allows to determine the viscosity of the quark gluon plasma. The observed dependence of v i $_{2}$/ϵ part ( N part ) on the particle species is a simple consequence of the different ratios of core to corona particles. PACS numbers: Simulations of heavy ion collisions with advanced event generators like EPOS [ ? ] which reproduce a multitude of experimental observables have revealed that nucleons at the surface of the reaction zone (called corona parti- cles) have only few collisions and do not come to statis- tical equilibrium with the more central (core) particles which form an equilibrated system. To study the conse- quences of this observation we have developed a simple model [2] by defining corona particles as those nucleons which have only one initial collision whereas the others are considered as core particles. f$_{core}$ is the fraction of core nucleons which depends on the centrality the sys- tem size and (weakly) on the beam energy. In this sim- ple model we could show that independent of the system size the centrality dependence of the multiplicity of all hadrons from SPS to RHIC energies can quantitatively be described by: where f$_{core}$ shown in Fig. 1 has been calculated in a Glauber model and i refers to the hadron species. For our calculation we fix M i core by applying eq. 1 to the most central AuAu or PbPb data point. M i corona is given as half of the multiplicity measured in pp collisions. Once these parameters are fixed the centrality dependence of M i is determined by eq. 1. Especially the centrality de- pendence of the lighter CuCu system follows then with- out any further input. Certainly this is a very simple model with no free parameter (besides the Glauber cal- culation of f$_{core}$ ) but the present experimental error bars of the quantities which we analyze give not sufficient in- formation to refine the model. One may ask whether the core - corona model can also describe the centrality dependence of other observables like < p$_{T}$ > ( N$_{part}$ ) or v$_{2}$/ϵ$_{part}$ ( N$_{part}$ ) of charged parti- cles or identified hadrons. Especially the centrality de- pendence of v$_{2}$/ϵ$_{part}$ ( N$_{part}$ ) has recently created a lot of theoretical activities. Initially the azimuthal distribution FIG. 1: f core the fraction of core nucleons as a function of the participant number N part for AuAu and CuCu collisions at √$_{s}$ = 200 GeV . M $^{i}$( N$_{part}$ ) (1) = N$_{part}$ [ $^{f$_{core}$}$· M i core + (1 − f$_{core}$ $^{)}$· M i $_{corona}$] 0 50 100 150 200 250 300 350 400 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 AuAu CuCu arXiv:1001.1545v2 [nucl-th] 11 Jul 2010 | scientific_articles |
PART II NOTE 18 Commitments Guarantees and Contingent Liabilities Like hundreds of other industrial companies we have been named as one of many defendants in asbestos-related personal injury litigation. Most of these cases allege personal injury or death resulting from exposure to asbestos in premises of FMC or to asbestos-containing components installed in machinery or equipment manufactured or sold by discontinued operations. We intend to continue managing these cases in accordance with our historical experience. We have established a reserve for this litigation within our discontinued operations and believe that any exposure of a loss in excess of the established reserve cannot be reasonably estimated. In February 2005 putative direct and indirect purchaser class action complaints were fi led against six U.S. hydrogen peroxide producers (and certain of their foreign affi liates) in various federal courts alleging violations of antitrust laws. Related cases were also filed in various state courts. In January 2009 FMC reached an agreement to settle with the direct purchaser class for $10 million with a pro rata credit for opt outs. The $10 million figure was included as a component of “Restructuring and other charges (income)” in our consolidated statements of income for the year ended December 31 2008. Ten companies (predominantly paper producers) opted out of this class settlement. FMC settled with two of the ten companies for an amount within the opt out credit described above. The remaining eight opt outs filed suit against FMC and in some cases Foret. These cases were assigned to the same judge as the class action. FMC’s motion to dismiss the opt out claims to the extent they were based on foreign purchases was granted on April 1 2010. FMC has settled the remaining claims of these eight opt outs for an aggregate of $1.7 million which is net of a $0.3 million opt out credit. Another individual opt out case was dismissed following the bankrupt opt out’s decision to participate in the class settlement. FMC settled the indirect purchaser class claims for $0.25 million. The settlement has been finally approved by the Court and all remaining state court cases have been dismissed with prejudice. We recorded the $2.0 million as a component of “Restructuring and other charges (income)” in our consolidated statements of income for the year ended December 31 2010. As a result all U.S. litigation against FMC regarding alleged price fi xing in the hydrogen peroxide industry is now concluded. We still face putative class actions against FMC and five other major hydrogen peroxide producers in provincial courts in Ontario Quebec and British Columbia under the laws of Canada. Four of the defendants have settled these claims for a total of approximately $20.5 million. On September 28 2009 the Ontario Superior Court of Justice certified a class of direct and indirect purchasers of hydrogen peroxide. FMC moved for leave to appeal the class certifi cation decision which was denied in June 2010. Th e Company intends to defend these cases. Since the proceedings are in the preliminary stages with respect to the merits we believe an exposure of loss cannot be reasonably estimated. We have certain other contingent liabilities arising from litigation claims performance guarantees and other commitments incident to the ordinary course of business. Based on information currently available and established reserves the ultimate resolution of our known contingencies including the matters described in this Note 18 is not expected to have a material adverse effect on our consolidated fi nancial position or liquidity. However there can be no assurance that the outcome of these contingencies will be favorable and adverse results in certain of these contingencies could have a material adverse eff ect on our consolidated financial position results of operations or liquidity. In late June 2004 we were served in a lawsuit captioned “Lewis et al v. FMC Corporation” which was filed in United States District Court for the Western District of New York. The suit was brought by thirteen residents of Middleport New York who allege that we violated certain state and federal environmental laws and seeks injunctive relief and monetary damages for personal injuries and property damage in connection with such alleged violations. A motion for summary was filed by the Company in 2007 and is expected to be decided in 2011. We believe this suit is without merit and therefore have not established a reserve for it. 69 FMC CORPORATION 2010 Form 10K | financial_reports |
TOURNAMENTS SECTION XII - WTA TOURNAMENT MEMBERSHIPS approval acceptance or other action with respect to the proposed Lease (ii) the identity of each party to the Lease and relevant background information for each such party (iii) the term of the Lease and (iv) any other information the CEO deems necessary for the Board of Director’s consideration of the proposed Lease consistent with the confidentiality provisions of Section XII.I.3.a above. The Board of Directors shall have the right in its sole discretion to approve or disapprove a Lease or delegate to the CEO the right to approve or disapprove a Lease. Any such approval or acceptance by the Board of Directors or the CEO may be given withheld or conditioned in the sole discretion of the Board of Directors or the CEO as applicable. Conditions to approval may include without limitation (A) the Lease containing mandatory lease terms (in addition to those set forth in Appendix C) as prescribed by the Board of Directors or the CEO from time to time and (B) any other condition to ensure that the Lease is in compliance with the Rules and/or in the best interest of the WTA. c. For the avoidance of doubt approval of a Lease by the CEO or the Board of Directors shall not extend to any Subsequent Transaction whether or not contemplated by the terms of a Lease or otherwise. For purposes of this Section “Subsequent Transaction” means (i) any amendment or modification to or extension or renewal of any Lease or any agreement related thereto (ii) the exercise by any person or entity of any rights of first negotiation or refusal relocation rights other back-end rights or any purchase or sale rights and (iii) any sale transfer assignment pledge or other disposition or encumbrance by any person or entity of any Lease or any “ownership interest.” Any such Subsequent Transaction shall be subject to separate and independent approval by the WTA in accordance with the Rules at the time that any such terms are sought to be triggered and/or exercised by any party. d. All Leases shall be required to include as an attachment or rider thereto the language set forth in Appendix C (or language in form and substance substantially similar thereto modified only as necessary to conform to the defined terms in the applicable agreement). e. The WTA may in its discretion waive any or all of the requirements of this Section 3. f. Any violation of this Section 3 shall be a violation of a Condition of Membership (as defined in the WTA By-Laws) and shall among other things be subject to the imposition of sanctions under Section 2.6 of the WTA By-Laws. In such circumstance WTA Management shall notify the member of the violation and sanction and provide the member with the opportunity to submit additional information. In the event that the WTA learns or becomes aware of facts or circumstances constituting a 221 | manuals |
5 uation where the spectral function of the embedded dot has a significant variation on the energy scale of Γ a which affects the resonance line-shape for large E . It should also be noted that parameters a and b have “unphysical” values a > 1 and b < 0 for small T . If the curve fitting is performed in a nar- rower energy interval [ − Γ a : +Γ a ] the asymptotic small- E form of the resonance can be well captured however the ex- tracted Fano parameters are factitious and therefore of little use. This demonstrates that in the presence of strong com- petition between the Fano interference and Kondo effect the curve fitting using the Fano line-shape is not recommended since the results depend very strongly on the energy window where fitting is performed and it is thus not advisable to make any inference based on them. tance curves for U d = 0 and U d /D = 1 at t/D = 0 . 0001 where Γ a /T 0 K = 1 . 7 × 10 − 3 since the Kondo temperature (Wilson’s definition) is T 0 K = 9 . 7 × 10 − $^{5}$D . In this regime the Kondo effect on the embedded dot in no way affects the Fano interference process in the relevant range of energies and temperatures (i.e. several times Γ a ). Only for very large ϵ a and very high temperature (of the order of T 0 $_{K}$) will the differ- ences become apparent however this is outside the parameter regime of interest here. When Γ a is equal to a considerable fraction of T 0 $_{K}$ we start to see small quantitative departure from the Fano line shape already for ϵ a and T of the order of Γ a see Fig. 4 middle panel. This is clearly a consequence of the competition be- tween correlation and interference effects combined with fur- ther thermal effects. As expected the discrepancy grows with increasing ϵ a and T . Finally for Γ a ≫ T 0 $_{K}$ the embedded dot is strongly per- turbed by the coupling to the side-dot and the differences become drastic: at finite T the line-shape differs qualita- tively from the Fano form and in particular we observe the e m ergence of non-uniform E -dependence with broad humps ar o und E ∼ Γ a . -4 -2 0 2 4 E= $_{a}$/ a 0 0.2 0.4 0.6 0.8 1 G(E T) 0 0.5 1.0 1.5 0 0.5 1 T/ a 0 0.25 0.5 0.75 1 $_{/}$Γ a -0.2 0 0.2 0.4 0.6 0.8 1 1.2 a b $_{a}$=t$^{2}$/ d T/ a a b / a t/D=0.006 $_{d}$/D=0.06 $_{a}$/D=1.67 10 -5 a) b) U$_{d}$/D=1 $_{a}$/T$_{K}$$^{0}$=6.1 0 0.2 0.4 0.6 0.8 1 G(E T) 0 0.5 1 1.5 0 0.2 0.4 0.6 0.8 G(E T) U=0 U/D=1 -4 -2 0 2 4 E= $_{a}$/ a 0 0.2 0.4 0.6 0.8 G(E T) T/ a t/D=0.0001 t/D=0.001 t/D=0.01 $_{a}$/T$_{K}$$^{0}$=0.0017 $_{a}$/T$_{K}$$^{0}$=0.17 $_{a}$/T$_{K}$$^{0}$=17 Figure 5: (Color online) Interacting model with U d = 0 and U a = 0 . Symmetric case ϵ d = 0 . a) Conductance curves for a range of temperatures. b) Fano parameters as a function of the temperature. Curve fitting is performed in the energy window which corresp onds to the horizontal axis in the upper subfigure. Since there are two different energy scales in the problem ( T 0 K and Γ a ) the temperature-dependence of the conductance is expected to be non-monotonic as shown in Fig. 6 where we plot the conductance at the bottom of the Fano anti-resonance (i.e. for ϵ a = 0 ). Such dependence is a consequence of the competition between the Kondo and Fano effects. The Kondo effect tends to increase the conductance through the formation of many-particle resonance at the Fermi level which opens a new conduction channel through the system. On the other hand the Fano effect suppresses the conductance through quantum interference. For T 0 K ≫ Γ a the conductance first increases at the higher temperature scale of T 0 K (the tempera- ture dependence being given by the universal Kondo conduc- tance curve$^{71}$) then it decreases at the lower temperature scale set by Γ a : see results for t/D = 0 . 0001 and t/D = 0 . 001 in Fig. 6. Note that the unitary limit of full conductance quantum It is instructive to perform curve fitting on the results wher e the Fano resonance is already strongly perturbed as shown in Fig. 5. The fits (shown using dashed lines) performed in the energy interval [ − 4Γ a : +4Γ a ] are clearly inade- quate. Extracted Fano parameters indicate that the resonance width is significantly reduced below Γ a and its width even decreases with increasing temperature which reflects the s it- Figure 4: (Color online) Resonance curves for non-interacting (full lines) and interacting models (dashed lines) for a range of scaled tem- peratures T/ Γ a and for different Γ a /T 0 K ratios. | scientific_articles |
With the approval of the Governor-General the provincial board may authorize any municipality of the province to exceed the foregoing percentages under such limitations as may be prescribed by resolution of said board. [1903-1; 1979-1 ( nn ).] SECTION 2246 . Disbursement of Municipal Funds. — Disbursements of municipal funds shall be made by the municipal treasurer upon properly executed vouchers pursuant to the budget and with the approval of the president. Vouchers covering disbursements from the school fund or for school purposes shall also be approved by the division superintendent of schools or his authorized representative. cDTACE The municipal treasurer shall keep in his office open at all times to the inspection of members of the municipal council a statement of the appropriations expenditures and balances in all municipal accounts. SECTION 2247 . Restriction Upon Disbursements . — Disbursements pursuant to the budget may be made from any municipal funds in the hands of the treasurer but the total disbursements from any municipal fund shall in no case be in excess of the actual collect ions accruing to such fund except upon written authority of the provincial treasurer and in no case shall an overdraft in excess of twenty-five per centum of the uncollected revenues and receipts accruing to any fund as shown by the approved budget be so authorized. SECTION 2248 . Application of Article. — The remedies provided in this article may be used so far as their nature permits for the collection of any delinquent municipal revenue except such as is mentioned in section two thousand two hundred and fifty-four hereof. caADSE SECTION 2249 . Civil Remedies. — The civil remedies available to enforce payment of delinquent municipal revenue shall be ( a ) by distraint of personal property and ( b ) by legal action either of which remedies or both simultaneously may be pursued in the di scretion of the proper authority. SECTION 2250 . Distraint of Personal Property. — The remedy by distraint shall proceed as follows: Upon the failure of the person owing any municipal tax or revenue to pay the same at the time required the municipal treasurer may seize and distrain any pe rsonal property belonging to such person or ARTICLE XVII Civil Remedies for Collection of Municipal Revenue 660 Copyright 2012 CD Technologies Asia Inc. and Accesslaw Inc. Philippine Law Encyclopedia 2011 | laws_and_regulations |
Appendix B Description and Overview of the System Safety Program Plan | laws_and_regulations |
mysqldump 497 mysqlpump 524 mysql_upgrade 411 netmask notation in account names 1215 network namespaces 994 network ports and NDB Cluster 4605 network-namespace option mysql 427 network-timeout option mysqldump 497 net_buffer_length system variable 843 net_read_timeout system variable 844 net_retry_count system variable 844 net_write_timeout system variable 844 new features 9 atomic DDL 9 backup lock 28 C API 29 cast functions 29 character sets 21 clone plugin 30 common table expressions 27 configuration 29 connection management 28 data dictionary 9 data types 24 EXPLAIN ANALYZE 32 hash join 31 InnoDB 12 innodb_deadlock_detect 12 internal temporary tables 28 JSON 21 JSON schema CHECK constraints 33 JSON schema validation 29 lateral derived tables 28 logging 28 multi-valued indexes 30 ON DUPLICATE KEY UPDATE 33 optimizer 24 plugins 29 query cast injection 32 redo log archiving 30 regular expressions 28 replication 28 resource management 11 security 9 table aliases and DELETE 28 table encryption 11 TABLE statement 34 time zone support 33 time_zone 30 upgrading 9 5490 | manuals |
18 中华人民共和国海洋环境保护法 第九十条 造成海洋环境污染损害的责任者,应当排除危害,并赔偿损失; 完全由于第三者的故意或者过失,造成海洋环境污染损害的,由第三者排除危害, 并承担赔偿责任。 对破坏海洋生态、海洋水产资源、海洋保护区,给国家造成重大损失的, 由依照本法规定行使海洋环境监督管理权的部门代表国家对责任者提出损害赔偿要 求。 第九十一条 对违反本法规定,造成海洋环境污染事故的单位,由依照本 法规定行使海洋环境监督管理权的部门根据所造成的危害和损失处以罚款;负有直 接责任的主管人员和其他直接责任人员属于国家工作人员的,依法给予行政处分。 前款规定的罚款数额按照直接损失的百分之三十计算,但最高不得超过三 十万元。 对造成重大海洋环境污染事故,致使公私财产遭受重大损失或者人身伤亡 严重后果的,依法追究刑事责任。 第九十二条 完全属于下列情形之一,经过及时采取合理措施,仍然不能 避免对海洋环境造成污染损害的,造成污染损害的有关责任者免予承担责任: (一)战争; (二)不可抗拒的自然灾害; (三)负责灯塔或者其他助航设备的主管部门,在执行职责时的疏忽,或 者其他过失行为。 第九十三条 对违反本法第十一条 、第十二条 有关缴纳排污费、倾倒费 和限期治理规定的行政处罚,由国务院规定。 第九十四条 海洋环境监督管理人员滥用职权、玩忽职守、徇私舞弊,造 成海洋环境污染损害的,依法给予行政处分;构成犯罪的,依法追究刑事责任。 第九十五条 本法中下列用语的含义是: 第十章 附则 Source: http://www.npc.gov.cn/wxzl/gongbao/2014-03/21/content_1867698.htm Date Accessed: 05-Mar-2015 | laws_and_regulations |
Contract number: EEAS-618-DELBRBB-SER-FWC-2019 Template of June 2018 Updated November 2018 I. SPECIAL CONDITIONS I.1. ORDER OF PRIORITY OF PROVISIONS I.2. SUBJECT MATTER I.3. ENTRY INTO FORCE AND DURATION OF THE FWC I.3.5 Renewal of the FWC If there is any conflict between different provisions in this FWC the following rules must be applied: Any reference to specific contracts applies also to order forms. The subject matter of the FWC is cleaning services for the Delegation of the European Union to Barbados the Eastern Caribbean States the OECS and CARICOM/CARIFORUM. The FWC is renewed automatically three (3) times for twelve (12) months each unless one of the parties receives formal notification to the contrary at least three (3) months before the end of the ongoing duration. Renewal does not change or postpone any existing obligations. 5 (a) The provisions set out in the special conditions take precedence over those in the other parts of the FWC. (b) The provisions set out in the general conditions take precedence over those in the order form and specific contract (Annex III) (c) The provisions set out in the order form and specific contract (Annex III) take precedence over those in the other annexes. (d) The provisions set out in the tender specifications (Annex I) take precedence over those in the tender (Annex II). (e) The provisions set out in the FWC take precedence over those in the specific contracts. I.3.1 The FWC enters into force on the date on which the last party signs it. I.3.2 The implementation of the FWC cannot start before its entry into force. I.3.3 The FWC is concluded for a period of twelve 4 years (12) months with effect from the date of its entry into force. I.3.4 The parties must sign any specific contract before the FWC expires. The FWC continues to apply to such specific contracts after its expiry. The services relating to such specific contracts must be performed no later than six (6) months after the expiry of the FWC. | government_tenders |
ndbinfo table 4571 phantom 6175 phantom rows 3098 phone book collation German 1978 1978 PHP 6176 PHP API 6176 physical 6176 physical backup 6176 PI() 2145 pid-file option mysql.server 390 mysqld_safe 386 pid_file system variable 858 Ping thread command 1846 pipe option 357 mysql 428 469 mysqladmin 458 mysqldump 483 mysqlimport 508 mysqlshow 537 mysqlslap 549 mysql_upgrade 411 PIPES_AS_CONCAT SQL mode 976 PITR 6176 PKG_CONFIG_PATH environment variable 632 plan stability 6176 platforms supported 96 pluggable authentication PAM 1317 restrictions 1262 Windows 1328 plugin audit_log 1465 plugin activation options FORCE 1077 FORCE_PLUS_PERMANENT 1077 OFF 1077 ON 1077 plugin API 1072 plugin installing audit_log 1466 Clone 1111 CONNECTION_CONTROL 1378 CONNECTION_CONTROL_FAILED_LOGIN_ATTEMPTS 1378 Data Masking 1576 ddl_rewriter 1096 keyring_aws 1402 keyring_encrypted_file 1402 keyring_file 1402 keyring_hashicorp 1402 keyring_oci 1402 keyring_okv 1402 5509 | manuals |
PLAYERS SECTION III - TOURNAMENT ENTRY TOURNAMENT ACCEPTANCE AND WILD CARDS 5. Filling Vacant Wild Card Spots a. Main Draw Singles b. Qualifying Singles If a Main Draw Wild Card withdraws from the Tournament after the Wild Card nomination deadline the Tournament Director can replace her with either a previously named or a new Wild Card up until the draw is made. The replacement singles Wild Card cannot be a player who is in the Qualifying Draw after Qualifying begins. If the Tournament does not name another Wild Card a Lucky Loser will fill the open spot. Until the start of Qualifying the Tournament Director will be allowed to fill a vacated Qualifying Wild Card spot with an alternate Wild Card nominated prior to the Qualifying Wild Card nominations deadline in the following instances: If a Main Draw Wild Card team withdraws from the Tournament after the Wild Card nomination deadline the Tournament Director can replace the team with either a previously named or new Wild Card team up until the draw is made. i. If at any time prior to the scheduled start of Qualifying a Wild Card or Wild Card team is accepted into the Qualifying or Main Draw based upon her or their WTA Ranking or Special Ranking or as a Special Exempt; or ii. If a Wild Card has withdrawn from the Tournament prior to the scheduled start of Qualifying. c. Doubles a. Sign in with the Supervisor or a WTA Operations staff member by the Qualifying Sign-In Deadline; 6. Additional Tournament Qualifying Wild Cards At Tournaments where there are no on-site Alternates openings in the qualifying draw may be filled by additional Tournament Wild Cards. Players waiting to get into the draw as additional Tournament Wild Cards must: 41 | manuals |
Glide ratio. The ratio between distance traveled and altitude lost during non-powered flight. Fuel control unit. The fuel-metering device used on a turbine engine that meters the proper quantity of fuel to be fed into the burners of the engine. It integrates the parameters of inlet air temperature compressor speed compressor discharge pressure and exhaust gas temperature with the position of the cockpit power control lever. Fuel efficiency. Defined as the amount of fuel used to produce a specific thrust or horsepower divided by the total potential power contained in the same amount of fuel. Fuel heaters. A radiator-like device which has fuel passing through the core. A heat exchange occurs to keep the fuel temperature above the freezing point of water so that entrained water does not form ice crystals which could block fuel flow. Glidepath. The path of an aircraft relative to the ground while approaching a landing. Global position system (GPS). A satellite-based radio positioning navigation and time-transfer system. Go-around. Terminating a landing approach. Governing range. The range of pitch a propeller governor can control during flight. Governor. A control which limits the maximum rotational speed of a device. Fuel injection. A fuel metering system used on some aircraft reciprocating engines in which a constant flow of fuel is fed to injection nozzles in the heads of all cylinders just outside of the intake valve. It differs from sequential fuel injection in which a timed charge of high-pressure fuel is sprayed directly into the combustion chamber of the cylinder. Ground adjustable trim tab. A metal trim tab on a control surface that is not adjustable in flight. Bent in one direction or another while on the ground to apply trim forces to the control surface. Gross weight. The total weight of a fully loaded aircraft including the fuel oil crew passengers and cargo. Ground effect. A condition of improved performance encountered when an airplane is operating very close to the ground. When an airplane’s wing is under the influence of ground effect there is a reduction in upwash downwash and wingtip vortices. As a result of the reduced wingtip vortices induced drag is reduced. Fuel load. The expendable part of the load of the airplane. It includes only usable fuel not fuel required to fill the lines or that which remains trapped in the tank sumps. Fuel tank sump. A sampling port in the lowest part of the fuel tank that the pilot can utilize to check for contaminants in the fuel. Fuselage. The section of the airplane that consists of the cabin and/or cockpit containing seats for the occupants and the controls for the airplane. Ground idle. Gas turbine engine speed usually 60-70 percent of the maximum rpm range used as a minimum thrust setting for ground operations. Ground loop. A sharp uncontrolled change of direction of an airplane on the ground. Gas generator. The basic power producing portion of a gas turbine engine and excluding such sections as the inlet duct the fan section free power turbines and tailpipe. Each manufacturer designates what is included as the gas generator but generally consists of the compressor diffuser combustor and turbine. Ground power unit (GPU). A type of small gas turbine whose purpose is to provide electrical power and/or air pressure for starting aircraft engines. Aground unit is connected to the aircraft when needed. Similar to an aircraft- installed auxiliary power unit. Groundspeed (GS). The actual speed of the airplane over the ground. It is true airspeed adjusted for wind. Groundspeed decreases with a headwind and increases with a tailwind. Gas turbine engine. A form of heat engine in which burning fuel adds energy to compressed air and accelerates the air through the remainder of the engine. Some of the energy is extracted to turn the air compressor and the remainder accelerates the air to produce thrust. Some of this energy can be converted into torque to drive a propeller or a system of rotors for a helicopter. Ground track. The aircraft’s path over the ground when in flight. G G-8 | laws_and_regulations |
59 C.2. Terms and conditions for accessing or otherwise using Python Python Setup and Usage Release 3.9.5 (continued from previous page) 8. By clicking on the "ACCEPT" button where indicated or by copying installing or otherwise using Python 1.6.1 Licensee agrees to be bound by the terms and conditions of this License Agreement. C.2.4 CWI LICENSE AGREEMENT FOR PYTHON 0.9.0 THROUGH 1.2 Copyright © 1991 - 1995 Stichting Mathematisch Centrum Amsterdam The Netherlands. All rights reserved. Permission to use copy modify and distribute this software and its documentation for any purpose and without fee is hereby granted provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation and that the name of Stichting Mathematisch Centrum or CWI not be used in advertising or publicity pertaining to distribution of the software without specific written prior permission. STICHTING MATHEMATISCH CENTRUM DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS IN NO EVENT SHALL STICHTING MATHEMATISCH CENTRUM BE LIABLE FOR ANY SPECIAL INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE DATA OR PROFITS WHETHER IN AN ACTION OF CONTRACT NEGLIGENCE OR OTHER TORTIOUS ACTION ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. Permission to use copy modify and/or distribute this software for any purpose with or without fee is hereby granted. THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY SPECIAL DIRECT INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE DATA OR PROFITS WHETHER IN AN ACTION OF CONTRACT NEGLIGENCE OR OTHER TORTIOUS ACTION ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. C.2.5 ZERO-CLAUSE BSD LICENSE FOR CODE IN THE PYTHON 3.9.5 DOCU- MENTATION | manuals |
Flanged Plain Single bevel Double bevel Thin stock Thick stock A B Figure 5-43. Edge joints. Figure 5-41. Types of butt joints. Figure 5-42. Types of tee joints showing filler penetration. Figure 5-44. Corner joints. Plain Single bevel Double bevel Closed type Open type A Braced C B 5-31 used for metals from 1 ⁄ 16 -inch to 1 ⁄ 8 -inch in thickness. A filler rod is used when making this joint to obtain a strong weld. The flanged butt joint can be used in welding thin sheets 1 ⁄ 16 - inch or less. The edges are prepared for welding by turning up a flange equal to the thickness of the metal. This type of joint is usually made without the use of a filler rod. If the metal is thicker than 1 ⁄ 8 -inch it may be necessary to bevel the edges so that the heat from the torch can completely penetrate the metal. These bevels may be either single or double-bevel type or single or double-V type. A filler rod is used to add strength and reinforcement to the weld. [Figure 5-41] Repair of cracks by welding may be considered just another type of butt joint. The crack should be stop drilled at either end and then welded like a plain butt joint using filler rod. In most cases the welding of the crack does not constitute a complete repair and some form of reinforcement is still required as described in following sections. A tee joint is formed when the edge or end of one piece is welded to the surface of another. [Figure 5-42] These joints are quite common in aircraft construction particularly in tubular structures. The plain tee joint is suitable for most thicknesses of metal used in aircraft but heavier thicknesses require the vertical member to be either single or double- beveled to permit the heat to penetrate deeply enough. The A corner joint is made when two pieces of metal are brought together so that their edges form a corner of a box or enclosure. [Figure 5-44] The corner joint shown in Figure 5-44A requires no filler rod since the edges fuse to make the weld. It is used where the load stress is not important. The type shown in Figure 5-44B is used on heavier An edge joint is used when two pieces of sheet metal must be fastened together and load stresses are not important. Edge joints are usually made by bending the edges of one or both parts upward placing the two ends parallel to each other and welding along the outside of the seam formed by the two joined edges. The joint shown in Figure 5-43A requires no filler rod since the edges can be melted down to fill the seam. The joint shown in Figure 5-43B being thicker material must be beveled for heat penetration; filler rod is added for reinforcement. dark areas in Figure 5-42 show the depth of heat penetration and fusion required. It is a good practice to leave a gap between the parts about equal to the metal thickness to aid full penetration of the weld. This is common when welding from only one side with tubing clusters. Tight fitment of the parts prior to welding does not provide for a proper weldment unless full penetration is secured and this is much more difficult with a gapless fitment. Edge Joints Tee Joints Corner Joints | laws_and_regulations |
Telephone and Data Systems Inc. 30 North LaSalle Street ■ Suite 4000 Chicago Illinois 60602 312/630-1900 ■ 312/630-1908 (fax) www.teldta.com | financial_reports |
www.firstmerchants.com | financial_reports |
mysqladmin — A MySQL Server Administration Program •For multiple-table deletes and updates an error is produced with safe updates enabled only if any target table uses a table scan. Disabling mysql Auto-Reconnect If the mysql client loses its connection to the server while sending a statement it immediately and automatically tries to reconnect once to the server and send the statement again. However even if mysql succeeds in reconnecting your first connection has ended and all your previous session objects and settings are lost: temporary tables the autocommit mode and user-defined and session variables. Also any current transaction rolls back. This behavior may be dangerous for you as in the following example where the server was shut down and restarted between the first and second statements without you knowing it: The @a user variable has been lost with the connection and after the reconnection it is undefined. If it is important to have mysql terminate with an error if the connection has been lost you can start the mysql client with the --skip-reconnect option. For more information about auto-reconnect and its effect on state information when a reconnection occurs see Automatic Reconnection Control. The mysql client uses a parser on the client side that is not a duplicate of the complete parser used by the mysqld server on the server side. This can lead to differences in treatment of certain constructs. Examples: If it is desirable for mysql not to interpret short-form commands within comments a partial workaround is to use the --binary-mode option which causes all mysql commands to be disabled except \C and \d in noninteractive mode (for input piped to mysql or loaded using the source command). 448 mysql> SET @a=1; Query OK 0 rows affected (0.05 sec) mysql> INSERT INTO t VALUES(@a); ERROR 2006: MySQL server has gone away No connection. Trying to reconnect... Connection id: 1 Current database: test Query OK 1 row affected (1.30 sec) mysql> SELECT * FROM t; +------+ | a | +------+ | NULL | +------+ 1 row in set (0.05 sec) mysql Client Parser Versus Server Parser 4.5.2 mysqladmin — A MySQL Server Administration Program •The server parser treats strings delimited by " characters as identifiers rather than as plain strings if the ANSI_QUOTES SQL mode is enabled. •Within /*! ... */ and /*+ ... */ comments the mysql client parser interprets short-form mysql commands. The server parser does not interpret them because these commands have no meaning on the server side. The mysql client parser does not take the ANSI_QUOTES SQL mode into account. It treats strings delimited by " ’ and ‘ characters the same regardless of whether ANSI_QUOTES is enabled. | manuals |
TE LEADERSHIP TEAM (seated l to r) (standing l to r) Bob Hau Jane Leipold James O’Toole Tom Lynch Steve Merkt Rob Shaddock Joe Donahue Amy Shah Brad Gambill Terrence Curtin Joe Eckroth John Jenkins Joan Wainwright Executive titles can be found on the back inside cover. Not present: Minoru Okamoto | financial_reports |
Exhibit No. Exhibit Title Incorporated by Reference from the Following Documents 10.27 Form of Restated Employment Agreement between Core Laboratories N.V. and Richard L. Bergmark dated as of December 31 2007 1 Form 10-Q May 12 2008 (File No. 001-14273) 10.28 Amendment to Restated Employment Agreement dated December 31 2007 between Core Laboratories N.V. and Richard L. Bergmark 1 Form 10-K February 22 2011 (File No. 001-14273) 10.29 Form of Restated Employment Agreement between Core Laboratories N.V. and Monty L. Davis dated as of December 31 2007 1 Form 10-Q May 12 2008 (File No. 001-14273) 10.3 Amendment to Restated Employment Agreement dated December 31 2007 between Core Laboratories N.V. and Monty L. Davis 1 Form 10-K February 22 2011 (File No. 001-14273) 10.31 Master Note Purchase Agreement dated as of September 30 2011 Form 8-K September 30 2011 (File No. 001-14273) 21.1 Significant Subsidiaries of the Registrant Filed Herewith 23.1 Consent of PricewaterhouseCoopers LLP Filed Herewith 31.1 Certification of Chief Executive Officer Pursuant to Rule 13a-14 of the Securities Exchange Act of 1934 As Adopted Pursuant to Section 302 of the Sarbanes-Oxley Act of 2002 Filed Herewith 31.2 Certification of Chief Financial Officer Pursuant to Rule 13a-14 of the Securities Exchange Act of 1934 As Adopted Pursuant to Section 302 of the Sarbanes-Oxley Act of 2002 Filed Herewith 32.1 Certification of Chief Executive Officer Pursuant to 18 U.S.C. Section 1350 As Adopted Pursuant to Section 906 of the Sarbanes-Oxley Act of 2002 Furnished Herewith 32.2 Certification of Chief Financial Officer Pursuant to 18 U.S.C. Section 1350 As Adopted Pursuant to Section 906 of the Sarbanes-Oxley Act of 2002 Furnished Herewith 101.INS XBRL Instance Document Filed Herewith 101.SCH XBRL Schema Document Filed Herewith 101.CAL XBRL Calculation Linkbase Document Filed Herewith 101.LAB XBRL Label Linkbase Document Filed Herewith 101.PRE XBRL Presentation Linkbase Document Filed Herewith 101.DEF XBRL Definition Linkbase Document Filed Herewith 1 Management contracts or compensatory plans or arrangements. 66 | financial_reports |
EUOSHA/2021/OP/F/SE/0142 4.4.3 Lot 3: Organisation of corporate events A - Project management and quality assurance/lot 3 1. Price — 30 % 2. Quality — 70 % Tenders will be evaluated on the basis of the award criteria described below and their weighting: The price considered for evaluation will be the total price of the tender presented in the financial model ( Annex X-III ) covering all the requirements set out in the tender specifications. The quality of the tender will be evaluated regarding the project management and quality assurance on the one hand and the scenario (as described in section 5.2.5 ) on the other hand based on the criteria described below. Award criteria Information to be provided Maximum score (and minimum) Project management approach The tenderer should describe the proposed approach to the contract including methods to ensure the tenderer is able to respond professionally and in a timely manner to any type of request for services described in this call for tender. The approach must be relevant and stringent including the work planning schedule. The tenderer must explain how the methodology will guarantee a consistently high level of service and maximum efficiency in terms of costs speed and quality of service as described in the technical specifications. 250 (min. 50 %) Continuity of service and quality of team organisation The tenderer will demonstrate how to guarantee sufficient resources for the continuity of the service offered and the quality of service necessary for proper performance. The tenderer should demonstrate ability to carry out different projects or tasks simultaneously. It must also be explained how the tenderer will track/monitor the schedule set for the project teams avoid work overload and comply with deadlines specified. 250 (min. 50 %) 67 | government_tenders |
performance_schema_events_transactions_history_size 5105 performance_schema_events_waits_history_long_size 5105 performance_schema_events_waits_history_size 5105 performance_schema_hosts_size 5106 performance_schema_max_cond_classes 5106 performance_schema_max_cond_instances 5106 performance_schema_max_digest_length 5107 performance_schema_max_digest_sample_age 5107 performance_schema_max_file_classes 5108 performance_schema_max_file_handles 5108 performance_schema_max_file_instances 5109 performance_schema_max_index_stat 5109 performance_schema_max_memory_classes 5109 performance_schema_max_metadata_locks 5110 performance_schema_max_mutex_classes 5110 performance_schema_max_mutex_instances 5110 performance_schema_max_prepared_statements_instances 5111 performance_schema_max_program_instances 5111 performance_schema_max_rwlock_classes 5111 performance_schema_max_rwlock_instances 5112 performance_schema_max_socket_classes 5112 performance_schema_max_socket_instances 5112 performance_schema_max_sql_text_length 5113 performance_schema_max_stage_classes 5113 performance_schema_max_statement_classes 5114 performance_schema_max_statement_stack 5114 performance_schema_max_table_handles 5115 performance_schema_max_table_instances 5115 performance_schema_max_table_lock_stat 5115 performance_schema_max_thread_classes 5116 performance_schema_max_thread_instances 5116 performance_schema_session_connect_attrs_size 5117 performance_schema_setup_actors_size 5117 performance_schema_setup_objects_size 5118 performance_schema_show_processlist 5118 performance_schema_users_size 5118 persisted_globals_load 857 938 persist_only_admin_x509_subject 857 pid_file 858 plugin_dir 858 port 859 preload_buffer_size 859 print_identified_with_as_hex 859 profiling 860 profiling_history_size 860 protocol_compression_algorithms 860 protocol_version 861 proxy_user 861 pseudo_slave_mode 861 pseudo_thread_id 862 query_alloc_block_size 863 query_prealloc_size 863 rand_seed1 864 rand_seed2 864 5585 | manuals |
PART II. Item 5. MARKET FOR THE REGISTRANT'S COMMON EQUITY RELATED STOCKHOLDER MATTERS AND ISSUER PURCHASES OF EQUITY SECURITIES Our Common Stock trades on the NASDAQ Global Market under the symbol DXYN. No market exists for our Class B Common Stock. As of February 22 2019 the total number of holders of our Common Stock was approximately 2 800 including an estimated 2 400 shareholders who hold our Common Stock in nominee names. The total number of holders of our Class B Common Stock was 10. Recent Sales of Unregistered Securities Issuer Purchases of Equity Securities None. Fiscal Month Ending Total Number of Shares Purchased Average Price Paid Per Share Total Number of Shares Purchased as Part of Publicly Announced Plans or Programs Maximum Number (or approximate dollar value) of Shares That May Yet Be Purchased Under Plans or Programs November 3 2018 — $ — — December 1 2018 — — — December 29 2018 — — — Three Fiscal Months Ended December 29 2018 — $ — — $ 2 170 597 Quarterly Financial Data Dividends and Price Range of Common Stock Table of Contents 14 Following are quarterly financial data dividends and price range of Common Stock for the four quarterly periods in the years ended December 29 2018 and December 30 2017. Due to rounding the totals of the quarterly information for each of the years reflected below may not necessarily equal the annual totals. There is a restriction on the payment of dividends under our revolving credit facility and we have not paid any dividends in the years ended 12/29/2018 and 12/30/17. | financial_reports |
Investor Relations Information Annual Meeting Company Headquarters Form 10-K Requests Web Site: www.myersind.com National Association of Investors Corporation (NAIC) Common Stock Auditors Counsel Dividend Reinvestment Plan Shareholder Contacts Transfer Agent & Registrar The Annual Meeting of Shareholders will be held on Thursday April 25 2002 at 9:00 a.m. in the Company’s L.S. Myers Training Center 1554 South Main Street Akron Ohio. For more information please call (330) 253-5592. First Chicago Trust Company of New York A Division of Equiserve LLP 14 Wall Street New York NY 10005 Telephone Response Center: (201) 324-0313 Myers Industries Inc. 1293 South Main Street Akron Ohio 44301 Tel: (330) 253-5592 A copy of the Company’s 2001 Annual Report on Form 10-K is available to shareholders at our website or upon written request to: Gregory J. Stodnick Vice President Finance Myers Industries Inc. 1293 South Main Street Akron Ohio 44301 Myers Industries’ home page provides detailed information about the company including: Myers Industries is a corporate member of the National Association of Investors Corporation (NAIC) the world’s largest individual shareholder membership group. Myers participates in NAIC regional and national events. Arthur Andersen LLP 200 Public Square Suite 1800 Cleveland Ohio 44114 Tel: (216) 781-2140 Brouse McDowell LPA 500 First National Tower Akron Ohio 44308 Tel: (330) 535-5711 Gregory J. Stodnick Vice President Finance & CFO Max R. Barton II Investor Relations Manager Myers Industries Inc. • 1293 S. Main Street • Akron Ohio 44301 Telephone: (330) 253-5592 • Fax: (330) 761-6156 Shareholders have a convenient opportunity to automatically reinvest cash dividends and make voluntary cash investments in the Company’s stock through the Dividend Reinvestment Plan. Participating shareholders pay no brokerage commissions or other charges on purchases of shares under the Plan; all such commissions and charges are paid by the Company. For full details about participating in the Dividend Reinvestment Plan please contact Garee Daniska Assistant Treasurer Myers Industries Inc. 1293 South Main Street Akron Ohio 44301. First Chicago Trust Company of New York is the company’s principal transfer agent and registrar. Please contact First Chicago directly with all request to: Traded on the New York Stock Exchange • Transfer stock; • Change name or address; • Replace lost stock certificates or dividend checks; • Stock prices and charting from the NYSE; • Downloadable Annual Report PDF files; • SEC Filings; • Recent press releases; • Myers’ products services and markets; • Historical information about Myers; and • Information order form to obtain current financial and investor-related information. • Consolidate accounts; • Eliminate multiple mailings; and • Obtain statements of holdings. 34 | financial_reports |
Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de Futtermittel dürfen noch bis zum 31. August 2020 mit Etiketten die den Anforderungen des § 6 Absatz 2 der Futtermittelverordnung in der am 30. Juli 2018 geltenden Fassung genügen gekennzeichnet werden. Futtermittel die mit Etiketten die den Anforderungen des § 6 Absatz 2 in der am 30. Juli 2018 geltenden Fassung genügen gekennzeichnet sind dürfen noch in den Verkehr gebracht werden bis die Bestände aufgebraucht sind. (1) Auf Sachverhalte die vor dem 12. November 2015 entstanden sind ist § 36b Absatz 2 Nummer 1 Buchstabe b in der bis zum 30. November 2015 geltenden Fassung hinsichtlich der Verfolgung von Ordnungswidrigkeiten weiter anzuwenden. (2) § 39 Nummer 3 ist in der am 19. Juli 2017 geltenden Fassung bis zum Ablauf des 31. Dezember 2017 weiter anzuwenden. (3) Auf Sachverhalte die vor dem 24. Dezember 2020 entstanden sind sind die §§ 2 und 4 Absatz 1 § 40 Absatz 2 Nummer 2 und die Anlage 1 in der bis zum 24. Dezember 2020 geltenden Fassung hinsichtlich der Verfolgung von Ordnungswidrigkeiten weiter anzuwenden. (Inkrafttreten; Außerkrafttreten bisheriger Vorschriften) (Fundstelle: BGBl. I 2016 2026) Verwendete Abkürzungen Anlage 2 (zu § 6 Absatz 1) Schätzgleichungen zur Berechnung des Energiegehaltes von Mischfuttermitteln Anlage 1 (weggefallen) § 51 Inkrafttreten Übergangsregelungen § 50 Weitere Anwendung von Vorschriften § 49a Übergangsregelungen - Seite 23 von 27 - Tierart Mischfuttermittel Schätzgleichung 1 2 3 alle ME in MJ/kg T$^{1}$ = 7 17 – (g/kg T) Rohasche × 0 01171 Rinder Schafe Ziegen + (g/kg T) Rohprotein × 0 00712 + (g/kg T) Rohfett 2 × 0 01657 GE = Bruttoenergie ME = umsetzbare Energie MJ/kg = Megajoule je Kilogramm NEL = Nettoenergie-Laktation v. H. = vom Hundert g = Gramm ml = Milliliter mg = Milligramm T = Trockenmasse | laws_and_regulations |
composition of the company’s offshore service vessel fleet includes vessels that are operated under joint ventures as well as vessels that are stacked or withdrawn from service. The company has one of the most global operating footprints in the offshore energy industry with operations in most of the world's significant crude oil and natural gas exploration and production regions. The company is also one of the most experienced international operators in the offshore energy industry with over five decades of international experience. As of March 31 2010 the company had 394 vessels (of which 10 were operated through joint ventures 83 were stacked and seven were withdrawn from service) servicing the global energy industry. Please refer to Note 1 to Notes to Consolidated Financial Statements included in Item 8 of this report for additional information regarding our stacked vessels and vessels withdrawn from service. The company also operates two shipyards which construct modify and repair vessels. The shipyards perform both repair work and new construction work for outside customers as well as the construction repair and modification of the company’s own vessels. The company’s revenues net earnings and cash flows from operations are largely dependent upon the activity level of its offshore marine vessel fleet. As is the case with other energy service companies our business activity is driven by the level of drilling and exploration activity by our customers. Our customer's business activity in turn is dependent on crude oil and natural gas prices which fluctuate depending on expected future levels of supply and demand for crude oil and natural gas and on estimates of the cost to find develop and produce reserves. The company's worldwide headquarters and principal executive offices are located at 601 Poydras Street New Orleans Louisiana 70130 and its telephone number is (504) 568-1010. The company’s United States (U.S.) marine operations are based in Amelia Louisiana; Oxnard California; and Houston Texas. The company’s shipyards and shipyard operations are located in Houma Louisiana. We conduct our international operations through facilities and offices located in over 30 countries. Our principal international offices and/or warehouse facilities most of which are leased are located in Rio de Janeiro and Macae Brazil; Ciudad Del Carmen Mexico; Port of Spain Trinidad; Aberdeen Scotland; Cairo Egypt; Luanda and Cabinda Angola; Lagos and Onne Port Nigeria; Douala Cameroon; Singapore; Perth Australia; and Dubai United Arab Emirates. The company’s operations generally do not require highly specialized facilities and suitable facilities are generally available on a lease basis as required. The company operates in two reportable segments: International and the United States. The principal customers for each business segment are major and independent oil and natural gas exploration field development and production companies; drilling contractors; and other companies that provide various services to the offshore energy industry including but not limited to offshore construction companies diving companies and well stimulation companies. The international business segment also has customers that are foreign government-owned or -controlled organizations and companies that explore and produce oil and natural gas. The company’s vessels in its international segment are geographically dispersed in the major crude oil and natural gas exploration and development areas throughout the world. Although barriers such as mobilization costs the availability of suitable vessels and cabotage rules in certain countries occasionally restrict the ability of the company to move vessels between international markets the company’s diverse mobile asset base and the wide geographic distribution of its vessel assets enable the company to respond relatively quickly to changes in market conditions. As such significant variations between international regions tend to be of a short-term duration as the company routinely moves vessel between and within geographic regions. The company’s internationally based vessels operate in the shallow intermediate and deepwater offshore markets around the world. The deepwater offshore market continues to be a growing sector of the international offshore crude oil and natural gas markets and is the one sector that has not experienced significant negative effects from the recent global economic recession largely because the deepwater oil Business Segments Offices and Facilities -5- | financial_reports |
Figure 5-21. Inserting batten into batten pocket. Figure 5-20. Wings spread and battens organized to insert into wings. Note small stepladder holding up keel. Figure 5-23. Wing ready to tension. Figure 5-19. Raising the kingpost and spreading the wings as needed to keep the kingpost upright. Figure 5-22. Attaching double pull batten (inset). Batten secured into batten pocket. go into on both sides. Note the protective pads are still on the wing tips so they are protected. [Figure 5-20] Insert the battens into the batten pockets starting at the root and work out to the tip. [Figure 5-21] Most batten attachments are double pull. [Figure 5-22] Some manufacturers use cord or elastic and others use a system that slips into the sail itself. See the POH for wing details. Insert battens from the root towards the tip about ¾ the way out on each side. Leave the tip battens for later. Spread the wings as far as possible. [Figure 5-23] Check to ensure all the wires are straight not wrapped around and clear to tension the wing. Tension the wing by pulling back on the crossbar tensioning cable and pulling the crossbar back into position. This may require significant effort for some wings. Secure the tensioning cable to the back of the keel. [Figure 5-24] If the keel does not extend out then support the aft end of the keel to lift the tips off of the ground. [Figure 5-25] Move to the front and secure the front control frame flying wires to the underside nose attachment. [Figure 5-26] Remove the tip bag protectors and install the tip battens continuing to move from the root to the tips on each side. Insert the washout strut into the leading edge. Each manufacturer has its own washout strut systems and tip battens. Some manufacturers have no washout struts. Refer to the POH for wing specifi cs. [Figure 5-27] 5-10 | laws_and_regulations |
I ( φ $^{′}$) = − ∂ ∂φ ′ ∑ n ε$_{n}$ ( φ $^{′}$) (24) k = 2 π L n + k $^{′}$ (17) I$_{n}$ ( φ $^{′}$) = − ev$_{n}$ ( φ $^{′}$) L = − ∂ε$_{n}$ ( φ $^{′}$) ∂φ ′ . (23) ϕ n φ ( x + L ) = exp( i 2 π φ φ$_{0}$ ) ϕ n φ ( x ) . (16) ϕ$_{n φ}$ ( x ) = exp ( i 2 π L φ φ$_{0}$ x ) ψ n φ ( x ) (15) φ = nφ$_{0}$ + φ $^{ }$ (14) V ( x ) = V ( x + a ) (22) k = 2 π L n n = 0 ± 1 ± 2 . . . (13) ϕ$_{k}$ ( x ) = ϕ$_{k}$ ( x + L ) (12) k = 2 π L ( n + φ φ$_{0}$ ) . (21) k ′ = 2 π L φ φ$_{0}$ (20) ϕ n k ( x + L ) = exp( ik $^{ }$L ) ϕ n k ( x ) . (19) ϕ$_{k}$ ( x ) = exp( ikx ) u$_{k}$ ( x ) (10) u$_{k}$ ( x ) = u$_{k}$ ( x + L ) (11) 3 where the function u ′ n k ′ ( x ) ≡ exp ( i 2 π L nx ) u$_{k}$ ( x ) fulfills the periodic condition u ′ n k ′ ( x ) = u ′ n k ′ x + L . It is then easy to verify that where V ( x ) is the infinite periodic potential with period L obtained by the periodic repetition of the ring potential V ( x ) . Equation (9) has the well known Bloch solution The equations (15) and (16) coincide with the equations (18) and (19) respectively if where the function u$_{k}$ ( x ) fulfills the periodic condition or alternatively if and k is the electron wave vector from the interval ( −∞ ∞ ) . Clearly the wave function (5) and Bloch solution (10) coin- cide for k = 2 π L φ φ $_{0}$. Let us discuss this coincidence in detail. Consider first the ring with zero magnetic flux. To obtain the wave functions in such ring it suffices to take the Bloch function (10) and to restrict it by the periodic condition One can thus formulate the following general recipe. In the ring with a known potential V ( x ) the eigen-function ϕ n φ ( x ) ≡ ϕ$_{φ}$ ( x ) and eigen-energy ε$_{n}$ ( φ $^{′}$) ≡ ε ( φ ) can be calculated by setting (20) or (21) into the Bloch solutions ϕ$_{n k}$ ( x ) ≡ ϕ$_{k}$ ( x ) a ε$_{n}$ ( k $^{ }$) ≡ ε ( k ) calculated for the same potential V ( x ) repeated with period L from x = −∞ to x = ∞ . The general recipe holds for any potential V ( x ) obeying the cyclic condition (8). It therefore holds also for any potential which additionally obeys the periodic condition which is the condition (7) for φ = 0 . Due to the condition (12) the wave vector k becomes discrete: Thus in the ring with zero magnetic flux and specified poten- tial V ( x ) the eigen-function ϕ$_{n}$ ( x ) and eigen-energy ε$_{n}$ can be calculated simply by setting k = 2 π L n into the Bloch so- lutions ϕ$_{k}$ ( x ) a ε ( k ) calculated for the same potential V ( x ) repeated with period L from x = −∞ to x = ∞ . This recipe can be generalized to nonzero magnetic flux as follows. Arbitrary magnetic flux φ can be written in the form It remains to express the persistent current. The Bloch elec- tron in state ( n k $^{′}$) moves with velocity v$_{n}$ ( k $^{′}$) = 1 ℏ ∂ε$_{n}$ ( k $^{′}$) ∂k ′ . We set into the Bloch electron velocity the formula (20). We obtain the expression v$_{n}$ ( φ $^{′}$) = L e ∂ε$_{n}$ ( φ $^{′}$) ∂φ ′ which is the elec- tron velocity in state ( n φ $^{′}$) in the ring. The current carried by the electron in state ( n φ $^{′}$) reads The total persistent current circulating in the ring is where φ is the reduced flux from the range < − φ 0 2 φ 0 2 ) or alternatively from < 0 φ$_{0}$ ) and n is one of the values n = 0 ± 1 ± 2 . . . . Setting (14) into (5) one can write (5) in the form where the function ψ n φ ( x ) ≡ exp ( i 2 π L nx ) ψ$_{φ}$ ( x ) obeys the periodic condition ψ n φ ( x ) = ψ n φ ( x + L . The boundary condition (7) now reads Similarly in the Bloch function theory it is customary to express the wave vector k by means of the relation where we sum (at zero temperature) over all occupied states n = 0 ± 1 ± 2 . . . up to the Fermi level. In the following text we use the formulas (23) and (24) with symbol φ ′ changed to φ where φ ∈ < − φ 0 2 φ 0 2 ) or alternatively φ ∈ < 0 φ$_{0}$ ) . where k ′ is the reduced wave vector from the first Brillouin zone and the integer n plays the role of the energy band num- ber. Using (17) we can write the Bloch function (10) as ϕ$_{n k}$ ( x ) = exp ( ik $^{ }$x ) u n k ( x ) (18) where a = L/N and N is the (integer) number of periods a within the period L . This type of potential will be con- sidered in the rest of the paper. Figure 1 illustrates how an infinite 1D crystal is created from a 1D ring with lattice pe- riod a and length L = Na . Such crystal is still described by Schrödinger equation (9) except that now V ( x ) = V ( x + a ) and consequently u$_{k}$ ( x ) = u$_{k}$ ( x + a ) . However the condition u$_{k}$ ( x ) = u$_{k}$ ( x + L ) holds as well because V ( x ) = V ( x + L ) . We can rederive the general recipe briefly if we compare u$_{k}$ ( x ) = u$_{k}$ ( x + L ) with ψ$_{φ}$ ( x ) = ψ$_{φ}$ ( x + L ) and ϕ$_{k}$ ( x ) = exp( ikx ) u$_{k}$ ( x ) with ϕ$_{φ}$ ( x ) = exp ( i 2 π L φ φ $_{0}$x ) ψ$_{φ}$ ( x ) . We see that ϕ$_{φ}$ ( x ) coincides with ϕ$_{k}$ ( x ) for k = 2 π L φ φ $_{0}$. | scientific_articles |
Notes to the Financial Statements (continued) CONSOLIDATED PARENT 2003 2002 2003 2002 $000 $000 $000 $000 27. Reserves Asset revaluation 173 442 133 822 - - Foreign currency translation (1 753) 2 295 - - Total reserves 171 689 136 117 - - These comprise: (a) Asset Revaluation The asset revaluation reserve is used to record increments and decrements in the value of non-current assets. The reserve can only be used to pay dividends in limited circumstances. Movements during the year: Balance at beginning of year 133 822 113 763 - - Share of joint venture partnership’s reserve increments arising during the year 2 960 1 462 - - Revaluation increments on revaluation of: - land 26 061 14 568 - - - buildings 10 599 4 029 - - Balance at end of year 173 442 133 822 - - (b) Foreign Currency Translation The foreign currency translation reserve is used to record exchange differences arising from the translation of the financial statements of self-sustaining foreign operations. Movements during the year: Balance at beginning of year 2 295 2 128 - - Gain/(loss) on translation of overseas controlled entities (4 048) 167 - - Balance at end of year (1 753) 2 295 - - HARVEY NORMAN HOLDINGS LIMITED AND ITS CONTROLLED ENTITIES – ANNUAL REPORT 2003 49 | financial_reports |
expected to be completed before end of financial year 2018/2019. The financial statements of Botswana Housing Corporation for the financial year ended 31 March 2018 were audited by Messrs KPMG Certified Auditors who were appointed by the Board in terms of Section 24 (3) of Botswana Housing Corporation Act (Cap 74:03). In the opinion of the auditors: The financial statements presented fairly in all material respects the financial position of Botswana Housing Corporation as at 31 March 2018 and of its financial performance and cash flows for the year then ended in accordance with International Financial Reporting Standards. In the year under review the Corporation recorded a surplus of P87.75 million compared to a surplus of P48.50 million in the previous year representing an increase of 81%. Income reduced by P167.46 million representing 29% reduction from P587.52 million in the previous year to P420.08 million in the year under review while expenditure also declined by P205.70 million representing 39% reduction from P539.04 million in the previous year to P333.34 million during the same period. Sales of housing units income declined by P212.84 million (or 75%) while rental income increased by P13.41 million (or 7.6%) during the year under review. Significant reductions in expenditure were noted in cost of sale of housing inventories which went down by P198.62 million (or 77%) In the year under review the Corporation paid a dividend of P20.21 million compared to P27.20 million (2015/2016: P6.99 million and P20.21 million of the accumulated dividend paid in 134. Botswana Housing Corporation 2.0 Accounts 2.1 Audit Opinion 2.2 Financial Results 2.3 Dividends 124 | laws_and_regulations |
155 US 9 291 896 B2 156 -continued -continued F -o-~l_ tt"( 0 0 (zl0S) (z109) F -o-~ l_ o u" t "( 0 0 (zlll) (z112) (z113) (z114) (z115) [ [ [ 0 II s-o- 11 F F F 0 | patents |
So from inequality (30) we have which contradicts (22). So the proof is complete. Corollary 3. Assume that b ( t ) = 0 c ( t ) ≡ 0 and that Then every solution of Eq. (1)-(2) is oscillatory. Corollary 4. Assume that b ( t ) ≡ 0 c ( t ) = 0 and that Then every solution of Eq. (1)-(2) is oscillatory. Now we give some examples to illustrate our results. Note that previous results in the litarature can not be applied following differential equations to obtain existence of oscillatory solutions. where c ( t ) ≥ 0 is any continuous function. It can be shown that the hypotheses of Theorem 2 as well as Theorem 3 are satisfied. So all solutions of Eq. (31) are oscillatory. 16 x $^{′}$( t ) + πx ( t − 1 2 ) + c ( t ) x ([ t − 1]) = 0 t = n n = 1 2 ... t > 0 x ( n $^{+}$) − x ( n $^{−}$) = − x ( n $^{+}$) n = 1 2 ... (31) Example 1. Let us consider the following differential equation lim n $_{→∞}$inf n +1 ∫ n ∏ n − 1 <t$_{j}$ ≤ s (1 − b$_{j}$ $_{)}$ c ( s $_{) exp}$ s ∫ n − 1 a ( u ) $_{du}$ ds > 1 e . lim t $_{→∞}$inf t ∫ t − τ ∏ s − τ<t$_{j}$ ≤ s (1 − b$_{j}$ $_{)}$ b ( s $_{) exp}$ s ∫ s − τ a ( u ) $_{du}$ ds > 1 e . lim n $_{→∞}$inf n +1 ∫ n +1 − τ ∏ n − 1 <t$_{j}$ ≤ s (1 − b$_{j}$ $_{)}$ c ( s $_{) exp}$ s ∫ n − 1 a ( u ) $_{du}$ ds ≤ 1 e | scientific_articles |
8/15/19 3/15/07 1/30/20 AIM AIM g. Ultralight Vehicles. No person may operate an ultralight vehicle within Class A Class B Class C or Class D airspace or within the lateral boundaries of the surface area of Class E airspace designated for an airport unless that person has prior authorization from the ATC facility having jurisdiction over that airspace. (See 14 CFR Part 103.) h. Unmanned Free Balloons. Unless otherwise authorized by ATC no person may operate an unmanned free balloon below 2 000 feet above the surface within the lateral boundaries of Class B Class C Class D or Class E airspace designated for an airport. (See 14 CFR Part 101.) i. Parachute Jumps. No person may make a parachute jump and no pilot − in − command may allow a parachute jump to be made from that aircraft in or into Class A Class B Class C or Class D airspace without or in violation of the terms of an ATC authorization issued by the ATC facility having jurisdiction over the airspace. (See 14 CFR Part 105.) a. Definition. Generally that airspace from 18 000 feet MSL up to and including FL 600 including the airspace overlying the waters within 12 nautical miles off the coast of the 48 contiguous States and Alaska; and designated international airspace beyond 12 nautical miles off the coast of the 48 contiguous States and Alaska within areas of domestic radio navigational signal or ATC radar coverage and within which domestic procedures are applied. b. Operating Rules and Pilot/Equipment Requirements. Unless otherwise authorized all persons must operate their aircraft under IFR. (See 14 CFR Section 71.33 Sections 91.167 through 91.193 Sections 91.215 through 91.217 and Sections 91.225 through 91.227.) c. Charts. Class A airspace is not specifically charted. a. Definition. Generally that airspace from the surface to 10 000 feet MSL surrounding the nation’s busiest airports in terms of IFR operations or passenger enplanements. The configuration of each Class B airspace area is individually tailored and 3. No person may take off or land a civil aircraft at an airport within Class B airspace or operate a civil aircraft within Class B airspace unless: (a) The pilot − in − command holds at least a private pilot certificate; or 2. No person may take off or land a civil aircraft at the following primary airports within Class B airspace unless the pilot − in − command holds at least a private pilot certificate: 1. Unless otherwise authorized by ATC aircraft must be equipped with an operable two-way radio capable of communicating with ATC on appropriate frequencies for that Class B airspace. b. Operating Rules and Pilot/Equipment Re- quirements. Regardless of weather conditions an ATC clearance is required prior to operating within Class B airspace. Pilots should not request a clearance to operate within Class B airspace unless the requirements of 14 CFR Sections 91.131 91.215 and 91.225 are met. Included among these requirements are: consists of a surface area and two or more layers (some Class B airspace areas resemble upside-down wedding cakes) and is designed to contain all published instrument procedures once an aircraft enters the airspace. An ATC clearance is required for all aircraft to operate in the area and all aircraft that are so cleared receive separation services within the airspace. The cloud clearance requirement for VFR operations is “clear of clouds.” (a) Andrews Air Force Base MD (b) Atlanta Hartsfield Airport GA (c) Boston Logan Airport MA (d) Chicago O’Hare Intl. Airport IL (e) Dallas/Fort Worth Intl. Airport TX (f) Los Angeles Intl. Airport CA (g) Miami Intl. Airport FL (h) Newark Intl. Airport NJ (i) New York Kennedy Airport NY (j) New York La Guardia Airport NY (k) Ronald Reagan Washington National Airport DC (l) San Francisco Intl. Airport CA 3 − 2 − 3. Class B Airspace 3 − 2 − 2. Class A Airspace Controlled Airspace 3 − 2 − 2 | laws_and_regulations |
Options Future Change in Accounting Policy Foreign Currency Risk Options are contractual agreements that convey the right but not the obligation to either buy or sell a specific amount of a currency commodity equity or financial instrument at a fixed price either at a fixed future date or at any time within a fixed future period. We manage foreign currency risk through cross-currency swaps. We also periodically hedge contractual U.S. dollar revenues to minimize fluctuations in U.S. dollar earnings through forward foreign exchange contracts. The Canadian Institute of Chartered Accountants has approved new accounting requirements for derivatives. Under these new requirements all derivatives are marked to market unless they meet criteria for hedging. We will be adopting the new requirements in fiscal 2003 and do not expect these new requirements to impact our results as our accounting policies already substantially comply with these new requirements. The effect of asset/liability management derivatives on net interest income and the net amount of deferred realized losses included in other liabilities in our Consolidated Balance Sheet was: These contracts are marked to market and mature monthly as related revenues are recorded and the realized gains and losses on these contracts are then recorded in non-interest revenue. For options written by us we receive a premium from the pur- chaser for accepting market risk. For options purchased by us a premium is paid for the right to exercise the option but we sustain credit risk due to the uncertainty as to the writer’s ability to fulfill the conditions of the contract. Also included in options are caps collars and floors which are contractual agreements where the writer agrees to pay the purchaser based on a specified notional amount the agreed upon difference between the market rate and the prescribed rate of the cap collar or floor. The writer receives a premium for selling this instrument. One technique that we use to reduce credit exposure on derivatives is to enter into master netting agreements with customers. These allow us to offset amounts due to/from a customer to limit our losses should the customer default on a derivative contract. Losses incurred on defaults of counterparties charged to the allowance for credit losses in the years ended October 31 2002 2001 and 2000 were not significant. The following terms are used in the derivatives table on page 88 which summarizes our derivative portfolio and related credit exposure. We manage interest rate risk primarily through interest rate swaps and options which are linked to and adjust the interest rate sensi- tivity of a specific asset liability firm commitment or a specific pool of transactions with similar risk characteristics. These include fair value hedges which modify exposure to interest rate risk by converting fixed rate assets and liabilities to floating rate and cash flow hedges which hedge exposure to variability in cash flows for variable rate interest bearing instruments. Our fair value hedges are primarily hedges of fixed rate deposits and mortgages. Our cash flow hedges which have a maximum term of 12 years are primarily hedges of floating rate deposits and commercial and personal loans. Types of Derivatives Derivative transactions both customer trading and ALM which are conducted directly between two counterparties in the over-the- counter market or on regulated exchange markets include: Swaps are contractual agreements between two parties to exchange a series of cash flows. For interest rate swaps counterparties generally exchange fixed and floating rate interest payments based on a notional value in a single currency. The main risks associated with these instruments are the exposure to movements in interest rates and the ability of the counterparties to meet the terms of the contract. Interest rate swaps are used to adjust exposure to interest rate risk by modifying the repricing or maturity characteristics of assets and liabilities. For cross-currency swaps fixed interest payments and notional amounts are exchanged in different currencies. For cross-currency interest rate swaps principal amounts and fixed and floating interest payments are exchanged in different currencies. For commodity swaps counterparties generally exchange fixed and floating rate payments based on a notional value in a single commodity. Risk-weighted balance: represents the credit risk equivalent weighted based on the creditworthiness of the counterparty as prescribed by the Superintendent of Financial Institutions Canada. Exchange traded derivatives have no potential for credit exposure as they can be settled net with the exchange. Credit risk equivalent: represents the total replacement cost and thereby the potential future credit exposure if the counter- party defaults. Replacement cost: represents the cost of replacing all contracts which have a positive fair value using current market rates. This figure represents in effect the unrealized gains on our deriv- ative instruments. Notional amount: represents the amount to which a rate or price is applied in order to calculate the amount of cash that must be exchanged under the contract. Forwards and futures are contractual agreements to either buy or sell a specified currency commodity equity or financial instrument at a specific price and date in the future. Forwards are customized contracts transacted in the over-the-counter market. Futures are transacted in standardized amounts on regulated exchanges and are subject to daily cash margining. Risks arise from the possible inability of over-the-counter counterparties to meet the terms of their contracts and from movements in securities values interest rates and foreign exchange rates. Forwards and Futures Swaps Interest Rate Risk 2002 2001 2000 Increase (decrease) in net interest income $ 236 $ 8 $ 94 Deferred realized (losses) $ (10) $ (10) $ (15) BMO FINANCIAL GROUP ANNUAL REPORT 2002 87 | financial_reports |
Shareholder and Corporate Information As of March 31 2003 there were 508 shareholders of record of the Company’s common stock. In addition 1 818 Columbus McKinnon employees owned shares through the Company ESOP. Approximately 1 500 additional shareholders held shares in “street name.” August 18 2003; 10:00 a.m. Columbus McKinnon Corporation Corporate Headquarters 140 Audubon Parkway Amherst NY 14228-1197 Please direct questions about lost certificates change of address and consolidation of accounts to the Company’s transfer agent and registrar: American Stock Transfer & Trust Company 59 Maiden Lane Plaza Level New York NY 10038 (718) 921-8200 www.amstock.com Positioning Lois H. Demler Corporate Secretary Columbus McKinnon Corporation 140 Audubon Parkway Amherst NY 14228-1197 (716) 689-5409 lois.demler@cmworks.com Investor information is available on the Company’s Web site: www.cmworks.com Investor Relations Contact Transfer Agent Annual Shareholders Meeting The following are trademarks of Columbus McKinnon Corporation registered in the U.S. Patent and Trademark Office: CM Big Orange Bossman Budgit Cady Coffing ColorLinks Conco Cyclone Duff-Norton Hammerlok Herc- Alloy Lift-Tech LTI Little Mule Lodestar Shaw-Box Tigrip Univeyor Yale. The following are trademarks of Columbus McKinnon Corporation: Abell-Howe Camlok CM Max CraneMart Deeweld Gaffey LARCO Positech Raccords Gautier Rotary Union Univeyor WECO. Ernst & Young LLP 50 Fountain Plaza 14th floor Buffalo NY 14202-2297 Independent Auditors According to the March 31 2003 SEC filings approximately 36 institutional investors own 42.6% of Columbus McKinnon’s outstanding shares. Corporate Headquarters Lifting Corporate Headquarters Columbus McKinnon Corporation 140 Audubon Parkway Amherst NY 14228-1197 Telephone: (716) 689-5400 Safely Efficiently 39 | financial_reports |
Vertragsbedingungen von Dezember 2015 Vertragsnummer: [ Io = Index für den Monat in dem der Vertrag in Kraft tritt; Ir = Index für den Monat in dem der Antrag auf Preisanpassung eingeht. Zahlungen gelten als an dem Tag geleistet an dem das Konto des Auftraggebers belastet wird. Zahlungen werden in EUR oder in der in Artikel I.7 genannten Währung geleistet. Der Auftraggeber nimmt Umrechnungen zwischen EUR und einer anderen Währung zu dem im Amtsblatt der Europäischen Union veröffentlichten EUR-Tageskurs vor oder wenn dies nicht möglich ist zu dem von der Europäischen Kommission ermittelten und auf der untengenannten Website veröffentlichten monatlichen Buchungskurs für den Tag an dem der Auftraggeber die Zahlungsanweisung ausstellt. Der Auftragnehmer nimmt Umrechnungen zwischen EUR und einer anderen Währung zu dem von der Europäischen Kommission ermittelten und auf der untengenannten Website veröffentlichten monatlichen Buchungskurs vor der am Rechnungsdatum gilt. http://ec.europa.eu/budget/contracts_grants/info_contracts/inforeuro/inforeuro_de.cfm Hinsichtlich der Überweisungskosten gilt Folgendes: Wird gemäß Artikel I.6 für eine Vorfinanzierung eine Sicherheit in Form einer Erfüllungsgarantie oder eines Gewährleistungseinbehalts verlangt sind folgende Bedingungen zu erfüllen: Der Auftragnehmer trägt die Kosten dieser Sicherheitsleistung. 29 (b) der Garantiegeber leistet die Sicherheit auf erste Anforderung und verzichtet auf die Einrede der Vorausklage gegen den Hauptschuldner (den Auftragnehmer). (a) Die Sicherheit wird von einer Bank oder einem vom Auftraggeber anerkannten Finanzinstitut oder auf Ersuchen des Auftragnehmers und mit Zustimmung des Auftraggebers von einem Dritten geleistet; (c) verursacht eine Vertragspartei eine nochmalige Überweisung trägt sie die Gebühren dafür. (b) der Auftragnehmer trägt die von seiner Bank in Rechnung gestellten Gebühren für eingehende Überweisungen; (a) Der Auftraggeber trägt die von seiner Bank in Rechnung gestellten Gebühren für ausgehende Überweisungen; II.20.5. Vorfinanzierungsgarantie Erfüllungsgarantie und Gewährleistungseinbehalt II.20.4. Überweisungskosten II.20.3. Umrechnung II.20.2. Währung II.20. ZAHLUNGEN UND SICHERHEITSLEISTUNGEN II.20.1. Zahlungsdatum | government_tenders |
NOTES TO CONSOLIDATED FINANCIAL STATEMENTS December 31 2011 2010 and 2009 (currencies in millions) The balance sheet classification of the Company’s deferred tax assets and liabilities are as follows: Cash paid for income taxes was $284.0 $82.9 and $67.3 in 2011 2010 and 2009 respectively. A reconciliation of the beginning and ending amount of unrecognized tax benefits is as follows: The Company had $16.3 and $40.6 of related assets at December 31 2011 and 2010. All of the unrecognized tax benefits and related assets would impact the effective tax rate if recognized. The Company recognized $1.7 of income related to interest and penalties in 2011. Accrued interest expense and penalties were $5.7 and $7.8 at December 31 2011 and 2010 respectively. The Company does not anticipate that there will be a material increase or decrease in the total amount of unrecognized tax benefits in the next twelve months. As of December 31 2011 the United States Internal Revenue Service has completed examinations of the Company’s tax returns for all years through 2008. The Company’s tax returns for other major jurisdictions remain subject to examination for the years ranging from 2004 through 2011. 2011 2010 2009 Balance at January 1 $ 43.1 $ 37.0 $ 33.0 Additions based on tax positions and settlements related to the current year 5.4 2.5 1.1 Additions based on tax positions and settlements related to the prior year 1.1 23.5 11.5 Reductions for tax positions of prior years (30.6) (10.7) (7.2) Lapse of statute of limitations (.7) (9.2) (1.4) Balance at December 31 $ 18.3 $ 43.1 $ 37.0 At December 31 2011 2010 Truck and Other: Other current assets $ 126.0 $ 98.8 Other noncurrent assets net 126.3 79.2 Accounts payable accrued expenses and other (1.0) Other liabilities (41.0) (26.7) Financial Services: Other assets 55.1 48.9 Deferred taxes and other liabilities (730.7) (529.5) Net deferred tax liability $(465.3) $(329.3) | financial_reports |
8/15/19 3/15/07 1/30/20 AIM 7110.65R CHG 2 AIM 6. Helicopter Route Charts. A three − color chart series which shows current aeronautical information useful to helicopter pilots navigating in areas with high concentrations of helicopter activity. Information depicted includes helicopter routes four classes of heliports with associated frequency and lighting capabilities NAVAIDs and obstructions. In addition pictorial symbols roads and easily identified geographical features are portrayed. Helicopter charts have a longer life span than other chart products and may be current for several years. Helicopter Route Charts are updated as requested by the FAA. Scale 1 inch = 1.71 nm/1:125 000. 34 x 30 inches folded to 5 x 10 inches. Revised biannually. (See FIG 9 − 1 − 4.) 1. IFR En Route Low Altitude Charts (Conterminous U.S. and Alaska). En route low altitude charts provide aeronautical information for navigation under IFR conditions below 18 000 feet MSL. This four − color chart series includes airways; limits of controlled airspace; VHF NAVAIDs with frequency identification channel geographic coor- dinates; airports with terminal air/ground communications; minimum en route and obstruction clearance altitudes; airway distances; reporting points; special use airspace; and military training routes. Scales vary from 1 inch = 5nm to 1 inch = 20 nm. 50 x 20 inches folded to 5 x 10 inches. Charts revised every 56 days. Area charts show congested terminal areas at a large scale. They are included with subscriptions to any conterminous U.S. Set Low (Full set East or West sets). (See FIG 9 − 1 − 5 and FIG 9 − 1 − 6.) b. IFR Navigation Charts. FIG 9 − 1 − 4 Helicopter Route Charts Types of Charts Available 9 − 1 − 4 | laws_and_regulations |
3 FIG. 2: (Color online) The variations of ¯ S and f$_{GCC}$ during the removal of weak ties first and strong ties first respectively. f$_{r}$ is the fraction of removed ties. formation diffusion in online social networks is different from traditional models such as SIS SIR and random walk. We start by discussing the procedure of informa- tion diffusion in online social networks. nected cluster (GCC) denoted by f$_{GCC}$ shows differ- ent dynamics between the removals of weak ties first and strong ties first. We denote the critical fractions of the re- moved ties at the phase transition point by f$_{c}$ . It is inter- esting to note that f$_{c}$ = 0 . 753 for YouTube and f$_{c}$ = 0 . 890 for Facebook when ¯ S reaches the submit which are very close to the case when f$_{GCC}$ ≈ 0. In the percolation theory the existence of the above phase transition means that the network is collapsed while the network is just shrinking if there is no phase transition when removing the ties [19]. So the above ex- periments tell us that weak ties play a special role in the structure of online social networks which is different from the one strong ties play. In fact they act as the important bridges that connect isolated communities. In what follows we build a model that associates the weak ties with the information diffusion to discuss the coupled dynamics of the structure and the information diffusion. The procedure of the diffusion in online social networks can be briefly described as follows: The information diffusing in online social networks in- cludes blogs photos messages comments multimedia files states etc. Because of the privacy control and other features of online social sites the mechanism of the in- It is easy to find that the key feature of the informa- tion diffusion in online social networks is that the infor- mation is pushed actively by the site and only part of • The user i publishes the information I which may be a photo a blog etc. • Friends of i will know I when they access the profile page of i or get some direct notifications from the online social site. We call this scheme as push . • Some friends of i may be one many or none will comment cite or reprint I because they think that it is interesting funny or important. We call this behavior as republish . • The above steps will be repeated with i replaced by each of those who have republished I . A. The Procedure of Information Diffusion IV. DIFFUSING ROLE OF WEAK TIES 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 5 10 15 20 25 30 35 40 f$_{r}$ ¯ S Remove Weak Ties First Remove Strong Ties First f$_{c}$ (a) Facebook 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 f$_{r}$ f GCC Remove Strong Ties First Remove Weak Ties First f$_{c}$ (b) Facebook 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 50 100 150 200 250 f$_{r}$ ¯ S Remove Strong Ties First Remove Weak Ties First f$_{c}$ (c) YouTube 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 f$_{r}$ f GCC Remove Strong Ties First Remove Weak Ties First f$_{c}$ (d) YouTube | scientific_articles |
10-K 1 form10k.htm FORM 10-K UNITED STATES SECURITIES AND EXCHANGE COMMISSION FORM 10-K For the Fiscal Year Ended December 31 2019 PROTECTIVE INSURANCE CORPORATION Washington D.C. 20549 ☒ ☐ ANNUAL REPORT PURSUANT TO SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934 OR TRANSITION REPORT PURSUANT TO SECTION 13 OR 15(d) OF THE SECURITIES EXCHANGE ACT OF 1934 For the transition period from ______ to ______ Commission file number: 0-5534 (Exact Name of Registrant as Specified in Its Charter) Indiana (State or Other Jurisdiction of Incorporation or Organization) 111 Congressional Boulevard Carmel Indiana (Address of Principal Executive Offices) 35-0160330 (I.R.S. Employer Identification No.) 46032 (Zip Code) Registrant's telephone number including area code: (317) 636-9800 Securities registered pursuant to Section 12(b) of the Act: Securities registered pursuant to Section 12(g) of the Act: None Indicate by check mark if the registrant is a well-known seasoned issuer as defined in Rule 405 of the Securities Act. Yes ☐ No ☒ Indicate by check mark if the registrant is not required to file reports pursuant to Section 13 or Section 15(d) of the Act. Yes ☐ No ☒ Indicate by check mark whether the registrant (1) has filed all reports required to be filed by Section 13 or 15(d) of the Securities Exchange Act of 1934 during the preceding 12 months (or for such shorter period that the registrant was required to file such reports) and (2) has been subject to such filing requirements for the past 90 days. Yes ☒ No ☐ Indicate by check mark whether the registrant has submitted electronically every Interactive Data File required to be submitted pursuant to Rule 405 of Regulation S-T (§ 232.405 of this chapter) during the preceding 12 months (or for such shorter period that the registrant was required to submit such files). Yes ☒ No ☐ Indicate by check mark whether the registrant is a large accelerated filer an accelerated filer a non-accelerated filer a smaller reporting company or an emerging growth company. See the definitions of "large accelerated filer" "accelerated filer" "smaller reporting company" and "emerging growth company" in Rule 12b-2 of the Exchange Act. Large accelerated filer ☐ Non-accelerated filer ☐ Accelerated filer ☒ Smaller reporting company ☐ Emerging growth company ☐ If an emerging growth company indicate by check mark if the registrant has elected not to use the extended transition period for complying with any new or revised financial accounting standards provided pursuant to Section 13(a) of the Exchange Act. ☐ Indicate by check mark whether the registrant is a shell company (as defined in Rule 12b-2 of the Exchange Act). Yes ☐ No ☒ The aggregate market value of Class A and Class B Common Stock held by non-affiliates of the Registrant as of June 28 2019 based on the closing trade prices on that date was approximately $175 668 000. The number of shares outstanding of each of the issuer's classes of common stock as of March 1 2020: Title of each class Trading Symbol(s) Name of each exchange on which registered Class A Common Stock No Par Value PTVCA The Nasdaq Stock Market LLC Class B Common Stock No Par Value PTVCB The Nasdaq Stock Market LLC | financial_reports |
Extending and Embedding Python Release 3.9.5 Appendix D. Copyright 98 | manuals |
Dedicated to moving technologies forward. With environmental regulations and cost of ownership changing the landscape of vehicle designs worldwide a focus on innovation is essential. Dana is continually devising new breakthroughs to reduce complexity friction losses weight and emissions while optimizing performance and improving fuel efficiency. Here are just a few of the ways that Dana is introducing tomorrow’s technologies into the present day. To help boost fuel economy while lowering costs of commercial vehicles Dana introduced two new lines of lightweight axles which are designed to enable the global trend of downspeeding engines. The Spicer$^{®}$ D-Series steer axles offer improved vehicle stopping power and reduced maintenance without the added weight that traditionally results from specifying air disc brakes while the Spicer$^{®}$ E-Series axles deliver best-in-class performance and durability. Dana’s multi-layer steel transmission separator plates have been selected as a finalist for the 2015 Automotive News PACE Awards. Designed to meet the demands of advanced transmissions this efficient technology can withstand higher sealing pressures and achieve greater levels of cleanliness than competitive products. The plates also prevent seal erosion and reduce energy consumption and CO$_{2}$ emissions. This is the fourth consecutive year that Dana has been selected as a finalist for a PACE Award which is recognized around the world as the industry benchmark for automotive supplier innovation. Supported by Dana’s advanced technology centers in Belgium Italy and the United States the Spicer$^{®}$ PowerBoost$^{®}$ hydraulic-hybrid system for construction equipment material-handling machines and on-highway vocational vehicles is now offered to manufacturers for field testing. Functional evaluations on a mid-sized front-end loader and compact telescopic boom handler have verified fuel savings exceeding 20 percent when compared with traditional drivetrain configurations. This year the technology was honored at the INTERMAT Innovation Awards which recognize products that advance the construction and construction-materials industries. Development advances on Spicer$^{®}$ PowerBoost$^{®}$ technology Multi-layer steel transmission technology honored by Automotive News New steer axle lines reduce weight while increasing efficiency and productivity | financial_reports |
unsecured borrowing market would be limited. We may also be subject to additional restrictive covenants that would reduce our flexibility. In addition macroeconomic conditions such as continued or increased volatility or disruption in the credit markets could adversely affect our ability to refinance existing debt or obtain additional financing to support operations or to fund new acquisitions or other capital-intensive initiatives. We have two classes of stock: Class A Common Stock and Class B Common Stock. Holders of Class A Common Stock are entitled to elect 30% of the Board of Directors and to vote with holders of Class B Common Stock on the reservation of shares for equity grants certain material acquisitions and the ratification of the selection of our auditors. Holders of Class B Common Stock are entitled to elect the remainder of the Board and to vote on all other matters. Our Class B Common Stock is principally held by descendants of Adolph S. Ochs who purchased The Times in 1896. A family trust holds approximately 90% of the Class B Common Stock. As a result the trust has the ability to elect 70% of the Board of Directors and to direct the outcome of any matter that does not require a vote of the Class A Common Stock. Under the terms of the trust agreement the trustees are directed to retain the Class B Common Stock held in trust and to vote such stock against any merger sale of assets or other transaction pursuant to which control of The Times passes from the trustees unless they determine that the primary objective of the trust can be achieved better by the implementation of such transaction. Because this concentrated control could discourage others from initiating any potential merger takeover or other change of control transaction that may otherwise be beneficial to our businesses the market price of our Class A Common Stock could be adversely affected. Our business depends on our intellectual property including our valuable brands content services and internally developed technology. We believe our proprietary trademarks and other intellectual property rights are important to our continued success and our competitive position. Unauthorized parties may attempt to copy or otherwise unlawfully obtain and use our content services technology and other intellectual property and we cannot be certain that the steps we have taken to protect our proprietary rights will prevent any misappropriation or confusion among consumers and merchants or unauthorized use of these rights. Advancements in technology have made the unauthorized duplication and wide dissemination of content easier making the enforcement of intellectual property rights more challenging. In addition as our business and the risk of misappropriation of our intellectual property rights have become more global in scope we may not be able to protect our proprietary rights in a cost-effective manner in a multitude of jurisdictions with varying laws. If we are unable to procure protect and enforce our intellectual property rights including maintaining and monetizing our intellectual property rights to our content we may not realize the full value of these assets and our business and profitability may suffer. In addition if we must litigate in the United States or elsewhere to enforce our intellectual property rights or determine the validity and scope of the proprietary rights of others such litigation may be costly and divert the attention of our management. We periodically receive claims from third parties alleging infringement misappropriation or other violations of their intellectual property rights. These third parties often include patent holding companies seeking to monetize patents they have purchased or otherwise obtained through asserting claims of infringement or misuse. Even if we believe that these claims of intellectual property infringement are without merit defending against the claims can be time-consuming be expensive to litigate or settle and cause diversion of management attention. These intellectual property infringement claims may require us to enter into royalty or licensing agreements on unfavorable terms use more costly alternative technology or otherwise incur substantial monetary liability. Additionally these claims may require us to significantly alter certain of our operations. The occurrence of any of these events as a result of these claims could result in substantially increased costs or otherwise adversely affect our business. P. 12 – THE NEW YORK TIMES COMPANY We have been and may be in the future subject to claims of intellectual property infringement that could adversely affect our business. Our business may suffer if we cannot protect our intellectual property. Our Class B Common Stock is principally held by descendants of Adolph S. Ochs through a family trust and this control could create conflicts of interest or inhibit potential changes of control. | financial_reports |
ManageMent’s Discussion anD analysis Information in this section is based on International Financial Reporting Standards (IFRS) unless otherwise indicated. However in the information about sales by product on pages 88–93 sales of each product and year-on-year changes are based on J-GAAP. In this section the Americas and EMEA are used as follows: the Americas refers to North Central and South America; EMEA includes Europe along with the Middle East and Africa. In the year under review the pharmaceutical industry con- tinued to face a challenging operating environment. This was due to a number of factors including stricter regula- tory processes for approval of new drugs and increased moves to curb medical expenditures in developed nations as well as emerging countries. Against this backdrop Astellas actively pursued growth in all aspects of its busi- ness from research and development through to manufac- turing and sales. We continued our strategy of developing high-value-added innovative drugs in fields with unmet medical needs for worldwide supply. Astellas is actively developing its business in Japan and in the global markets of the Americas EMEA Asia & Oceania and elsewhere. The Company also has a high level of over- seas ownership with more than 50% of its shares held by foreign shareholders. Given its global operations share- holder composition and other such factors Astellas has adopted the International Financial Reporting Standards (“IFRS”) effective from fiscal 2013 as a means of enabling capital market participants to more readily com- pare the financial information on an international basis. In line with the Company’s change to IFRS the Company discloses financial results on a core basis as an indicator of its recurring profitability. Certain items reported in financial results under IFRS on a full basis that are deemed to be non-recurring items by the Company are excluded as non- core items from these financial results on a core basis. These adjusted items include impairment losses gain (loss) on sales of non-current assets restructuring costs loss on disaster a large amount of losses on compensation or settlement of litigation and other legal disputes and other items that the Company judges should be excluded. In fiscal 2013 consolidated sales increased 16.1% year on year to ¥1 139.9 billion. New products contributed to increased sales including XTANDI for the treatment of prostate cancer and Betanis/ Myrbetriq/BETMIGA for the treatment of overactive bladder (OAB). In addition sales of Vesicare for the treatment of OAB and other products continued to increase. Sales of Prograf an immunosuppressant and Harnal for the treat- ment of functional symptoms of benign prostatic hyperplasia increased partly due to the foreign exchange rate impact. Consolidated Performance Overview Foreign Exchange Rates (Average) Fluctuation in Foreign Exchange Rates from April to March Adoption of International Financial Reporting Standards Consolidated Financial Results (Core Basis) Overview of Year Ended March 31 2014 (Fiscal 2013) Consolidated operating results (core basis) for fiscal 2013 are shown in the table below. Sales core operating profit and core profit for the year increased. The exchange rates for the yen in fiscal 2013 are shown in the table below. Movements in the rates led to a ¥113.0 billion increase in the value of sales and a ¥24.2 billion increase in core operating profit. Foreign Exchange Impact for Fiscal 2013 (¥ million) 2013.3 2014.3 Sales ¥981 899 ¥1 139 909 Core operating profit 168 022 186 253 Core profit for the year 118 792 132 796 (¥) 2013.3 2014.3 US$1 ¥83 ¥100 € 1 107 134 (¥) 2013.3 2014.3 US$1 ¥12 (Weakening of yen) ¥ 9 (Weakening of yen) € 1 ¥11 (Weakening of yen) ¥21 (Weakening of yen) Sales Astellas Pharma Inc. _ Annual Report 2014 86 | financial_reports |
US 2007/0072121 Al 2 Mar. 29 2007 -continued (Al) wherein [0017] in the formula (Ia) AR represents an aromatic group and X$_{1 }$represents a group having a carbon number of 5 or more and being capable of decomposing under the action of an acid and [0018] in the formula (Al) m represents an integer of one of 1 and 2. [0021] ( 4) A positive resist composition comprising: [0022] (A-2) a resin of which a solubility in an alkali developer increases under the action of an acid the resin comprising a repeating unit represented by formula (lb) and a repeating unit represented by formula (A2); and [0023] (B) a compound capable of generating an acid upon irradiation with one of actinic rays and radiation: [0019] (2) The positive resist composition as described in the item (1) wherein X$_{1 }$ has a tertiary carbon atom bonded to the oxygen atom in formula (Ia). [0020] (3) The positive resist composition as described in the item (1) wherein X$_{1 }$ has an alicyclic group. [0026] (5) The positive resist composition as described in the item (4) above wherein X$_{2 }$ is a group capable of decomposing under the action of the acid. [0027] (6) The positive resist composition as described in the item (5) wherein X$_{2 }$ is a group having an alicyclic group and being capable of decomposing under the action of the acid. wherein [0024] in the formula (lb) AR represents an aromatic group and X$_{2 }$ represents one of a hydrogen atom and a hydrocarbon group and [0025] in the formula (A2) A$_{1 }$represents a group contain› ing a group capable of decomposing under the action of the acid and n represents an integer of one of 1 and 2. [0028] (7) A pattern forming method comprising: [0029] forming a resist film from a positive resist compo› sition as described in the item (1 ); and [0030] exposing and developing the resist film. [0031] (8) The pattern forming method as described in the item (7) wherein the resist film is exposed with one of electron beam and extreme ultraviolet light. [0032] (9) A pattern forming method comprising: [0033] forming a resist film from a positive resist compo› sition as described in the item (4); and [0034] exposing and developing the resist film. [0036] According to the present invention as regards the pattern formation by the irradiation of electron beam KrF excimer laser light EUV light or the like a positive resist composition excellent in the sensitivity and resolving power and further excellent in the pattern profile defocus latitude depended on line pitch and dissolution contrast and a pattern forming method using the composition can be pro› vided. [0035] (10) The pattern forming method as described in the item (9) wherein the resist film is exposed with one of electron beam and extreme ultraviolet light. DETAILED DESCRIPTION OF THE INVENTION [0037] The compounds for use in the present invention are described in detail below. [0038] Incidentally in the present invention when a group ( atomic group) is denoted without specifying whether sub› stituted or unsubstituted the group includes both a group having no substituent and a group having a substituent. For example an "alkyl group" includes not only an alkyl group having no substituent (unsubstituted alkyl group) but also an alkyl group having a substituent (substituted alkyl group). [1] Resins (A-1) and (A-2) which are insoluble or sparingly soluble in an alkali developer and of which solubility in an alkali developer increases under the action of an acid [0039] The resin of which solubility in an alkali developer increases under the action of an acid contained in the positive resist composition of the present invention is at least either a resin (A-1) comprising a repeating unit repre› sented by formula (Ia) and a repeating unit represented by formula (Al) or a resin (A-2) comprising a repeating unit represented by formula (lb) and a repeating unit represented by formula (A2). [0040] In formula (Ia) AR represents an aromatic group preferably a phenyl group (a hydroxyphenyl group as a phenyl group having a substituent) a naphthyl group or an anthranyl group. (lb) AR I ---f CH - CH- - I C=O I OX2 (A2) (Resin (A-1)) AR I ---fCH-CH- - 1 c=o I OX1 (la) (Al) | patents |
Figure 2-5 Setting up NFS server primer -1 3. Install the Helm chart through IBM Cloud Private. Click the nfs-client tile as in Figure 2-5 and configure the Helm chart with the following values for your cluster. We documented the figures as follows: – You see callout letters beside each field where you enter a value. – Each callout letter maps to a description in these steps. – At the end of each description the default value is displayed in parentheses (). – Bolded values are variables that you might have to change. – You can apply the unbolded values in your environment if you follow the configuration that is described here. Values for callout letters a to c apply to Figure 2-6 on page 31. Table 2-1 Values for callout letters a to c a. Helm release name is the name for the helm release. Make sure that each helm release in the cluster has a unique name. Otherwise you get an error and you must redeploy the release to a different name. (nfsc) b. Target Namespace is the namespace where the helm release resources will be deployed. This chart requires the kube-system namespace if callout letter j Run as system-cluster-critical is selected. [This is the recommended option. It gives the provisioner priority over the pods that rely on it.] (kube-system) c. Target Cluster is the cluster that you are targeting with the deployment. (local-cluster). 30 Implementation Guide for IBM Blockchain Platform for Multicloud | manuals |
AMERICAS (INCLUDES AEGON USA AND AEGON CANADA) RESULTS Exchange rate translation negatively impacted the earnings reported in euro which is the currency of the financial statements. At constant currency exchange rates net income and income before tax increased by 30% and 29% respectively in 2003. Earnings per share for the full year amounted to EUR 1.15 an increase of 11% compared to EUR 1.04 for last year (adjusted for the 2002 stock dividend). Standardized life production increased by 3% to EUR 2 545 million which at constant currency exchange rates would have increased by 15%. The increase in standardized life production was driven by higher production in the Americas the United Kingdom and Other Countries in particular in Taiwan partly offset by lower production in the Netherlands. During 2003 indirect income of EUR 631 million pre-tax was included in earnings compared to EUR 758 million pre-tax in 2002. As announced earlier effective January 1 2004 AEGON discontinued the indirect income method for recognizing gains and losses on investments in shares and real estate. A generally accepted and recognized method has been adopted which is in accordance with International Financial Reporting Standards (IFRS) requirements and is similar to US GAAP. This method recognizes gains and losses on shares and real estate investments when realized. Income before tax of USD 1 740 million increased USD 598 million or 52% compared to 2002 primarily due to lower additions to the asset default provision (USD 258 million) lower accelerated amortization of deferred policy acquisition costs (DPAC) for variable annuities (USD 314 million) and lower additions to the provisions for guaranteed minimum benefits (GMBs) (USD 243 million). Income before tax also reflects the following one-time positive items: a non-recurring property insurance settlement benefit of USD 54 million a provision release of USD 36 million relating to real estate and interest on a tax refund for an amount of USD 34 million. Partially offsetting the income increases were lower employee pension plan income (USD 90 million) lower indirect investment income from shares and real estate investments (USD 135 million) and lower investment yields (USD 91 million) on the general account fixed income investments. Traditional life income before tax of USD 724 million in 2003 was 11% lower than in 2002 reflecting lower investment yields on fixed income investments less indirect investment income and a reduction in employee pension plan income. The one- time property insurance settlement benefit and a provision release described above partially offset these negative results. Fixed annuity income before tax of USD 378 million increased 129% compared to 2002. The favorable impact of lower credit losses in 2003 was partly offset by the decline in indirect investment income and lower product spreads compared to 2002. Crediting rates were lowered on both existing and new deposits throughout 2003 to improve product spreads. Fixed annuity account balances increased 7% to USD 45 billion during 2003 due to new sales and additional deposits on existing contracts. GICs and funding agreements income before tax declined 6% to USD 241 million due to lower indirect investment income (lower by USD 29 million) and interest rate spread compression. Lower additions to the default provision resulted AEGON GROUP ANNUAL REPORT 2003 23 Transamerica Finance Corporation (TFC) most of which was sold in line with our strategy to concentrate on life insurance pensions savings and investment products contributed EUR 218 million to net income during 2003 compared to EUR 51 million in 2002. The effective tax rate for 2003 was 27% compared to 19% in 2002. The lower effective tax rate in 2002 was largely due to a reduction of the deferred tax liability and favorable adjustments resulting from the filing of the 2001 corporate tax returns in the United States lower taxable income relative to preferred investments and tax-exempt income in the Netherlands and the United States and the use of tax losses in the United Kingdom. The following selected financial data should be read in conjunction with AEGON’s consolidated financial statements and the related notes to the financial statements of this annual report. The discussion of AEGON’s full year results for 2003 includes comparative information presented in USD for the results in the Americas and in GBP for the results in the United Kingdom which management believes is useful to investors because those businesses operate and are managed primarily in those currencies. INCOME BEFORE TAX Full year net income of EUR 1 793 million increased 16% compared to EUR 1 547 million in 2002. The largest influences on full year results were improved equity and credit markets as well as improved administrative operating efficiencies. INCOME BY 2003 2002 2003 2002 PRODUCT SEGMENT in in in in million million million million USD USD % EUR EUR % Traditional life 724 813 (11) 640 859 (25) Fixed annuities 378 165 129 334 174 92 GICs and funding agreements 241 257 (6) 213 272 (22) Life for account of policyholders 82 106 (23) 73 112 (35) Variable annuities 71 (437) 63 (462) — Fee business (19) 5 (17) 5 — LIFE INSURANCE 1 477 909 62 1 306 960 36 Accident and health insurance 263 233 13 232 246 (6) INCOME BEFORE TAX 1 740 1 142 52 1 538 1 206 28 Corporation tax (501) (226) 122 (443) (239) 85 NET INCOME 1 239 916 35 1 095 967 13 | financial_reports |
1111111111111111 IIIIII IIIII 1111111111 11111 lllll 111111111111111 lllll 111111111111111 11111111 US 20200268679Al c19) United States c12) Patent Application Publication PRUD’HOMME et al. c10) Pub. No.: US 2020/0268679 Al (43) Pub. Date: Aug. 27 2020 (54) HYDROPHOBIC ION PAIRING AND FLASH NANOPRECIPITATION FOR FORMATION OF CONTROLLED-RELEASE NANOCARRIER FORMULATIONS (71) Applicant: The Trustees of Princeton University Princeton NJ (US) (72) Inventors: Robert K. PRUD’HOMME Princeton NJ (US); Kurt D. RISTROPH Princeton NJ (US); Nathalie M. PINKERTON Princeton NJ (US); Hoang D. LU Princeton NJ (US); Paradorn RUMMANEETHORN Princeton NJ (US) (73) Assignee: The Trustees of Princeton University Princeton NJ (US) (21) Appl. No.: 16/761 140 (22) PCT Filed: Nov. 2 2018 (86) PCT No.: PCT /US2018/058869 § 371 (c)(l) (2) Date: May 1 2020 (60) Provisional application No. 62/581 394 filed on Nov. 3 2017. (51) Int. Cl. (52) U.S. Cl. CPC ........ A61K 915153 (2013.01); A61K 3117036 (2013.01); A61K 38112 (2013.01); A61K 38/10 (2013.01); A61K 915192 (2013.01); A61K 38/38 (2013.01); A61K 38147 (2013.01); A61K 915161 (2013.01); A61K 3115377 (2013.01) Related U.S. Application Data Publication Classification (57) ABSTRACT A61K 9151 A61K 3117036 A61K 38112 A61K 38/10 A61K 3115377 A61K 38/38 A61K 38147 (2006.01) (2006.01) (2006.01) (2006.01) (2006.01) (2006.01) (2006.01) Methods for encapsulating water-soluble biologic and small molecule active pharmaceutical ingredients (APis) into nanoparticles by applying nanoprecipitation techniques and ion-pairing the nanoparticles with hydrophobic counterions to produce new API salts that exhibit altered solubilities are presented. Pre»fnrrried ion paired .AP! Organic stream Water stream iorHpairoo APi complex amph!ph!Hc PCL"’b .PEG staomzer Organic stream .. Water stream @jfi ton- pak!ng @ 6 reagent o 0 @ •• . ~::1~1 $^{fifi }$ | patents |
Chapter 5 Improving Security Governance and Cloud Reliability In This Chapter Finding out Why Cloud Security Matters Security is top on the list of any IT manager who’s thinking about the cloud. Whether you’re looking at creating a private cloud leveraging a public cloud or implementing a hybrid environment you must have a security strategy. M any companies contemplating the addition of the cloud into their IT strategy are concerned about three key issues: security accountability and reliability. This chapter presents best practices that can help you improve security build a reliable and resilient environment and put proper controls in place to meet governance requirements. ▶ Understanding the nuances of cloud security ▶ Ensuring accountability through proper governance ▶ Establishing the right service delivery levels for your company ▶ Asking the right questions These materials are the copyright of John Wiley & Sons Inc. and any dissemination distribution or unauthorized use is strictly prohibited. | manuals |
CERTIFICATE OF AMENDMENT OF THE AMENDED AND RESTATED CERTIFICATE OF INCORPORATION OF LANDMARK BANCORP INC. EXHIBIT 3.2 Landmark Bancorp Inc. (hereinafter called the “Company”) a corporation organized and existing under and by virtue of the General Corporation Law of the State of Delaware does hereby certify that: 1. The name of the Company is: Landmark Bancorp Inc. 2. The first sentence of Article 4(A) of the Certificate of Incorporation of the Company is hereby replaced in its entirety and amended to read as follows: “A. CAPITAL STOCK. The total number of shares of stock which the corporation shall have authority to issue is Seven Million Five Hundred Thousand (7 500 000) shares of Common Stock par value of $0.01 per share and Two Hundred Thousand (200 000) shares of Preferred Stock par value of $0.01 per share.” 3. The amendment of the Amended and Restated Certificate of Incorporation herein certified has been duly adopted in accordance with the provisions of Section 242 of the General Corporation Law of the State of Delaware. Dated as of the 4$^{th}$ day of June 2008 By: /s/ Patrick L. Alexander Patrick L. Alexander President and Chief Executive Officer 108 LANDMARK BANCORP INC. | financial_reports |
December 31 2012 2011 2010 Total Primary Insurance Prime Number of insured loans. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 667 622 610 438 626 344 Number of loans in default. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60 854 71 546 77 931 Percentage of total loans in default . . . . . . . . . . . . . . . . . . . . . . . . . . 9.12% 11.72% 12.44% Alt-A Number of insured loans. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 069 62 839 71 999 Number of loans in default. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 005 20 044 24 569 Percentage of total loans in default . . . . . . . . . . . . . . . . . . . . . . . . . . 29.60% 31.90% 34.12% A minus and below Number of insured loans. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49 307 56 361 63 760 Number of loans in default. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 310 19 271 22 970 Percentage of loans in default . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33.08% 34.19% 36.03% Total Primary Number of insured loans. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 770 998 729 638 762 103 Number of loans in default. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 169 110 861 125 470 Percentage of loans in default . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.08% 15.19% 16.46% Default Statistics—Pool Insurance: Number of loans in default. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 147 21 685 32 456 Year Ended December 31 2012 2011 2010 Beginning default inventory. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110 861 125 470 151 998 Plus: New defaults (1). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 517 94 817 115 360 Less: Cures (1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61 906 77 997 100 166 Less: Claims paid (2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 933 24 479 25 765 Less: Rescissions (3). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 433 4 852 4 440 Less: Denials (4) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 937 2 098 2 763 Less: Terminations of transactions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . — — 8 754 Ending default inventory. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 169 110 861 125 470 The following table shows a rollforward of our primary loans in default: __________________ (1) Amounts reflected are compiled on a monthly basis consistent with reports received from loan servicers. The number of new defaults and cures presented includes the following number of monthly defaults that defaulted and cured within the periods indicated: (2) Includes those charged to a deductible or captive. (3) Net of any previously rescinded policies or denied claims that were reinstated during the period. Such reinstated rescissions may ultimately result in a paid claim while any previously denied claims are generally reviewed for possible rescission prior to any claim payment. (4) Net of any denied claims that were reinstated during the period. Such previously denied but reinstated claims are generally reviewed for possible rescission prior to any claim payment. A significant number of denials in 2012 relate to one servicer. 109 Year Ended December 31 2012 2011 2010 Intra-period new defaults. . . . . . . . . . . . . . . . . . . . . . 42 159 53 103 67 276 | financial_reports |
of Kitty Hawk North Carolina. [Figure 1-4] The Wrights developed a series of gliders while experimenting with aerodynamics which was crucial to developing a workable control system. Many historians and most importantly the Wrights themselves pointed out that their game plan was to learn flight control and become pilots specifically by soaring whereas all the other experimenters rushed to add power without refining flight control. By 1903 Orville and Wilbur Wright had achieved powered flight of just over a minute by putting an engine on their best glider design. Wolfgang Klemperer broke the Wright Brothers 1911 soaring duration record with a flight of 13 minutes using ridge lift. In 1928 Austrian Robert Kronfeld proved that thermal lift could be used by a sailplane to gain altitude by making a short out and return flight. In 1929 the National Glider Association was founded in Detroit Michigan; by 1930 the first USA National Glider Contest was held in Elmira New York. In 1937 the first World Championships were held at the Wasserkuppe in Germany. By the 1950s soaring was developing rapidly with the first American Dr. Paul MacCready Jr. taking part in a World Soaring Championships held in Sweden. Subsequently Dr. MacCready went on to become the first American to win a World Soaring Championship in 1956 in France. The period of the 1960s and 1980s found soaring growing rapidly. During this period there was also a revival of hang gliders and ultralight aircraft as new materials and a better understanding of low-speed aerodynamics made new designs possible. By the late 1990s aviation had become commonplace with jet travel becoming critical to the world economy. Soaring had grown into a diverse and interesting sport. Modern high performance gliders are made from composite materials and take advantage of highly refined aerodynamics and control systems. Today soaring pilots use sophisticated instrumentation including global positioning system (GPS) and altitude information (variometer) integrated into electronic glide computers to go farther faster and higher than ever before. The Federal Aviation Administration (FAA) defines a glider as a heavier-than-air aircraft that is supported in flight by the dynamic reaction of the air against its lifting surfaces and whose free flight does not depend principally on an engine. [Figure 1-5] The term “glider” is used to designate the rating By 1906 the sport of gliding was progressing rapidly. An American glider meet was sponsored by the Aero Club of America on Long Island New York. By 1911 Orville Wright had set a world duration record of flying his motorless craft for 9 minutes and 45 seconds. By 1920 the sport of soaring was coming into its own. Glider design was spurred on by developments in Germany where the World War I Treaty of Versailles banned flying power aircraft. New forms of lift were discovered that made it possible to gain altitude and travel distances using these previously unknown atmospheric resources. In 1921 Dr. Figure 1-4. Orville Wright (left) and Dan Tate (right) launching the Wright 1902 glider off the east slope of the Big Hill Kill Devil Hills North Carolina on October 17 1902. Wilbur Wright is flying the glider. Figure 1-3. Otto Lilienthal in flight. Figure 1-5. A Schleicher ASK 21 glider. Glider or Sailplane? 1-3 | laws_and_regulations |
4 Structuring for Future Growth Our collaboration has led to better more cost-efficient product launches a successful move of our corporate head- quarters to Auburn Hills Michigan an effective acquisition process and unprecedented quality and workplace safety results. In addition we are leveraging our infrastructure within the Engine and Drivetrain groups on two Korean campuses and a single manufacturing campus in China. Over the past few years we have been building a robust and disciplined cost reduction process. This process touches all aspects of our business and was the reason we could manage through a situation as daunting as steep increases “ I have challenged our people to broaden the competitive gap between us and other suppliers in three key areas. These are qualit y and cost improvement the use of electronic controls strategies and harnessing the power of collaboration and teamwork – all with a focus on our vision of Product Leadership.” in steel and other raw materials costs in 2004. We operate in a very cost-competitive environment and must continually adjust our cost structure to the realities of our marketplace. We have made progress in harnessing our expertise in mechanical functioning of engines and torque management through software controls strategies. This expertise is a major differentiator between BorgWarner and our competi- tors for most of our product lines. Computer control is the “brainpower” of the powertrain and is the critical element of new engine and drivetrain campuses in Korea and in China at our recently opened office in Shanghai and expanding Ningbo manufacturing compound we are sharing space and support services. In the past we would have established individual operations by product line. Our new business model is reaching beyond emerging market opportunities to the rest of our business. We want to preserve the best of our entrepreneurial heritage while taking advantage of the benefits of common systems and prices and shifting market shares among our customers. At BorgWarner we will continue to manage through these issues with a focus on delivering the results our stockholders have come to expect. Timothy M. Manganello Chairman and CEO We are also focused on structuring ourselves for global growth. There is a difference between operating in multiple countries and being a truly global company. We realize that we must operate differently than we have in the past. Good examples are our expansions in China and Korea. At our powertrains of the future. BorgWarner knows more about powertrains than any other supplier but we need to make sure we are leveraging that expertise where it counts. Our acquisition of Beru shares will help us advance in this area. processes including information technology and supply chain management. This report looks at those qualities that bring us together as BorgWarner people and that differentiate us from others in the industry: our continuing ability to supply innovative tech- nology; our diversity – both in terms of our customer base and our geographic presence; our manufacturing excellence; and our financial discipline. The auto industry expects to face another challenging year in 2005 with uncertainty about production high commodity BorgWarner Vision BorgWarner Beliefs GLYPH<127> Respect for Each Other GLYPH<127> The Power of Collaboration GLYPH<127> Passion for Excellence GLYPH<127> Personal Integrity GLYPH<127> Responsibility to Our Communities BorgWarner is the recognized world leader in advanced products and technologies that satisfy customer needs in powertrain components and systems solutions. 77] If 7 5 “Our strategic focus proves beneficial as market shares among the global automakers shift in favor of our faster growing customers.” G LO B A L | financial_reports |
Replication and Binary Logging Options and Variables regard to the logging format in effect so the following statement-based rules for --binlog-ignore-db always apply in determining whether or not the statement is logged. Statement-based logging. Tells the server to not log any statement where the default database (that is the one selected by USE ) is db_name . When there is no default database no --binlog-ignore-db options are applied and such statements are always logged. (Bug #11829838 Bug #60188) Row-based format. Tells the server not to log updates to any tables in the database db_name . The current database has no effect. When using statement-based logging the following example does not work as you might expect. Suppose that the server is started with --binlog-ignore-db=sales and you issue the following statements: The UPDATE statement is logged in such a case because --binlog-ignore-db applies only to the default database (determined by the USE statement). Because the sales database was specified explicitly in the statement the statement has not been filtered. However when using row-based logging the UPDATE statement’s effects are not written to the binary log which means that no changes to the sales.january table are logged; in this instance --binlog-ignore-db=sales causes all changes made to tables in the source’s copy of the sales database to be ignored for purposes of binary logging. To specify more than one database to ignore use this option multiple times once for each database. Because database names can contain commas the list is treated as the name of a single database if you supply a comma-separated list. You should not use this option if you are using cross-database updates and you do not want these updates to be logged. Checksum options. MySQL supports reading and writing of binary log checksums. These are enabled using the two options listed here: Enabling this option causes the source to write checksums for events written to the binary log. Set to NONE to disable or the name of the algorithm to be used for generating checksums; currently only CRC32 checksums are supported and CRC32 is the default. You cannot change the setting for this option within a transaction. To control reading of checksums by the replica (from the relay log) use the --slave-sql-verify- checksum option. Testing and debugging options. The following binary log options are used in replication testing and debugging. They are not intended for use in normal operations. 3545 • --binlog-checksum={NONE|CRC32} USE prices; UPDATE sales.january SET amount=amount+1000; Command-Line Format --binlog-checksum=type Type String Default Value CRC32 Valid Values NONE CRC32 | manuals |
the bulk bands for an inverse of the phonon mass of 0.015 f is shown in Fig. 6(a) where the magnetic resonance is lower than the dielectric resonance. The effects of a magnetic resonance above the dielectric resonance with 0.009 f are shown in Fig. 6(b). Only band overlap and intersections are affected. Note a consequence of this for the surface modes. In the case where the magnetic resonance is below the dielectric resonance have a broader range in wavevector (see Fig. 6(a)) compared to the case where the magnetic resonance is above the dielectric resonance (in Fig. 6(b)). Dispersion relations for a material having linear magnetoelectric coupling have been cal- culated for tranverse electric polariton modes. Effects associated with spin canting are considered. The polarisation and weak ferromagnetism are parallel to the surface and the antiferromagnet magnetisations are out of plane. We find surface modes associated with the weak ferromagnetism that are non-reciprocal with respect to propagation direction such that ω ( ⃗ k ) = ω ( − ⃗ k ). For sufficiently large magnetic fields or different material parameters surface modes may also exist in the magnetostatic region with k ≫ ω/c . Application of static magnetic field can be used to modify the middle bulk band frequencies We wish to acknowledge the support of Ausaid the Australian Research Council and DEST. ACKNOWLEDGMENTS V. CONCLUSIONS 15 [1] R. E. Camley and D. L. Mills Phys. Rev. 26 1280 (1982). [2] K. Welford Opt Quant. Elec. 23 1 (1991). [3] G. Cairns D. McNeill and P. Dawson Surf. Sci. 429 117 (1999). [4] F. KeilMann J. Micros. 194 567 (1999). [5] V. N. Konopsky and E. V. Alieva Phys. Rev. Let 97 253904 (2006). [6] R. W. Damon and J. R. Esbach J. Phys. Chem. Solids. 19 308 (1961). | scientific_articles |
0.1 0.2 0.3 0.4 0.2 0.3 0.4 0.5 T * FIG. 10: Cascade of water-like anomalies in the density-temperature plane. The solid line lim its the region of density anomaly the dashed line illustrates the region of diffusion anomaly and the dot-dashed line shows the region of structural anomaly. The filled circles represent the density of minimum and maximum s$_{2}$ and the stars represent the region of minimum and maximum F$_{im}$ . We demonstrate that the diffusivity and the excess entropy of a core-softened fluid with isotropic pair interactions obey Rosenfeld-type excess entropy scaling of transport properties. The use of macroscopic reduction parameters for the diffusivity based on temperature and density is particularly appropriate for fluids with multiple length scales where defining an effective hard-sphere radius is inappropriate. We also show that the substituting the excess entropy by the pair correlation entropy leads to a weak isochore dependence of the Rosenfeld- scaling parameters not seen in simple liquids but observed in other water-like liquids. 66 The instantaneous normal mode spectra including the Einstein frequency and the fraction of imaginary modes is computed over a wide range of temperatures and densities. INM analysis is shown to provide unexpected insights into the dynamical consequences of the interplay between length scales characteristic of anomalous fluids that cannot be obtained from an equilibrium transport property such as the diffusivity. Both the real and imaginary branches of the INM spectra exhibit bimodality that has so far not been observed. As a function of density along an isotherm the bimodality in the real branch of the INM spectrum persists to very high densities well beyond the structurally 17 | scientific_articles |
General Information (Section 1) Preliminary Pages Operating Limitations (Section 2) Instrument Markings Airspeed Limitations ROBINSON R22 R OTORCRAFT FLIGHT MANUAL Figure 5-1. The RFM is a regulatory document in terms of the maneuvers procedures and operating limitations described therein. 5-2 However if “Pilot’s Operating Handbook” is used as the main title instead of “Rotorcraft Flight Manual ” a statement must be included on the title page indicating that the document is the Federal Aviation Administration (FAA) approved Rotorcraft Flight Manual (RFM). [Figure 5-1] The general information section provides the basic descriptive information on the rotorcraft and the powerplant. In some manuals there is a three-view drawing of the rotorcraft that provides the dimensions of various components including the overall length and width and the diameter of the rotor systems. This is a good place for pilots to quickly familiarize themselves with the aircraft. Pilots need to be aware of the dimensions of the helicopter since they often must decide the suitability of an operations area for themselves as well as hanger space landing pad and ground handling needs. Not including the preliminary pages an FAA-approved RFM may contain as many as ten sections. These sections are: General Information; Operating Limitations; Emergency Procedures; Normal Procedures; Performance; Weight and Balance; Aircraft and Systems Description; Handling Servicing and Maintenance Supplements; and Safety and Operational Tips. Manufacturers have the option of including a tenth section on safety and operational tips and an alphabetical index at the end of the handbook. Pilots can find definitions abbreviations explanations of symbology and some of the terminology used in the manual at the end of this section. At the option of the manufacturer metric and other conversion tables may also be included. While RFMs may appear similar for the same make and model of aircraft each flight manual is unique since it contains specific information about a particular aircraft such as the equipment installed and weight and balance information. Therefore manufacturers are required to include the serial number and registration on the title page to identify the aircraft to which the flight manual belongs. If a flight manual does not indicate a specific aircraft registration and serial number it is limited to general study purposes only. The operating limitations section contains only those limitations required by regulation or that are necessary for the safe operation of the rotorcraft powerplant systems and equipment. It includes operating limitations instrument markings color coding and basic placards. Some of the areas included are: airspeed altitude rotor and powerplant limitations including fuel and oil requirements; weight and loading distribution; and flight limitations. Most manufacturers include a table of contents which identifies the order of the entire manual by section number and title. In addition some helicopters may include a log of changes or a revision page to track changes to the manual. Usually each section also contains its own table of contents. Page numbers reflect the section being read 1-1 2-1 3-1 and so on. If the flight manual is published in looseleaf form each section is usually marked with a divider tab indicating the section number or title or both. The emergency procedures section may have a red tab for quick identification and reference. Instrument markings may include but are not limited to green red and yellow ranges for the safe operation of the aircraft. The green marking indicates a range of continuous operation. The red range indicates the maximum or minimum operation allowed while the yellow range indicates a caution or transition area. Airspeed limitations are shown on the airspeed indicator by color coding and on placards or graphs in the aircraft. A red line on the airspeed indicator shows the airspeed limit beyond which structural damage could occur. This is called the never exceed speed or V$_{NE}$. The normal operating speed range is depicted by a green arc. A blue or a red cross-hatched line is sometimes added to show the maximum autorotation speed. [Figure 5-2] Other airspeed limitations may be included in this section of the RFM. Examples include reduced V$_{NE}$ when doors are removed maximum airspeed for level flight with maximum continuous power (V$_{H}$) or restrictions when carrying an external load. Pilots need to understand and adhere to all airspeed limitations appropriate to the make model and configuration of the helicopter being flown. | laws_and_regulations |
Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de (3) Mit Antragstellung ist nachzuweisen dass der Referenzfilm die jeweils geltenden Voraussetzungen der §§ 41 bis 48 erfüllt. Sofern Mittel zur Kapitalaufstockung verwendet werden sollen muss die antragstellende Person dem Antrag nachprüfbare Unterlagen über den wirtschaftlichen Zustand ihres Unternehmens beifügen. (1) Die Förderhilfen werden in den ersten drei Monaten nach dem Schluss eines Kalenderjahres den Herstellern der Referenzfilme durch Bescheid zuerkannt die im abgelaufenen Kalenderjahr die Voraussetzungen für die Zuerkennung nachgewiesen haben. Dem Grunde nach kann die Zuerkennung schon vorher erfolgen. (2) Steht dem Grunde nach fest dass ein Film eine hinreichende Referenzpunktzahl erreicht hat kann der Vorstand nach Maßgabe der Haushaltslage der Filmförderungsanstalt bis zu 70 Prozent des Referenzwertes des Vorjahres vorab zuerkennen. (3) Für den Bescheid über die Zuerkennung der Förderhilfen gilt § 67 Absatz 1 in Verbindung mit Absatz 10 für den Referenzfilm entsprechend. Der Bescheid ist zudem mit Auflagen zu verbinden um sicherzustellen dass für den Fall dass die Förderhilfe zur Herstellung eines neuen programmfüllenden Films verwendet wird der neue Film den jeweils geltenden Voraussetzungen der §§ 41 bis 48 sowie den Voraussetzungen des § 67 Absatz 2 bis 11 entspricht. Die antragstellende Person kann die Erfüllung der Voraussetzungen nach § 67 Absatz 2 bis 11 bis zur Auszahlung der Förderhilfe nachholen. (+++ § 83 Abs. 1 u. 2: zur Anwendung vgl. § 129 +++) (1) Der Hersteller hat die Förderhilfen spätestens bis zum Ablauf von drei Jahren nach Erlass des jeweiligen Zuerkennungsbescheids vorrangig für die Herstellung neuer programmfüllender Filme im Sinne der §§ 41 bis 48 zu verwenden. Die §§ 63 und 64 gelten entsprechend. (2) Ist der Betrag für eine internationale Koproduktion zuerkannt worden bei der die Beteiligung des Herstellers nach § 41 Absatz 1 Nummer 1 nach § 42 weniger als 50 Prozent betragen hat so darf der Betrag nur für die Finanzierung eines Films verwendet werden an dem die Beteiligung des Herstellers nach § 41 Absatz 1 Nummer 1 nach § 42 mindestens 50 Prozent beträgt oder größer ist als die Beteiligung jedes anderen Koproduzenten. (1) Der Vorstand kann auf Antrag des Herstellers im Sinne des § 41 Absatz 1 Nummer 1 gestatten dass die nach § 73 oder § 76 zuerkannten Förderhilfen bis zu 75 Prozent in jedem Fall aber bis zu 100 000 Euro für besonders aufwendige Maßnahmen der Stoffbeschaffung der Drehbuchbeschaffung oder -entwicklung oder in sonstiger Weise für die Vorbereitung eines neuen programmfüllenden Films im Sinne der §§ 41 bis 48 verwendet werden. (2) Der Vorstand kann auf Antrag des Herstellers im Sinne des § 41 Absatz 1 Nummer 1 auch gestatten dass bis zu 75 Prozent der nach § 73 oder § 76 zuerkannten Förderhilfen insgesamt jedoch für dasselbe Unternehmen in einem Zeitraum von fünf Jahren nicht mehr als 500 000 Euro im Interesse der Strukturverbesserung des Unternehmens des Herstellers für eine nicht nur kurzfristige Aufstockung des Eigenkapitals verwendet werden. Werden die Förderhilfen für die Herstellung neuer Filme nach § 84 verwendet können sie auch für bereits begonnene Maßnahmen verwendet werden. Dies gilt nicht wenn die Maßnahme vor dem Antrag auf Zuerkennung nach § 82 Absatz 2 begonnen wurde. Eine Verwendung der Förderhilfen für bereits abgeschlossene Maßnahmen ist nicht möglich. § 65 gilt im Rahmen der Referenzfilmförderung entsprechend. (1) Die Filmförderungsanstalt zahlt die Förderhilfen nach den §§ 73 und 76 bedarfsgerecht in bis zu drei Raten an die antragstellende Person aus sobald nachgewiesen ist dass die Förderhilfen eine den Bestimmungen § 88 Auszahlung § 87 Begonnene Maßnahmen § 86 Bürgschaften - Seite 34 von 56 - § 83 Zuerkennung Fußnote § 84 Verwendung § 85 Besondere Verwendungsmöglichkeiten | laws_and_regulations |
Exercices terminés les 31 mars 1. Principales conventions comptables Recours à des estimations États financiers consolidés Stocks Immobilisations Écarts d’acquisition Impôts sur les bénéfices Rémunération à base d’actions (en milliers de dollars) Les états financiers ont été dressés selon les principes comptables généralement reconnus utilisés du Canada et tiennent compte des principales conventions comptables suivantes : Dans le cadre de la préparation des états financiers conformément aux principes comptables généralement recon- nus la direction doit procéder à des estimations et poser des hypothèses qui influent sur les montants déclarés des actifs et passifs ainsi que sur la présentation des actifs et des passifs éventuels à la date des états financiers et sur les montants des revenus et charges de l’exercice. Les résultats réels peuvent différer des estimations. Les états financiers consolidés comprennent les comptes de Saputo Inc. et de toutes ses filiales (la « Société »). Les résultats d’exploitation des entreprises acquises sont inclus aux états consolidés des résultats depuis leurs dates respectives d’acquisition. Les stocks de produits finis et de produits en cours sont évalués au moindre du coût moyen et de la valeur de réalisation nette. Les stocks de matières premières sont évalués au moindre du coût et de la valeur de remplacement. Le coût est déterminé selon la méthode de l’épuisement successif. Les immobilisations sont comptabilisées au coût et sont amorties de façon linéaire sur les durées suivantes ou en utilisant les méthodes suivantes : Les écarts d’acquisition ne sont plus amortis depuis le 1 er avril 2001 date à laquelle la Société a adopté de manière prospective les nouvelles recommandations de l’Institut Canadien des Comptables Agréés (ICCA) relativement aux écarts d’acquisition pour adopter le test de dépréciation prévu en vertu des nouvelles règles (voir la note 2). La Société suit la méthode du passif fiscal. Selon cette méthode les actifs d’impôts futurs et les passifs d’impôts futurs sont établis en fonction des écarts entre la valeur comptable et la valeur fiscale de l’actif et du passif et sont mesurés par application des taux d’imposition en vigueur au moment où ces écarts se résorberont. La Société a instauré un régime d’options d’achat d’actions visant l’achat d’actions ordinaires par des employés clés des dirigeants et des administrateurs de la Société. La méthode de la valeur intrinsèque est utilisée pour la comptabilisation des attributions à base d’actions et aucune charge n’est donc constatée à l’égard de ce régime lorsque des options sont octroyées. La contrepartie payée lors de l’exercice des options est créditée au capital-actions. 40 • 41 Bâtisses 15 ans à 40 ans Mobilier et équipement machinerie et outillage 3 ans à 15 ans Matériel roulant 5 ans à 10 ans ou en fonction du kilométrage parcouru Notes afférentes aux états financiers consolidés | financial_reports |
PART I ITEM 1A Risk Factors The future performance of Cigna’s business will depend in large part on Cigna’s ability to effectively implement and execute its strategic and operational initiatives that include: (1) driving growth in targeted geographies product lines buying segments and distribution channels; (2) improving its strategic and financial flexibility; and (3) pursuing additional opportunities in high-growth markets with particular focus on individuals. Successful execution of these strategic and operational initiatives depends on a number of factors including: If these initiatives fail or are not executed effectively it could harm the Company’s consolidated financial position and results of operations. For example reducing operating expenses while maintaining the necessary resources and the Company’s talent pool is important to the Company and if not managed effectively could have long-term effects on the business such as failure to maintain or improve the quality of its products and limiting its ability to retain or hire key personnel. In addition to succeed the Company must align its organization to its strategy. Cigna must effectively integrate its operations including its most recently acquired businesses actively work to ensure consistency throughout the organization and promote a global mind-set and a focus on individual customers. If the Company fails to do so it may be unable to grow as planned or the result of expansion may be unsatisfactory. Also the current competitive economic and regulatory environment will require Cigna’s organization to adapt rapidly and nimbly to new opportunities and challenges. The Company will be unable to do so if it does not make important decisions quickly define its appetite for risk specifically implement new governance managerial and These factors may increase in importance as Cigna continues to expand globally and any one of these challenges could negatively affect the Company’s operations or its long-term growth. Currently South Korea is the single largest geographic market in Cigna’s Global As a global company Cigna’s business is increasingly exposed to risks inherent in foreign operations. These risks which can vary substantially by market include political legal operational regulatory economic and other risks including government intervention and censorship that the Company does not face in its U.S. operations. The global nature of Cigna’s business and operations presents challenges including but not limited to those arising from: organizational processes smoothly and communicate roles and responsibilities clearly. Business Risks Future performance of Cigna’s business will depend on the Company’s ability to execute on its strategic and operational initiatives effectively. As a global company Cigna faces political legal operational regulatory economic and other risks that present challenges and could negatively affect its multinational operations or the Company’s long-term growth. CIGNA CORPORATION - 2012 Form 10-K 21 differentiating Cigna’s products and services from those of its competitors by leveraging its health advocacy capabilities and other strengths in targeted markets geographies and buyer segments; GLYPH<127> developing and introducing new products or programs particularly in response to government regulation and the increased focus on consumer directed products; GLYPH<127> identifying and introducing the proper mix or integration of products that will be accepted by the marketplace; GLYPH<127> attracting and retaining sufficient numbers of qualified employees; GLYPH<127> attracting and engaging a sufficient number of qualified partners including physicians partners in an environment with a growing shortage of primary care physicians; GLYPH<127> effectively managing balance sheet exposures including the Company’s pension funding obligation; GLYPH<127> improving medical cost competitiveness in targeted markets; and GLYPH<127> reducing Cigna HealthCare’s medical operating expenses to achieve sustainable benefits. GLYPH<127> general economic and political conditions. GLYPH<127> political instability or acts of war terrorism natural disasters pandemics in locations where Cigna operates; and GLYPH<127> the need to provide sufficient levels of technical support in different locations; GLYPH<127> challenges associated with managing more geographically diverse operations and projects; GLYPH<127> risk associated with managing Cigna’s partner relationships in accordance with business objectives in countries where our foreign businesses voluntarily operate or are required to operate with local business partners; GLYPH<127> reliance on local sales forces for some of its operations in countries that may have labor problems and less flexible employee relationships that can be difficult and expensive to terminate or where changes in local regulation or law may disrupt the business operations; GLYPH<127> foreign currency exchange rates and fluctuations that may have an impact on the future costs or on future sales and cash flows from the Company’s international operations and any measures that it may implement to reduce the effect of volatile currencies and other risks of its international operations may not be effective; GLYPH<127> varying regional and geopolitical business conditions and demands; GLYPH<127> discriminatory regulation nationalization or expropriation of assets; GLYPH<127> price controls or other pricing issues and exchange controls or other restrictions that prevent it from transferring funds from these operations out of the countries in which it operates or converting local currencies that our foreign operations hold into U.S. dollars or other currencies; GLYPH<127> | financial_reports |
Europol Public Information accordance with the requirements stated in the Tender Specifications. Personal data relating to Europol staff obtained during the performance of this Framework Contract shall be processed only in accordance with the requirements set by the Data controller and in accordance with the applicable data protection legislation. If requested by Europol in writing the Contractor shall provide additional information and/or evidence with regard to processing of Europol staff Personal data at the required standards 24 . Where the basis for the transfer is (b) or (c) the Parties shall cooperate in good faith to agree any updated wording required in light of best practice or as a result of standard contractual clauses updated by implementing decision of the European Commission for the transfer of Personal data to third countries (excluding EEA countries for this purpose). 24 If the Contractor is situated outside the EU as established in the Special Conditions those standards refer to the compliance with the relevant provisions governing the exchange of Personal data with parties outside the EU. Page 48 of 79 Europol’s initials: Contractor’s initials: ii. prevent the unauthorised reading copying modification or removal of data media (data media control); i. deny unauthorised persons access to data-processing equipment used for processing Personal data (equipment access control); 6. In relation to any Personal data which the Contractor requires to store and use for the performance of its contractual obligations the agrees to provide sufficient guarantees that appropriate technical and organisational measures are implemented so that processing meets the requirements of the applicable data protection legislation and ensures the protection of the rights of the data subject. In respect of automated data processing the Contractor shall implement measures designed to protect Personal data against accidental or unlawful destruction accidental loss or unauthorised disclosure alteration and access or any other unauthorised form of processing. The Contractor shall have due regard to the risks inherent to the processing and to the nature of such data in order to: 5. The Contractor shall grant its personnel access to Europol Personal data to the extent strictly necessary for the implementation management and monitoring of the FWC. The Contractor must ensure that personnel authorised to process personal data have committed to confidentiality or are under appropriate statutory obligations of confidentiality in accordance with the provisions of Article II-15 of the FWC. (c) a case-by-case assessment that will ensure respect for Europol’s obligations under its Regulation and under EU data protection legislation and in relation to which the particular contractual provisions are provided for either in the Special Conditions the Specific Contract or in the Purchase Order . (b) valid European Commission's standard contractual clauses for data protection adopted by implementing decision if the European Commission has not adopted an adequacy decision for the third country outside the EU or (a) an applicable European Commission's adequacy decision or 4. (i) When the Special Conditions (or exceptionally the provisions of a particular Purchase Order or Specific Contract placed under this Framework Contract) foresee the transfer of Personal data to a third country outside of the EU or of the EEA the parties acknowledge that this will be done on the basis of: | government_tenders |
(k) any payment made under the National Health Service (Scotland) (Injury Benefits) Regulations 1998( a ) the Health and Personal Social Services (Injury Benefits) Regulations (Northern Ireland) 2001( b ) or the National Health Service (Injury Benefits) Regulations 1995( c ); (l) any benefit that is equivalent or substantially similar to those listed in sub-paragraphs (a)- (k) above (including benefits awarded under the legislation of another country or dependent territory). (a) a person is determined to be entitled to victims’ payments in respect of disablement suffered by that person or another person but (b) compensation has previously been paid to the person so entitled in respect of that disablement and (c) the compensation referred to in sub-paragraph (b) exceeds the amount of exempted compensation. (a) in proceedings on a claim (b) in settlement of a claim (whether or not proceedings on the claim were brought before a court) or (c) under a scheme established under a statutory provision. (a) the amount of compensation referred to in sub-paragraph (b) which is in excess of the amount of exempted compensation; (b) the period of time since any such compensation was paid and (c) any other factor the Board considers relevant. (a) the number of weeks since the relevant incident and (b) the appropriate rate. (a) beginning with the date of the relevant incident and (b) ending with the date of the determination of the person’s entitlement to victims’ payments. Adjustment in respect of past compensation 20. —(1) This regulation applies in a case where— (2) The reference in paragraph (1)(b) to the payment of compensation is a reference to the payment of compensation— (3) The Board may to the extent that Board considers appropriate adjust the amount of victims’ payments payable to the person in respect of the amount compensation mentioned in paragraph (1)(b) which is in excess of the amount of exempted compensation. (4) In considering whether and to what extent to exercise the power in paragraph (3) the Board must have regard in particular to — (5) The exempted amount of compensation is calculated by taking the following three steps. (6) The first step is to calculate the amount a person would have received had they been entitled to victims’ payments from the date of the relevant incident by multiplying together— (7) The second step is to adjust the amount calculated under step 1 for inflation using the ratio published by the Treasury and known as the Gross Domestic Product deflator by reference to the period— (8) The third step is to further adjust the amount calculated under step 1 to reflect the time value of money with reference to the Bank of England base rate. ( a ) 1998 No. 1594 (S. 84). ( b ) S.R. 2001 No. 365. ( c ) S.I. 1995/866. 14 | laws_and_regulations |
When the emergency is over (or the CBU test is complete) the system must be returned to its original configuration. The CBU features can be deactivated at any time before the expiration date. Failure to deactivate the CBU feature before the expiration date can cause the system to downgrade resources gracefully to the original configuration. The system does not deactivate dedicated engines or the last of in-use shared engines. Planning: CBU for processors provides a concurrent upgrade. This upgrade can result in more enabled processors changed capacity settings that are available to a system configuration or both. You can activate a subset of the CBU features that are ordered for the system. Therefore more planning and tasks are required for nondisruptive logical upgrades. For more information see “Guidelines to avoid disruptive upgrades” on page 360. For more information see the IBM Z Capacity on Demand User’s Guide SC28-6846. The activation and deactivation of the CBU function is your responsibility and does not require the onsite presence of IBM SSRs. The CBU function is activated or deactivated concurrently from the HMC by using the API. On the SE CBU is activated by using the Perform Model Conversion task or through the API. The API enables task automation. CBU is activated from the SE by using the HMC and SSO to the SE by using the Perform Model Conversion task or through automation by using the API on the SE or the HMC. During a real disaster use the Activate CBU option to activate the 90-day period. After CBU activation the z14 server can have more capacity more active PUs or both. The extra resources go into the resource pools and are available to the LPARs. If the LPARs must increase their share of the resources the LPAR weight can be changed or the number of logical processors can be concurrently increased by configuring reserved processors online. The operating system must concurrently configure more processors online. If necessary more LPARs can be created to use the newly added capacity. To deactivate the CBU the extra resources must be released from the LPARs by the operating systems. In some cases this process is a matter of varying the resources offline. In other cases it can mean shutting down operating systems or deactivating LPARs. After the resources are released the same facility on the HMC/SE is used to turn off CBU. To deactivate CBU select the Undo temporary upgrade option from the Perform Model Conversion task on the SE. Test CBUs are provided as part of the CBU contract. CBU is activated from the SE by using the Perform Model Conversion task. Select the test option to start a 10-day test period. A standard contract allows one test per CBU year. However you can order more tests in increments of one up to a maximum of 15 for each CBU order. 354 IBM z14 (3906) Technical Guide CBU testing CBU deactivation Image upgrades CBU activation 8.7.2 CBU activation and deactivation | manuals |
flat universes. However there is also an alternative interpretation when we restrict our attention to the thick-line rectangle of Fig.1. In fact we realize that the upper tunnel (the strip where in the Reissner-Nordstr¨ om case we would expect to have the central singularity) is a copy of the lower tunnel. This suggests that we might identify the two tunnels. If we do that the manifold becomes finite and cyclic in the timelike coordinate. In the extreme case M = M$_{0}$ the metric (2) becomes where φ is a differentiable and not vanishing function in the interval [0 ∞ ). In order to derive the maximal extension we shall follow the procedure adopted in [20]. To this purpose we consider the surface { ϑ = const ϕ = const } and we write (28) as follows: By introducing null coordinates p and q defined as our metric becomes where now r is a function of p and q . It is worth mentioning that the surface { r = r$_{0}$ ϑ = const ϕ = const } is made of radial null geodesics corresponding to lines parallel to p = const and q = const in the ( p q )-plane. The metric (31) is regular for all real values of p and q . In order to understand where the coordinate singularity r$_{0}$ lies in the ( p q )-plane we need to study the signs of φ ( r$_{0}$ ) and φ $^{′}$( r$_{0}$ ). First of all notice that 13 φ ( r$_{0}$ ) = 1 2 g ′′ $_{00}$( r$_{0}$ ) φ $^{′}$( r$_{0}$ ) = 1 6 g ′′′ $_{00}$( r$_{0}$ ) ds 2 = ( r − r$_{0}$ ) $^{2}$φ ( r ) dp dq − r $^{2}$dϑ2 − r $^{2}$sin2 ϑ dϕ 2 (31) r ∗ := ∫ dr ( r − r$_{0}$ ) $^{2}$φ ( r ) = − 1 ( r − r$_{0}$ ) φ ( r$_{0}$ ) − φ $^{′}$( r$_{0}$ ) φ $^{2}$( r$_{0}$ ) ln ( r − r$_{0}$ ) + O ( r − r$_{0}$ ) (30) p := t + r $^{∗}$ q := t − r $^{∗}$ ds 2 = ( r − r$_{0}$ ) $^{2}$φ ( r ) [ dt − dr ( r − r$_{0}$ ) $^{2}$φ ( r ) ] [ dt + dr ( r − r$_{0}$ ) $^{2}$φ ( r ) ] (29) ds 2 = ( r − r$_{0}$ ) $^{2}$φ ( r ) dt 2 − dr 2 ( r − r$_{0}$ ) $^{2}$φ ( r ) − r $^{2}$dϑ2 − r $^{2}$sin2 ϑ dϕ 2 (28) VI. THE EXTREME CASE | scientific_articles |
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<s46>GLYPH<s56> GLYPH<s49>GLYPH<s46>GLYPH<s48> GLYPH<s49>GLYPH<s46>GLYPH<s50> GLYPH<s49>GLYPH<s46>GLYPH<s52> GLYPH<s49>GLYPH<s46>GLYPH<s54> GLYPH<s49>GLYPH<s46>GLYPH<s56> 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<s46>GLYPH<s56> GLYPH<s49>GLYPH<s46>GLYPH<s48> GLYPH<s49>GLYPH<s46>GLYPH<s50> GLYPH<s49>GLYPH<s46>GLYPH<s52> GLYPH<s49>GLYPH<s46>GLYPH<s54> GLYPH<s49>GLYPH<s46>GLYPH<s56> GLYPH<s118> GLYPH<s103> GLYPH<s40>GLYPH<s50>GLYPH<s108>GLYPH<s43>GLYPH<s49>GLYPH<s41> GLYPH<s49>GLYPH<s47>GLYPH<s50> GLYPH<s47>GLYPH<s108> GLYPH<s32>GLYPH<s68>GLYPH<s105>GLYPH<s114>GLYPH<s101>GLYPH<s99>GLYPH<s116>GLYPH<s32>GLYPH<s110>GLYPH<s117>GLYPH<s109>GLYPH<s101>GLYPH<s114>GLYPH<s105>GLYPH<s99>GLYPH<s97>GLYPH<s108>GLYPH<s32>GLYPH<s115>GLYPH<s105>GLYPH<s109>GLYPH<s117>GLYPH<s108>GLYPH<s97>GLYPH<s116>GLYPH<s105>GLYPH<s111>GLYPH<s110> GLYPH<s32>GLYPH<s65>GLYPH<s110>GLYPH<s97>GLYPH<s108>GLYPH<s121>GLYPH<s116>GLYPH<s105>GLYPH<s99>GLYPH<s97>GLYPH<s108>GLYPH<s32>GLYPH<s115>GLYPH<s111>GLYPH<s108>GLYPH<s117>GLYPH<s116>GLYPH<s105>GLYPH<s111>GLYPH<s110>GLYPH<s32>GLYPH<s117>GLYPH<s110>GLYPH<s100>GLYPH<s101>GLYPH<s114> GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s32>GLYPH<s97>GLYPH<s100>GLYPH<s105>GLYPH<s97>GLYPH<s98>GLYPH<s97>GLYPH<s116>GLYPH<s105>GLYPH<s99>GLYPH<s32>GLYPH<s97>GLYPH<s112>GLYPH<s112>GLYPH<s114>GLYPH<s111>GLYPH<s120>GLYPH<s105>GLYPH<s109>GLYPH<s97>GLYPH<s116>GLYPH<s105>GLYPH<s111>GLYPH<s110> 3 FIG. 3: (Color online) Light intensity | E s | $^{2}$+ | E$_{d}$ | 2 as a func- tion of time and position z for γ n = 0 with different length L 0 . Figures (a)-(f) represents L 0 /l$_{abs}$ = 5 10 20 30 40 and 50 respectively. The position is in unit of l$_{abs}$ and the time is in unit of 1 / Γ. Strong light is shown in red bright color while the back ground is in blue. FIG. 2: (Color online) Group velocity v g of the recreated forward (backward)-propagating light pulse in the γ n = 0 limit. The unit of v g is c Ω 2 c g 2 $_{N}$. The red straight line is from the approximate analytic calculation (24)(25) in Appendix while the black dots are obtained by the direct numerical simulation of Eqs.(6)-(9) in Sec. III. The error margins of the data points are ± 0 . 006. group velocity v$_{g}$ of the forward (backward)-propagating light pulse is shown in Fig.2. One finds that: 1) the ap- proximate solution with cutoff at finite ℓ yields a non-zero v$_{g}$ and 2) v$_{g}$ ( ℓ ) reaches the maximum value at ℓ = 1 and then vanishes with √$_{2}$$_{ℓ}$$_{+ 1}$$_{/ℓ}$$_{.}$ Since the real sys- tem corresponds to the infinite-order limit one “seems” to conclude that the recreated light forms a stationary pulse. pulse in cold atomic systems ( γ$_{n}$ = | n | a Γ) for which the approximate treatment is unavailable we directly simu- late Eqs.(6)–(9). Naturally a cutoff takes place at finite ℓ and accordingly 5+4 ℓ equations are involved in each sim- ulation. The result for real systems ( ℓ → ∞ ) is obtained from the extrapolation of simulations for finite ℓ . We first consider the zero-decay limit ( γ$_{n}$ = 0). The initial condition is taken such that: 1) only the zeroth component S$_{0}$ ( z t = 0) of the ground-spin coherence is nonzero while all other components S$_{2}$$_{n}$ ( z 0) are zero; S$_{0}$ assumes a Gaussian shape S$_{0}$ ( z 0) = e − ( z/L$_{0}$ ) 2 with L$_{0}$ the length of the wave packet; 2) all components of the optical coherence are zero P$_{2}$$_{n}$$_{+1}$ ( z 0) = 0 and 3) no probe light exists at the beginning E + p ( z 0) = E − p ( z 0) = 0. Further the wave-packet length is set at L$_{0}$ = 5 l$_{abs}$ with l$_{abs}$ = Γ c g $^{2}$N the absorption length. To be in the slow- light regime we chose the parameters to be Ω$_{c}$ = 0 . 69Γ g $^{2}$N = 138Γ $^{2}$. The equations are directly solved by Lax- Friedrichs method with sufficiently small step. The sim- ulation is up to ℓ = 100 and the group velocity v$_{g}$ of the recreated forward (backward)-propagating light pulse is measured. The results are shown in Fig. 2. As the ap- proximate analysis v$_{g}$ ( ℓ ) reaches its maximum at ℓ = 1 and then starts to decrease. Nevertheless the decrease of v$_{g}$ becomes slower and slower after ℓ ≈ 14 and eventu- ally stays unchanged at v$_{g}$ = 0 . 47 ± 0 . 006. From Fig. 2 For cold atomic systems where temperature is low but nonzero one has γ$_{0}$ = 0 and γ$_{n}$ = 0 for n = 0. In this case we set γ$_{n}$ = | n | a Γ with a the decay constant. This decay model can well describe the decays of the coef- ficients of the ground-spin/optical coherence in various cold atomic systems. For instance in the laser-cooled cold atomic ensembles the higher-order coefficients have a phase grating of e ink$_{c}$z across the atomic gases and thus will decay due to atomic random motion. The de- cay rate can be estimated by the time needed for the atoms moving across one wavelength of the phase grat- ing γ$_{n}$ ∼ | v$_{s}$ λ | = n | k$_{c}$v$_{s}$ 2 π | [17]. In the Bose condensation the higher-order coefficients can be regarded as a particle excitation with momentum | n | k$_{c}$ ℏ At average they move out of the atomic gases after a time of L $_{(}$| n | k$_{c}$ ℏ m ) − 1 [18] and the decay rate can be approximated by γ$_{n}$ ∼ | n | k$_{c}$ ℏ mL . To check the validity of the approximate solution in Fig. 2 and further find the dynamics of the recreated light III. NUMERICAL SOLUTION | scientific_articles |
Ein Service des Bundesministeriums der Justiz und für Verbraucherschutz sowie des Bundesamts für Justiz ‒ www.gesetze-im-internet.de Verordnung über die Berufsausbildung zum Fahrzeuginnenausstatter/zur Fahrzeuginnenausstatterin FahrzIAAusbV Ausfertigungsdatum: 21.07.2003 Vollzitat: "Verordnung über die Berufsausbildung zum Fahrzeuginnenausstatter/zur Fahrzeuginnenausstatterin vom 21. Juli 2003 (BGBl. I S. 1512)" Ersetzt durch V 806-22-1-131 v. 13.10.2020 I 2166 (FintMechAusbV) (+++ Textnachweis ab: 1.8.2003 +++) Diese Rechtsverordnung ist eine Ausbildungsordnung im Sinne des § 25 des Berufsbildungsgesetzes. Die Ausbildungsordnung und der damit abgestimmte von der Ständigen Konferenz der Kultusminister der Länder in der Bundesrepublik Deutschland beschlossene Rahmenlehrplan für die Berufsschule werden demnächst als Beilage zum Bundesanzeiger veröffentlicht. Auf Grund des § 25 Abs. 1 in Verbindung mit Abs. 2 Satz 1 des Berufsbildungsgesetzes vom 14. August 1969 (BGBl. I S. 1112) der zuletzt durch Artikel 212 Nr. 2 der Verordnung vom 29. Oktober 2001 (BGBl. I S. 2785) geändert worden ist in Verbindung mit § 1 des Zuständigkeitsanpassungsgesetzes vom 16. August 2002 (BGBl. I S. 3165) und dem Organisationserlass vom 22. Oktober 2002 (BGBl. I S. 4206) verordnet das Bundesministerium für Wirtschaft und Arbeit im Einvernehmen mit dem Bundesministerium für Bildung und Forschung: Der Ausbildungsberuf Fahrzeuginnenausstatter/Fahrzeuginnenausstatterin wird staatlich anerkannt. Die Ausbildung dauert drei Jahre. Die in dieser Verordnung genannten Fertigkeiten und Kenntnisse (Qualifikationen) sollen bezogen auf Arbeits- und Geschäftsprozesse vermittelt werden. Diese Qualifikationen sollen so vermittelt werden dass die Auszubildenden zur Ausübung einer qualifizierten beruflichen Tätigkeit im Sinne des § 1 Abs. 2 des Berufsbildungsgesetzes befähigt werden die insbesondere selbständiges Planen Durchführen und Kontrollieren sowie das Handeln im betrieblichen Gesamtzusammenhang einschließt. Die im Satz 2 beschriebene Befähigung ist auch in den Prüfungen nach den §§ 8 und 9 nachzuweisen. Die Ausbildenden haben unter Zugrundelegung des Ausbildungsrahmenplans für die Auszubildenden einen Ausbildungsplan zu erstellen. Die Auszubildenden haben ein Berichtsheft in Form eines Ausbildungsnachweises zu führen. Ihnen ist Gelegenheit zu geben das Berichtsheft während der Ausbildungszeit zu führen. Die Ausbildenden haben das Berichtsheft regelmäßig durchzusehen. § 5 Berichtsheft § 4 Ausbildungsplan § 3 Zielsetzung der Berufsausbildung § 2 Ausbildungsdauer § 1 Staatliche Anerkennung des Ausbildungsberufes Eingangsformel V aufgeh. durch § 20 Satz 2 V 806-22-1-131 v. 13.10.2020 I 2166 mWv 1.8.2021 Fußnote - Seite 1 von 12 - | laws_and_regulations |
8.5. The$_{with}$ statement 99 The Python Language Reference Release 3.9.5 8.5 The with statement manager=(EXPRESSION) enter =type(manager) .__enter__ exit =type(manager) .__exit__ value=enter(manager) hit_except = False try : TARGET =value SUITE except : hit_except = True if not exit(manager *sys.exc_info()): raise finally : if not hit_except: exit(manager None None None ) is semantically equivalent to: If the suite was exited for any reason other than an exception the return value from$_{__exit__()}$ is ignored and execution proceeds at the normal location for the kind of exit that was taken. The following code: If the suite was exited due to an exception and the return value from the$_{__exit__()}$ method was false the exception is reraised. If the return value was true the exception is suppressed and execution continues with the statement following the$_{with}$ statement. 7. The context manager’s$_{__exit__()}$ method is invoked. If an exception caused the suite to be exited its type value and traceback are passed as arguments to$_{__exit__()}$ . Otherwise three$_{None}$ arguments are supplied. 6. The suite is executed. Note: The with statement guarantees that if the __enter__() method returns without an error then __exit__() will always be called. Thus if an error occurs during the assignment to the target list it will be treated the same as an error occurring within the suite would be. See step 6 below. 4. The context manager’s$_{__enter__()}$ method is invoked. 5. If a target was included in the$_{with}$ statement the return value from$_{__enter__()}$ is assigned to it. 3. The context manager’s __exit__() is loaded for later use. 2. The context manager’s __enter__() is loaded for later use. 1. The context expression (the expression given in the with_item ) is evaluated to obtain a context manager. The execution of the$_{with}$ statement with one “item” proceeds as follows: The with statement is used to wrap the execution of a block with methods defined by a context manager (see section With Statement Context Managers ). This allows common try … except … finally usage patterns to be encapsulated for convenient reuse. with_stmt ::= "with" with_item (" " with_item )* ":" suite with_item ::= expression ["as" target ] with EXPRESSION as TARGET: SUITE | manuals |
[39] Luo A. C. J. [2014] Toward Analytical Chaos in Nonlinear Systems (John Wiley & Sons United Kingdom). [40] Marotto F. R. [1978] “Snap-back repellers imply chaos in R $^{n}$ ” J. Math. Anal. Appl. $_{63}$ 199–223. [41] Owens B. A. M. Stahl M. T. Corron N. J. Blakely J. N. & Illing L. [2013] “Exactly solvable chaos in an electromechanical oscillator ” Chaos $_{23}$ 033109. [42] Samoilenko A. M. & Perestyuk N. A. [1995] Impulsive Differential Equations (World Scientific Singapore). [43] Shi Y. & Chen G. [2004] “Chaos of discrete dynamical systems in complete metric spaces ” Chaos Solitons & Fractals $_{22}$ 555–571. [44] Shi Y. & Chen G. [2005] “Discrete chaos in Banach spaces ” Science in China Ser. A: Mathematics $_{48}$ 222–238. [45] Thamilmaran K. Lakshmanan M. & Venkatesan A. [2004] “Hyperchaos in a modified canonical Chua’s circuit ” Int. J. Bifurcation and Chaos $_{14}$ 221–243. [46] Tisdell C. C. & Zaidi A. [2008] “Basic qualitative and quantitative results for solutions to nonlinear dynamic equations on time scales with an application to economic modelling ” Nonlinear Analysis $_{68}$ 3504–3524. [47] Ueda Y. [1978] “Random phenomena resulting from non-linearity in the system described by Duff- ing’s equation ” Trans. Inst. Electr. Eng. Jpn. $_{98A}$ 167–173. [48] Zhang J. Fan M. & Zhu H. [2010] “Periodic solution of single population models on time scales ” Mathematical and Computer Modelling $_{52}$ 515–521. 16 | scientific_articles |
RADIO PHONE-IN Radio phone-ins would see an OSH expert (whether from the focal point or other relevant national institution) being interviewed on a one-to-one basis with a journalist to provoke debate on a certain topic. The bi-directional setting of this measure would initiate instant debate with the radio channel receiving telephone calls emails or texts from members of the public and having their questions raised with the interviewee. The evaluation of a radio phone-in can be achieved by assessing the total number of listeners as well as analysis of the questions raised which indicates the public interest for the topic. The table below summarises the main services: Radio phone-in Overall management (including the elaboration of concept) Social media posts* Identification of expert in cooperation with EU-OSHA/network members Briefing of experts Identification and negotiation with radio station for cost-free placement Overall management including development of concept for a radio phone-in Kick-off meeting for definition of topic and elaboration of concept • Kick-off meeting between the EU-OSHA's national partner and the Contractor’s network partner should determine the overall approach and concept of the radio call-in (including its focus topic potential spokesperson and key messages). • Concept of radio-call in to be elaborated in agreement between EU-OSHA's national partner and the Contractor’s network partner. • EU-OSHA’s resources should be utilised and referred to. European Agency for Safety and Health at Work – EU-OSHA 71 | government_tenders |
NOTES TO THE CONSOLIDATED FINANCIAL STATEMENTS 1. CORPORATE INFORMATION 2. SIGNIFICANT ACCOUNTING POLICIES a) Statement of Compliance b) Adoption of Accounting Standards i. Consolidated Financial Statements Joint Ventures and Disclosures ii. Employee Benefits 86 BROOKFIELD ASSET MANAGEMENT Brookfield Asset Management Inc. (“Brookfield” or the “company”) is a global alternative asset management company. The company owns and operates assets with a focus on property renewable energy infrastructure and private equity. The company is listed on the New York Toronto and Euronext stock exchanges under the symbols BAM BAM.A and BAMA respectively. The company was formed by articles of amalgamation under the Business Corporations Act (Ontario) and is registered in Ontario Canada. The registered office of the company is Brookfield Place 181 Bay Street Suite 300 Toronto Ontario M5J 2T3. These consolidated financial statements have been prepared in accordance with International Financial Reporting Standards (“IFRS”) as issued by the International Accounting Standards Board (“IASB”). These financial statements were authorized for issuance by the Board of Directors of the company on March 28 2014. In 2013 the company has applied new and revised standards issued by the IASB that are effective for the period beginning on or after January 1 2013 as follows: In May 2011 the IASB issued three standards: IFRS 10 Consolidated Financial Statements (“IFRS 10”) IFRS 11 Joint Arrangements (“IFRS 11”) and IFRS 12 Disclosure of Interests in Other Entities (“IFRS 12”) and amended two standards: IAS 27 Separate Financial Statements (“IAS 27”) and IAS 28 Investments in Associates and Joint Ventures (“IAS 28”). IAS 27 is not applicable to the company as it relates only to entities with separate financial statements. IFRS 10 replaces IAS 27 and SIC-12 Consolidation-Special Purpose Entities (“SIC-12”). The consolidation requirements previously included in IAS 27 have been included in IFRS 10. IFRS 10 uses control as the single basis for consolidation irrespective of the nature of the investee eliminating the risks and rewards approach included in SIC-12. An investor must have power with existing rights to direct the relevant activities of the investee have exposure or rights to variable returns from involvement with the investee and have the ability to use its power over the investee to affect the amount of its returns in order to conclude it controls an investee. IFRS 10 requires continuous reassessment if the facts and circumstances change to one or more of the elements of control. The company applied the principles of IFRS 10 retrospectively and accordingly resulted in the consolidation of an investee which was previously equity accounted. The retrospective application of IFRS 10 increased consolidated assets liabilities and non-controlling interests by $218 million $114 million and $104 million respectively as at December 31 2012 and increased consolidated revenues and net income by $69 million and $8 million respectively for the year then ended with no impact on common equity or net income attributable to shareholders during the year ended December 31 2012. IFRS 11 supersedes IAS 31 Interests in Joint Ventures and SIC-13 Jointly Controlled Entities – Non-Monetary Contributions by Venturers . IFRS 11 is applicable to all parties that have an interest in a joint arrangement. IFRS 11 establishes two types of joint arrangements: joint operations and joint ventures. In a joint operation the parties to the joint arrangement have rights to the assets and obligations for the liabilities of the arrangement and recognize their share of the assets liabilities revenues and expenses. In a joint venture the parties to the joint arrangement have rights to the net assets of the arrangement and account for their interest using the equity method of accounting under IAS 28. IAS 28 prescribes the accounting for investments in associates and sets out the requirements for the application of the equity method when accounting for investments in associates and joint ventures. There was no impact of adoption of IFRS 11 on the company’s consolidated financial statements. IFRS 12 integrates the disclosure requirements of interests in other entities and requires a parent company to disclose information about significant judgments and assumptions it has made in determining whether it has control joint control or significant influence over another entity and the type of joint arrangement when the arrangement has been structured through a separate vehicle. An entity should also provide these disclosures when changes in facts and circumstances affect the entity’s conclusion during the reporting period. As a result of the adoption of IFRS 12 the company has included more comprehensive disclosures surrounding consolidated subsidiaries and equity accounted investments in the consolidated financial statements. In September 2011 the IASB amended IAS 19 Employee Benefits (“IAS 19”) for items impacting defined benefit plans including the recognition of: actuarial gains and losses within other comprehensive income; interest on the net benefit liability (or asset) in profit and loss; and unvested past service costs in profit and loss at either the earlier of when an amendment is made or when related restructuring or termination costs are recognized. Additionally the adoption of amendments to IAS 19 required the company to retroactively exclude expected returns on plan assets from profit and loss the result of which was a net charge against common equity of $6 and $10 million as at January 1 2012 and December 31 2012 respectively. | financial_reports |
2014 ANNUAL REPORT CLOSE FILE X VILLAGE ROADSHOW LIMITED | financial_reports |
MongoDB Documentation Release 3.0.4 For example if you have six collections in a database using the MMAPv1 storage engine and an operation takes a collection-level write lock the other five collections are still available for read and write operations. An exclusive database lock makes all six collections unavailable for the duration of the operation holding the lock. For reporting on lock utilization information on locks use any of the following methods: Specifically the locks document in the output of serverStatus or the locks field in the current operation reporting provides insight into the type of locks and amount of lock contention in your mongod instance. To terminate an operation use db.killOp() . In some situations read and write operations can yield their locks. Long running read and write operations such as queries updates and deletes yield under many conditions. MongoDB operations can also yield locks between individual document modifications in write operations that affect multiple documents like update() with the multi parameter. MongoDB’s mmapv1 (page 91) storage engine uses heuristics based on its access pattern to predict whether data is likely in physical memory before performing a read. If MongoDB predicts that the data is not in physical memory an operation will yield its lock while MongoDB loads the data into memory. Once data is available in memory the operation will reacquire the lock to complete the operation. For storage engines supporting document level concurrency control yielding is not necessary when accessing storage as the intent locks held at the global database and collection level do not block other readers and writers. Changed in version 2.6: MongoDB does not yield locks when scanning an index even if it predicts that the index is not in memory. Changed in version 2.2. The following table lists common database operations and the types of locks they use. 11.4. FAQ: Concurrency 759 11.4.5 Which operations lock the database? 11.4.4 Does a read or write operation ever yield the lock? 11.4.3 How do I see the status of locks on my mongod instances? • db.serverStatus() • db.currentOp() • mongotop • mongostat and/or • the MongoDB Cloud Manager 18 or Ops Manager an on-premise solution available in MongoDB Enterprise Advanced 19 $^{18}$https://cloud.mongodb.com/?jmp=docs $^{19}$https://www.mongodb.com/products/mongodb-enterprise-advanced?jmp=docs | manuals |
Table of Contents jurisdiction's regulatory capital adequacy formula. If we do not meet these minimum requirements we may be restricted or prohibited from operating our business in the applicable jurisdictions and specialized markets. If we are required to record a material charge against earnings in connection with a change in estimated insurance reserves the occurrence of a catastrophic event or if we incur significant losses related to our investment portfolio which severely deteriorates our capital position we may violate these minimum capital adequacy requirements unless we are able to raise sufficient additional capital. We may be limited in our ability to raise significant amounts of capital on favorable terms or at all. The IAIS recently adopted a common framework for the supervision of internationally active insurance groups and continues to develop a group basis Insurance Capital Standard (ICS). The NAIC is also developing a group capital standard that is intended to be comparable to the ICS. The development and adoption of these capital standards could increase our prescribed capital requirement the level at which regulatory scrutiny intensifies as well as significantly increase our cost of regulatory compliance. We are a holding company and are dependent upon dividends loans and other sources of cash from our subsidiaries in order to meet our obligations. Ordinary dividend payments or dividends that do not require prior approval by the insurance subsidiaries' domiciliary insurance regulator are generally limited to amounts determined by formulas that vary by jurisdiction. If we are restricted from paying or receiving intercompany dividends by regulatory rule or otherwise we may not be able to fund our corporate obligations and debt service requirements or pay our stockholders dividends from available cash. As a result we would need to look to other sources of capital which may be more expensive or may not be available at all. Ratings are an important factor in establishing the competitive position of insurance companies. Our insurance company subsidiaries as well as our public debt are rated by rating agencies including A.M. Best Company (A.M. Best) Moody's Investors Service Inc. (Moody's) and Standard & Poor's (S&P). Ratings reflect the rating agency's opinions of an insurance company's or insurance holding company's financial strength capital adequacy enterprise risk management practices operating performance strategic position and ability to meet its obligations to policyholders and debt holders. The rating agencies may take action to lower our ratings in the future as a result of any significant financial loss or possible changes in the methodology or criteria applied by the rating agencies. The severity of the impact on our business is dependent on the level of downgrade and for certain products which rating agency takes the rating action. Among the adverse effects in the event of such downgrades would be the inability to obtain a material volume of business from certain major insurance brokers the inability to sell a material volume of our insurance products to certain markets and the required collateralization of certain future payment obligations or reserves. In addition it is possible that a significant lowering of the corporate debt ratings of Loews by certain of the rating agencies could result in an adverse effect on our ratings independent of any change in our circumstances. The insurance industry is subject to comprehensive and detailed regulation and supervision. Most insurance regulations are designed to protect the interests of our policyholders and third-party claimants rather than our investors. Each jurisdiction in which we do business has established supervisory agencies that regulate the manner in which we do business. Any changes in regulation could impose significant burdens on us. In addition the Lloyd's marketplace sets rules under which its members including our Hardy syndicate operate. Our insurance subsidiaries upon whom we depend for dividends in order to fund our corporate obligations are limited by insurance regulators in their ability to pay dividends. Rating agencies may downgrade their ratings of us and thereby adversely affect our ability to write insurance at competitive rates or at all. We are subject to extensive existing state local federal and foreign governmental regulations that restrict our ability to do business and generate revenues; additional regulation or significant modification to existing regulations or failure to comply with regulatory requirements may have a materially adverse effect on our business our operations and financial condition. 13 | financial_reports |
Python Frequently Asked Questions Release 3.9.5 def remove_gray_shades ( colors:list[tuple[int int int]])->list[tuple[int int int]]: pass Color =tuple[int int int] def remove_gray_shades (colors:list[Color])->list[Color]: pass could be made more readable like this: See$_{typing}$and PEP 484 which describe this functionality. Type hints are optional and are not enforced by Python but they are useful to static type analysis tools and aid IDEs with code completion and refactoring. Type hints of global variables class attributes and functions but not local variables can be accessed using typing.get_type_hints() . See typing and PEP 484 which describe this functionality. type hint An annotation that specifies the expected type for a variable a class attribute or a function parameter or return value. universal newlines A manner of interpreting text streams in which all of the following are recognized as ending a line: the Unix end-of-line convention '
' the Windows convention '\r
' and the old Macintosh convention$_{'\r'}$ . See PEP 278 and PEP 3116 as well as$_{bytes.splitlines()}$ for an additional use. variable annotation An annotation of a variable or a class attribute. virtual environment A cooperatively isolated runtime environment that allows Python users and applications to install and upgrade Python distribution packages without interfering with the behaviour of other Python appli- cations running on the same system. virtual machine A computer defined entirely in software. Python’s virtual machine executes the bytecode emitted by the bytecode compiler. Zen of Python Listing of Python design principles and philosophies that are helpful in understanding and using the language. The listing can be found by typing “$_{import this}$ ” at the interactive prompt. Appendix A. Glossary 88 See also$_{venv}$ . Variable annotation syntax is explained in section annassign. See function annotation PEP 484 and PEP 526 which describe this functionality. Variable annotations are usually used for type hints : for example this variable is expected to take$_{int}$ values: classC : field:'annotation' count:int =0 When annotating a variable or a class attribute assignment is optional: | manuals |
Table 1 System architecture specifications (part 2 of 2) 6 IBM Storage Networking SAN128B-6 Switch Performance Fibre Channel: 4.25 Gbps line speed full duplex; 8.5 Gbps line speed full duplex; 10.53 Gbps line speed full duplex; 14.025 Gbps line speed full duplex; 28.05 Gbps full duplex; 112.2 Gbps full duplex; auto-sensing of 4/8/10/16/32 Gbps port speeds and capable of supporting 128 Gbps speeds; 10 Gbps optionally programmable to fixed port speed. Auto-sensing of 4×32 / 4×16 / 4×8 / 4×4 Gbps speeds on the QSFP ports with FOS v8.2.0. ISL trunking Frame-based trunking with up to eight 32 Gbps connections between a pair of switches combined to form a single logical ISL with a speed of up to 256 Gbps (512 Gbps full duplex) per ISL trunk. Exchange-based load balancing across ISLs with DPS included in FOS. On the QSFP ports 256 Gbps trunks are supported by trunking 2× (4×32 Gbps) QSFP ports. Aggregate bandwidth 4 Tbps Maximum fabric latency Latency for locally switched ports is < 780 ns (including FEC); compression is 1 μs per node Maximum frame size 2 112-byte payload Frame buffers 15K frame buffers with dynamic buffer sharing capability across ports Classes of service Class 2 Class 3 Class F (inter-switch frames) Port types D_Port (ClearLink Diagnostic Port) E_Port EX_Port F_Port AE_Port optional port-type control Data traffic types Fabric switches supporting unicast Media types Hot-pluggable industry-standard Small Form-Factor Pluggable Plus (SFP+) LC connector; Short-Wave Laser (SWL) Long-Wave Laser (LWL); Extended Long-Wave Laser (ELWL); distance depends on fiber optic cable and port speed. Supports SFP+ (32/16/8 Gbps) SFP+ (16/8/4 Gbps) SFP+ 10 Gbps optical transceivers 4×32 Gbps QSFP SWL and 4×16 Gbps QSFP SWL optical transceivers. USB One USB port for system log file downloads or firmware upgrades Fabric services Monitoring and Alerting Policy Suite (MAPS); Flow Vision; Adaptive Networking (Ingress Rate Limiting Traffic Isolation QoS); Fabric Performance Impact (FPI) Monitoring; Slow Drain Device Quarantine (SDDQ); Advanced Zoning (default zoning port/WWN zoning broadcast zoning peer zoning target-driven zoning); Dynamic Path Selection (DPS); Extended Fabrics; Enhanced BB Credit Recovery; FDMI; Frame Redirection; Frame-based Trunking; FSPF; Integrated Routing; ISL Trunking; Management Server; NPIV; Time Server; Registered State Change Notification (RSCN); Reliable Commit Service (RCS); Simple Name Server (SNS); Virtual Fabrics (Logical Switch Logical Fabric); Read Diagnostics Parameter (RDP) Extension Fibre Channel in-flight compression (LZO) and encryption (AES-GCM-256); integrated optional 10 Gbps Fibre Channel for DWDM MAN connectivity | manuals |
MV2075 (052020) Vehicle Checklist 10 most common reasons a vehicle might not be accepted for a road test: You need to bring a safe reliable vehicle for your road test. If it isn’t safe or doesn’t meet legal requirements we may have to cancel your test. 1. Dash warning lights (for example air bag) that affect the safe operation of the vehicle 2. Brake lights signal lights or headlights not working or with badly cracked or missing lenses 3. Unsafe tires 4. Doors or windows not operating (for example doors don’t open from inside) 5. Cracked or illegally tinted windshield or windows 6. Horn not working 7. Gas tank or electric charge too low 8. Vehicle not properly licensed or insured 9. Seatbelts not working or frayed 10. Unsafe or illegal vehicle modifications | manuals |
and C. J. Peters Proceedings of the NATO Advanced Study Institute NATO Science Series E Vol. 366 (Kluwer Dordrecht 2000). [5] Y. Xia B. Gates Y. Yin and Y. Lu Adv. Mater. 12 693 (2000). [6] J. N. Israelachvili Intermolecular and Surface Forces (Academic London 1992). [7] C. Hertlein L. Helden A. Gambassi S. Dietrich and C. Bechinger Nature 451 172 (2008). [8] A. Gambassi A. Maciolek C. Hertlein U. Nellen L. Helden C. Bechinger and S. Dietrich Phys. Rev. E 80 061143 (2009). [9] A. Onuki and H. Kitamura J. Chem. Phys. 121 3143 (2004). [10] E. L. Eckfeldt and W. W. Lucasse J. Phys. Chem. 47 164 (1943). [11] B. J. Hales G. L. Bertrand and L. G. Hepler J. Phys. Chem. 70 3970 (1966). [12] V. Balevicius and H. Fuess Phys. Chem. Chem. Phys. 1 1507 (1999). [13] Y. Tsori and L. Leibler Proc. Nat. Acad. Sci. USA 104 7348 (2007). [14] D. Ben-Yaakov D. Andelman D. Harries and R. Podgornik J. Phys. Chem. B 113 6001 (2009). [15] J. D. Jackson Classical Electrodynamics 3rd ed. (Academic Press New York 1999). [16] A. Ciach and G. Stell Phys. Rev. E 70 016114 (2004). [17] A. Ciach and G. Stell Int. J. Mod. Phys. B 19 3309 (2005). [18] A. Ciach and V. Babin J. Mol. Liq. 112 37 (2004). [19] M. Bier and S. Dietrich unpublished. 24 | scientific_articles |
135 US 9 958 775 B2 136 -continued --+CH¢c:H~ OH Ab-206 CH3 CH3 I I ---fCH2-C+-- --+CH2-C-t-- OAO OAO ~(° 0 ~ Vy 0 Ab-207 [Chem. 84] Ab-206 | patents |
(continued from previous page) Data structure read access: read_list 24.2 24.5 20.8 20.8 read_deque 24.7 25.5 20.2 20.6 read_dict 24.3 25.7 22.3 23.0 read_strdict 22.6 24.3 19.5 21.2 Data structure write access: write_list 27.1 28.5 22.5 21.6 write_deque 28.7 30.1 22.7 21.8 write_dict 31.4 33.3 29.3 29.2 write_strdict 28.4 29.9 27.5 25.2 Stack (or queue) operations: list_append_pop 93.4 112.7 75.4 74.2 deque_append_pop 43.5 57.0 49.4 49.2 deque_append_popleft 43.7 57.3 49.7 49.7 Timing loop: loop_overhead 0.5 0.6 0.40.3 0.3 These results were generated from the variable access benchmark script at: Tools/scripts/ var_access_benchmark.py . The benchmark script displays timings in nanoseconds. The benchmarks were measured on an Intel® Core™ i7-4960HQ processor running the macOS 64-bit builds found at python.org. 14 • The explicit passing of coroutine objects to$_{asyncio.wait()}$ has been deprecated and will be removed in version 3.11. (Contributed by Yury Selivanov and Kyle Stanley in bpo-34790.) • Deprecated the$_{split()}$ method of$_{_tkinter.TkappType}$ in favour of the$_{splitlist()}$ method which has more consistent and predicable behavior. (Contributed by Serhiy Storchaka in bpo-38371.) • Opening the$_{GzipFile}$ file for writing without specifying the mode argument is deprecated. In future Python versions it will always be opened for reading by default. Specify the mode argument for opening it for writing and silencing a warning. (Contributed by Serhiy Storchaka in bpo-28286.) • The$_{random}$module currently accepts any hashable type as a possible seed value. Unfortunately some of those types are not guaranteed to have a deterministic hash value. After Python 3.9 the module will restrict its seeds to$_{None}$ $_{int}$ $_{float}$ $_{str}$ $_{bytes}$ and$_{bytearray}$. • The Public C API functions PyParser_SimpleParseStringFlags() PyParser_SimpleParseStringFlagsFilename() $_{PyParser_SimpleParseFileFlags()}$ and$_{PyNode_Compile()}$ are deprecated and will be removed in Python 3.10 together with the old parser. • Using$_{NotImplemented}$in a boolean context has been deprecated as it is almost exclusively the result of incorrect rich comparator implementations. It will be made a$_{TypeError}$ in a future version of Python. (Contributed by Josh Rosenberg in bpo-35712.) • The$_{parser}$ and$_{symbol}$modules are deprecated and will be removed in future versions of Python. For the majority of use cases users can leverage the Abstract Syntax Tree (AST) generation and compilation stage using the$_{ast}$module. • Currently$_{math.factorial()}$ accepts$_{float}$instances with non-negative integer values (like$_{5.0}$ ). It raises a$_{ValueError}$for non-integral and negative floats. It is now deprecated. In future Python versions it will raise a$_{TypeError}$ for all floats. (Contributed by Serhiy Storchaka in bpo-37315.) • The distutils$_{bdist_msi}$command is now deprecated use$_{bdist_wheel}$(wheel packages) instead. (Con- tributed by Hugo van Kemenade in bpo-39586.) 8 Deprecated | manuals |