all-applications computer

all-applications computer

универсальная вычислительная машина

mechanical computer — механическое вычислительное устройство

linkage computer — вычислительное устройство шарнирного типа

fluid computer — вычислительная машина на струйных элементах

computer test circuit — схема контроля вычислительной машины

analog computer unit — блок аналоговой вычислительной машины

all-applications computer

универсальная вычислительная машина

all-applications computer

Вычислительная техника: универсальная вычислительная машина

all-applications computer

универсальная вычислительная машина

all applications computer

komputer do zastosowań ogólnych

komputer uniwersalny

all applications computer

komputer do zastosowań ogólnych

komputer uniwersalny

all applications digital computer

[lang name="English"]AADC, all applications digital computer

универсальная цифровая ЭВМ

all applications digital computer

Военный термин: универсальная цифровая ЭВМ

all-applications digital computer

Микроэлектроника: универсальная ЭВМ

all-applications digital computer

універсальна ЕОМ

computer

1) компьютер; вычислительная машина; ЭВМ; вычислительное устройство; вычислитель; редк. процессор

2) редк. счётная машина (см. тж calculator, machine)

•

- active computer

- adaptive computer
- airborne computer
- all-applications computer
- all-purpose computer
- alternating-current analog computer
- analog computer
- analog-digital computer
- arbitrary sequence computer
- associative computer
- asynchronous computer
- automotive computer
- baby-sized computer
- back-end computer
- batch-oriented computer
- battery-operated computer
- binary computer
- binary-transfer computer
- board computer
- boutique computer
- brand-name computer
- breadboard computer
- buffered computer
- business computer
- business-oriented computer
- byte computer
- byte-organized computer
- byte-oriented computer
- cassette-based computer
- census computer
- central computer
- character-oriented computer
- chemical-based computer
- chess computer
- CISC computer
- commercial computer
- commodity computer
- communication computer
- communications oriented computer
- compatible computer
- complete-instruction-set computer
- concurrent computer
- consecutive computer
- consecutive sequence computer
- continuously acting computer
- control computer
- control flow computer
- correlation computer
- coupled computers
- cryogenic computer
- cryotron computer
- custom computer
- database computer
- data-flow computer
- decimal computer
- dedicated computer
- desk computer
- desk-size computer
- desk-top computer
- dialing set computer
- dial set computer
- digital computer
- direct execution computer
- direct-analogy computer
- direct-current computer
- diskless computer
- distributed logic computer
- drum computer
- dual-processor computer
- education computer
- electromechanical analog computer
- electronic tube computer
- electron tube computer
- electronic computer
- end-user computer
- ever-faster computer
- externally programmed computer
- fault-tolerant computer
- fifth-generation computer
- file computer
- first-generation computer
- fixed word-length computer
- fixed-point computer
- fixed-program computer
- flat screen computer
- floating-point computer
- fluid computer
- four-address computer
- fourth-generation computer
- fractional computer
- front-end computer
- gateway computer
- general-purpose computer
- giant computer
- giant-powered computer
- giant-scale computer
- giant-size computer
- gigacycle computer
- gigahertz computer
- guidance computer
- handheld computer
- high-end computer
- high-function computer
- high-level language computer
- high-level computer
- highly parallel computer
- high-performance computer
- high-speed computer
- hobby computer
- home banking computer
- home computer
- host computer
- hybrid computer
- IBM-compatible computer
- IC computer
- incompatible computer
- incremental computer
- industrial computer
- integrated circuit computer
- interface computer
- interim computer
- intermediate computer
- internally programmed computer
- Internet computer
- keyboard computer
- kid computer
- laptop computer
- large computer
- large-powered computer
- large-scale computer
- large-scale integration circuit computer
- large-size computer
- laser computer
- linkage computer
- local computer
- logical computer
- logic computer
- logic-controlled sequential computer
- logic-in-memory computer
- low-end computer
- low-profile computer
- low-speed computer
- LSI computer
- mainframe computer
- massively parallel computer
- master computer
- mechanical computer
- medium computer
- medium-powered computer
- medium-size computer
- medium-speed computer
- medium-to-large scale computer
- mediun-scale computer
- megacycle computer
- megahertz computer
- microprogrammable computer
- microwave computer
- mid-range computer
- molecular computer
- monoprocessor computer
- multiaddress computer
- multi-MIPS computer
- multiple-access computer
- multiple-user computer
- multiprocessor computer
- multiprogrammed computer
- multipurpose computer
- multiradix computer
- navigation computer
- net node computer
- networked computer
- N-node computer
- no-address computer
- node computer
- nonsequential computer
- nonstop computer
- non-von Neumann computer
- notebook computer
- object computer
- office computer
- off-the-shelf computer
- one-address computer
- one-and-half-address computer
- one-on-one computer
- one-purpose computer
- optical computer
- optical path computer
- original computer
- palm-size computer

- palmtop computer

- parallel computer

- parallel-processing computer
- parallel-serial computer
- parametric-electronic computer
- parametron computer
- pen-based computer
- pentop computer
- perihperal support computer
- peripheral computer
- personal computer
- pictorial computer
- pipeline computer
- plugboard computer
- plug-compatible computer
- plugged program computer
- pneumatic computer
- pocket computer
- Polish-string computer
- polynomial computer
- portable computer
- process control computer
- production control computer
- professional computer
- professional personal computer
- program-compatible computer
- program-controlled computer
- programmed computer
- punch-card computer
- rack-size computer
- radix two computer
- real-time computer
- recovering computer
- reduced instruction set computer
- reduction computer
- remote computer
- repetitive computer
- RISC computer
- satellite computer
- scientific computer
- second-generation computer
- secondhand computer
- self-adapting computer
- self-organizing computer
- self-programming computer
- self-repairing computer
- self-repair computer
- sensor-based computer
- sequence-controlled computer
- sequenced computer
- sequential computer
- serial computer
- service computer
- service-oriented computer
- SIMD computer
- simultaneous-operation computer
- simultaneous computer
- single-address computer
- single-board computer
- single-purpose computer
- single-user computer
- slave computer
- small computer
- small-powered computer
- small-scale computer
- small-size computer
- soft-compatible computer
- solid-state computer
- SOS computer
- source computer
- space computer
- spaceborne computer
- special-purpose computer
- special computer
- square-root computer
- stack-oriented computer
- standby computer
- statistical computer
- steering computer
- stored-program computer
- subscriber computer
- super computer
- superconductive computer
- superhigh-speed computer
- superpersonal computer
- superspeed computer
- supervisory computer
- switch-control computer
- switching computer
- symbolic computer
- synchronous computer
- synchronous tracking computer
- tagged computer
- talking computer
- target computer
- technical computer
- technical personal computer
- terminal computer
- terminal control computer
- ternary-transfer computer
- tessellated computer
- thermal computer
- thin-film memory computer
- third-generation computer
- three-address computer
- three-dimensional analog computer
- timeshared computer
- top level computer
- top-of-the-line computer
- toy computer
- training computer
- transformation computer
- transistorized computer
- transistor computer
- translating computer
- tridimensional analog computer
- trip computer
- truth-table computer
- Turing-type computer
- two-address computer
- ultrafast computer
- underlying computer
- user computer
- vacuum tube computer
- variable word-length computer
- very-high-speed computer
- video-and-cassette-based computer
- virtual computer
- von Neumann computer
- wearable computer
- weather computer
- wired-program computer
- word-oriented computer
- workgroup computer
- X-computer
- zero-address computer

computer

електронна обчислювальна машина, ЕОМ

- all-applications digital computer

- back-end computer
- divide-and-conquer computer
- front-end computer
- LSI computer
- mainframe computer
- microelectronic computer
- microprocessor-array computer
- molecular computer
- multifunctional processing computer
- single-chip computer

универсальная вычислительная машина

all-applications computer, all-purpose computer, feneral-purpose computer, large-scale computer, mainframe computer, multipurpose computer

AADC

1) Геология: Australian Antarctic Data Centre

2) Военный термин: Army Air Defense Commander, Army air defense command, all applications digital computer, antiaircraft defense commander, antiaircraft director center

3) Техника: advanced airborne digital computer, all-applications digital computer

4) Юридический термин: Arizona Association Of Defense Counsel

5) Телекоммуникации: Automated Area Distribution Center

6) Сокращение: American Air Defense Command, Anti-Aircraft Defence Commander, Area Air Defense Command (USA), Area Air Defense Commander, Area Air-Defense Capability, Area Air-Defense Commander, all application digital computer

7) Университет: Associate Alumnae Of Douglass College

8) Биохимия: ДАЛА, Декарбоксилаза ароматических l-аминокислот (Aromatic L-amino acid decarboxylase)

9) Транспорт: Airport Arrival Demand Chart, Allison Advanced Development Company, Approach and Departure Control

10) Фирменный знак: Arabian American Development Company

11) Должность: Advanced Alcohol And Drug Counselor

12) Хобби: Adelaide Advertising Design Club

AADC

1. advanced airborne digital computer - усовершенствованная бортовая цифровая вычислительная машина;

2. all-applications digital computer - универсальная ЭВМ;

3. Army air defense command - командование ПВО сухопутных войск;

4. Army air defense commander - командующий ПВО сухопутных войск

AADC

[lang name="English"]AADC, all applications digital computer

универсальная цифровая ЭВМ

————————

[lang name="English"]AADC, antiaircraft defense commander

начальник ПВО (напр. сектора)

————————

[lang name="English"]AADC, antiaircraft director center

центр управления средствами ПВО

————————

[lang name="English"]AADC, Army air defense command

командование ПВО СВ (соединение)

————————

[lang name="English"]AADC, Army Air Defense Commander

командующий ПВО СВ

modular data center

1. модульный центр обработки данных (ЦОД)

 

модульный центр обработки данных (ЦОД)
-
[Интент]

Параллельные тексты EN-RU

[ http://loosebolts.wordpress.com/2008/12/02/our-vision-for-generation-4-modular-data-centers-one-way-of-getting-it-just-right/]

[ http://dcnt.ru/?p=9299#more-9299]

Data Centers are a hot topic these days. No matter where you look, this once obscure aspect of infrastructure is getting a lot of attention. For years, there have been cost pressures on IT operations and this, when the need for modern capacity is greater than ever, has thrust data centers into the spotlight. Server and rack density continues to rise, placing DC professionals and businesses in tighter and tougher situations while they struggle to manage their IT environments. And now hyper-scale cloud infrastructure is taking traditional technologies to limits never explored before and focusing the imagination of the IT industry on new possibilities.

В настоящее время центры обработки данных являются широко обсуждаемой темой. Куда ни посмотришь, этот некогда малоизвестный аспект инфраструктуры привлекает все больше внимания. Годами ИТ-отделы испытывали нехватку средств и это выдвинуло ЦОДы в центр внимания, в то время, когда необходимость в современных ЦОДах стала как никогда высокой. Плотность серверов и стоек продолжают расти, все больше усложняя ситуацию для специалистов в области охлаждения и организаций в их попытках управлять своими ИТ-средами. И теперь гипермасштабируемая облачная инфраструктура подвергает традиционные технологии невиданным ранее нагрузкам, и заставляет ИТ-индустрию искать новые возможности.

At Microsoft, we have focused a lot of thought and research around how to best operate and maintain our global infrastructure and we want to share those learnings. While obviously there are some aspects that we keep to ourselves, we have shared how we operate facilities daily, our technologies and methodologies, and, most importantly, how we monitor and manage our facilities. Whether it’s speaking at industry events, inviting customers to our “Microsoft data center conferences” held in our data centers, or through other media like blogging and white papers, we believe sharing best practices is paramount and will drive the industry forward. So in that vein, we have some interesting news to share.

В компании MicroSoft уделяют большое внимание изучению наилучших методов эксплуатации и технического обслуживания своей глобальной инфраструктуры и делятся результатами своих исследований. И хотя мы, конечно, не раскрываем некоторые аспекты своих исследований, мы делимся повседневным опытом эксплуатации дата-центров, своими технологиями и методологиями и, что важнее всего, методами контроля и управления своими объектами. Будь то доклады на отраслевых событиях, приглашение клиентов на наши конференции, которые посвящены центрам обработки данных MicroSoft, и проводятся в этих самых дата-центрах, или использование других средств, например, блоги и спецификации, мы уверены, что обмен передовым опытом имеет первостепенное значение и будет продвигать отрасль вперед.

Today we are sharing our Generation 4 Modular Data Center plan. This is our vision and will be the foundation of our cloud data center infrastructure in the next five years. We believe it is one of the most revolutionary changes to happen to data centers in the last 30 years. Joining me, in writing this blog are Daniel Costello, my director of Data Center Research and Engineering and Christian Belady, principal power and cooling architect. I feel their voices will add significant value to driving understanding around the many benefits included in this new design paradigm.

Сейчас мы хотим поделиться своим планом модульного дата-центра четвертого поколения. Это наше видение и оно будет основанием для инфраструктуры наших облачных дата-центров в ближайшие пять лет. Мы считаем, что это одно из самых революционных изменений в дата-центрах за последние 30 лет. Вместе со мной в написании этого блога участвовали Дэниел Костелло, директор по исследованиям и инжинирингу дата-центров, и Кристиан Белади, главный архитектор систем энергоснабжения и охлаждения. Мне кажется, что их авторитет придаст больше веса большому количеству преимуществ, включенных в эту новую парадигму проектирования.

Our “Gen 4” modular data centers will take the flexibility of containerized servers—like those in our Chicago data center—and apply it across the entire facility. So what do we mean by modular? Think of it like “building blocks”, where the data center will be composed of modular units of prefabricated mechanical, electrical, security components, etc., in addition to containerized servers.

Was there a key driver for the Generation 4 Data Center?

Наши модульные дата-центры “Gen 4” будут гибкими с контейнерами серверов – как серверы в нашем чикагском дата-центре. И гибкость будет применяться ко всему ЦОД. Итак, что мы подразумеваем под модульностью? Мы думаем о ней как о “строительных блоках”, где дата-центр будет состоять из модульных блоков изготовленных в заводских условиях электрических систем и систем охлаждения, а также систем безопасности и т.п., в дополнение к контейнеризованным серверам.
Был ли ключевой стимул для разработки дата-центра четвертого поколения?

If we were to summarize the promise of our Gen 4 design into a single sentence it would be something like this: “A highly modular, scalable, efficient, just-in-time data center capacity program that can be delivered anywhere in the world very quickly and cheaply, while allowing for continued growth as required.” Sounds too good to be true, doesn’t it? Well, keep in mind that these concepts have been in initial development and prototyping for over a year and are based on cumulative knowledge of previous facility generations and the advances we have made since we began our investments in earnest on this new design.

Если бы нам нужно было обобщить достоинства нашего проекта Gen 4 в одном предложении, это выглядело бы следующим образом: “Центр обработки данных с высоким уровнем модульности, расширяемости, и энергетической эффективности, а также возможностью постоянного расширения, в случае необходимости, который можно очень быстро и дешево развертывать в любом месте мира”. Звучит слишком хорошо для того чтобы быть правдой, не так ли? Ну, не забывайте, что эти концепции находились в процессе начальной разработки и создания опытного образца в течение более одного года и основываются на опыте, накопленном в ходе развития предыдущих поколений ЦОД, а также успехах, сделанных нами со времени, когда мы начали вкладывать серьезные средства в этот новый проект.

One of the biggest challenges we’ve had at Microsoft is something Mike likes to call the ‘Goldilock’s Problem’. In a nutshell, the problem can be stated as:

The worst thing we can do in delivering facilities for the business is not have enough capacity online, thus limiting the growth of our products and services.

Одну из самых больших проблем, с которыми приходилось сталкиваться Майкрософт, Майк любит называть ‘Проблемой Лютика’. Вкратце, эту проблему можно выразить следующим образом:

Самое худшее, что может быть при строительстве ЦОД для бизнеса, это не располагать достаточными производственными мощностями, и тем самым ограничивать рост наших продуктов и сервисов.

The second worst thing we can do in delivering facilities for the business is to have too much capacity online.

А вторым самым худшим моментом в этой сфере может слишком большое количество производственных мощностей.

This has led to a focus on smart, intelligent growth for the business — refining our overall demand picture. It can’t be too hot. It can’t be too cold. It has to be ‘Just Right!’ The capital dollars of investment are too large to make without long term planning. As we struggled to master these interesting challenges, we had to ensure that our technological plan also included solutions for the business and operational challenges we faced as well.
So let’s take a high level look at our Generation 4 design

Это заставило нас сосредоточиваться на интеллектуальном росте для бизнеса — refining our overall demand picture. Это не должно быть слишком горячим. И это не должно быть слишком холодным. Это должно быть ‘как раз, таким как надо!’ Нельзя делать такие большие капиталовложения без долгосрочного планирования. Пока мы старались решить эти интересные проблемы, мы должны были гарантировать, что наш технологический план будет также включать решения для коммерческих и эксплуатационных проблем, с которыми нам также приходилось сталкиваться.
Давайте рассмотрим наш проект дата-центра четвертого поколения

Are you ready for some great visuals? Check out this video at Soapbox. Click here for the Microsoft 4th Gen Video.

It’s a concept video that came out of my Data Center Research and Engineering team, under Daniel Costello, that will give you a view into what we think is the future.

From a configuration, construct-ability and time to market perspective, our primary goals and objectives are to modularize the whole data center. Not just the server side (like the Chicago facility), but the mechanical and electrical space as well. This means using the same kind of parts in pre-manufactured modules, the ability to use containers, skids, or rack-based deployments and the ability to tailor the Redundancy and Reliability requirements to the application at a very specific level.

Посмотрите это видео, перейдите по ссылке для просмотра видео о Microsoft 4th Gen:

Это концептуальное видео, созданное командой отдела Data Center Research and Engineering, возглавляемого Дэниелом Костелло, которое даст вам наше представление о будущем.

С точки зрения конфигурации, строительной технологичности и времени вывода на рынок, нашими главными целями и задачами агрегатирование всего дата-центра. Не только серверную часть, как дата-центр в Чикаго, но также системы охлаждения и электрические системы. Это означает применение деталей одного типа в сборных модулях, возможность использования контейнеров, салазок, или стоечных систем, а также возможность подстраивать требования избыточности и надежности для данного приложения на очень специфичном уровне.

Our goals from a cost perspective were simple in concept but tough to deliver. First and foremost, we had to reduce the capital cost per critical Mega Watt by the class of use. Some applications can run with N-level redundancy in the infrastructure, others require a little more infrastructure for support. These different classes of infrastructure requirements meant that optimizing for all cost classes was paramount. At Microsoft, we are not a one trick pony and have many Online products and services (240+) that require different levels of operational support. We understand that and ensured that we addressed it in our design which will allow us to reduce capital costs by 20%-40% or greater depending upon class.

Нашими целями в области затрат были концептуально простыми, но трудно реализуемыми. В первую очередь мы должны были снизить капитальные затраты в пересчете на один мегаватт, в зависимости от класса резервирования. Некоторые приложения могут вполне работать на базе инфраструктуры с резервированием на уровне N, то есть без резервирования, а для работы других приложений требуется больше инфраструктуры. Эти разные классы требований инфраструктуры подразумевали, что оптимизация всех классов затрат имеет преобладающее значение. В Майкрософт мы не ограничиваемся одним решением и располагаем большим количеством интерактивных продуктов и сервисов (240+), которым требуются разные уровни эксплуатационной поддержки. Мы понимаем это, и учитываем это в своем проекте, который позволит нам сокращать капитальные затраты на 20%-40% или более в зависимости от класса.

For example, non-critical or geo redundant applications have low hardware reliability requirements on a location basis. As a result, Gen 4 can be configured to provide stripped down, low-cost infrastructure with little or no redundancy and/or temperature control. Let’s say an Online service team decides that due to the dramatically lower cost, they will simply use uncontrolled outside air with temperatures ranging 10-35 C and 20-80% RH. The reality is we are already spec-ing this for all of our servers today and working with server vendors to broaden that range even further as Gen 4 becomes a reality. For this class of infrastructure, we eliminate generators, chillers, UPSs, and possibly lower costs relative to traditional infrastructure.

Например, некритичные или гео-избыточные системы имеют низкие требования к аппаратной надежности на основе местоположения. В результате этого, Gen 4 можно конфигурировать для упрощенной, недорогой инфраструктуры с низким уровнем (или вообще без резервирования) резервирования и / или температурного контроля. Скажем, команда интерактивного сервиса решает, что, в связи с намного меньшими затратами, они будут просто использовать некондиционированный наружный воздух с температурой 10-35°C и влажностью 20-80% RH. В реальности мы уже сегодня предъявляем эти требования к своим серверам и работаем с поставщиками серверов над еще большим расширением диапазона температур, так как наш модуль и подход Gen 4 становится реальностью. Для подобного класса инфраструктуры мы удаляем генераторы, чиллеры, ИБП, и, возможно, будем предлагать более низкие затраты, по сравнению с традиционной инфраструктурой.

Applications that demand higher level of redundancy or temperature control will use configurations of Gen 4 to meet those needs, however, they will also cost more (but still less than traditional data centers). We see this cost difference driving engineering behavioral change in that we predict more applications will drive towards Geo redundancy to lower costs.

Системы, которым требуется более высокий уровень резервирования или температурного контроля, будут использовать конфигурации Gen 4, отвечающие этим требованиям, однако, они будут также стоить больше. Но все равно они будут стоить меньше, чем традиционные дата-центры. Мы предвидим, что эти различия в затратах будут вызывать изменения в методах инжиниринга, и по нашим прогнозам, это будет выражаться в переходе все большего числа систем на гео-избыточность и меньшие затраты.

Another cool thing about Gen 4 is that it allows us to deploy capacity when our demand dictates it. Once finalized, we will no longer need to make large upfront investments. Imagine driving capital costs more closely in-line with actual demand, thus greatly reducing time-to-market and adding the capacity Online inherent in the design. Also reduced is the amount of construction labor required to put these “building blocks” together. Since the entire platform requires pre-manufacture of its core components, on-site construction costs are lowered. This allows us to maximize our return on invested capital.

Еще одно достоинство Gen 4 состоит в том, что он позволяет нам разворачивать дополнительные мощности, когда нам это необходимо. Как только мы закончим проект, нам больше не нужно будет делать большие начальные капиталовложения. Представьте себе возможность более точного согласования капитальных затрат с реальными требованиями, и тем самым значительного снижения времени вывода на рынок и интерактивного добавления мощностей, предусматриваемого проектом. Также снижен объем строительных работ, требуемых для сборки этих “строительных блоков”. Поскольку вся платформа требует предварительного изготовления ее базовых компонентов, затраты на сборку также снижены. Это позволит нам увеличить до максимума окупаемость своих капиталовложений.
Мы все подвергаем сомнению

In our design process, we questioned everything. You may notice there is no roof and some might be uncomfortable with this. We explored the need of one and throughout our research we got some surprising (positive) results that showed one wasn’t needed.

В своем процессе проектирования мы все подвергаем сомнению. Вы, наверное, обратили внимание на отсутствие крыши, и некоторым специалистам это могло не понравиться. Мы изучили необходимость в крыше и в ходе своих исследований получили удивительные результаты, которые показали, что крыша не нужна.
Серийное производство дата центров

In short, we are striving to bring Henry Ford’s Model T factory to the data center. http://en.wikipedia.org/wiki/Henry_Ford#Model_T. Gen 4 will move data centers from a custom design and build model to a commoditized manufacturing approach. We intend to have our components built in factories and then assemble them in one location (the data center site) very quickly. Think about how a computer, car or plane is built today. Components are manufactured by different companies all over the world to a predefined spec and then integrated in one location based on demands and feature requirements. And just like Henry Ford’s assembly line drove the cost of building and the time-to-market down dramatically for the automobile industry, we expect Gen 4 to do the same for data centers. Everything will be pre-manufactured and assembled on the pad.

Мы хотим применить модель автомобильной фабрики Генри Форда к дата-центру. Проект Gen 4 будет способствовать переходу от модели специализированного проектирования и строительства к товарно-производственному, серийному подходу. Мы намерены изготавливать свои компоненты на заводах, а затем очень быстро собирать их в одном месте, в месте строительства дата-центра. Подумайте о том, как сегодня изготавливается компьютер, автомобиль или самолет. Компоненты изготавливаются по заранее определенным спецификациям разными компаниями во всем мире, затем собираются в одном месте на основе спроса и требуемых характеристик. И точно так же как сборочный конвейер Генри Форда привел к значительному уменьшению затрат на производство и времени вывода на рынок в автомобильной промышленности, мы надеемся, что Gen 4 сделает то же самое для дата-центров. Все будет предварительно изготавливаться и собираться на месте.
Невероятно энергоэффективный ЦОД

And did we mention that this platform will be, overall, incredibly energy efficient? From a total energy perspective not only will we have remarkable PUE values, but the total cost of energy going into the facility will be greatly reduced as well. How much energy goes into making concrete? Will we need as much of it? How much energy goes into the fuel of the construction vehicles? This will also be greatly reduced! A key driver is our goal to achieve an average PUE at or below 1.125 by 2012 across our data centers. More than that, we are on a mission to reduce the overall amount of copper and water used in these facilities. We believe these will be the next areas of industry attention when and if the energy problem is solved. So we are asking today…“how can we build a data center with less building”?

А мы упоминали, что эта платформа будет, в общем, невероятно энергоэффективной? С точки зрения общей энергии, мы получим не только поразительные значения PUE, но общая стоимость энергии, затраченной на объект будет также значительно снижена. Сколько энергии идет на производство бетона? Нам нужно будет столько энергии? Сколько энергии идет на питание инженерных строительных машин? Это тоже будет значительно снижено! Главным стимулом является достижение среднего PUE не больше 1.125 для всех наших дата-центров к 2012 году. Более того, у нас есть задача сокращения общего количества меди и воды в дата-центрах. Мы думаем, что эти задачи станут следующей заботой отрасли после того как будет решена энергетическая проблема. Итак, сегодня мы спрашиваем себя…“как можно построить дата-центр с меньшим объемом строительных работ”?
Строительство дата центров без чиллеров

We have talked openly and publicly about building chiller-less data centers and running our facilities using aggressive outside economization. Our sincerest hope is that Gen 4 will completely eliminate the use of water. Today’s data centers use massive amounts of water and we see water as the next scarce resource and have decided to take a proactive stance on making water conservation part of our plan.

Мы открыто и публично говорили о строительстве дата-центров без чиллеров и активном использовании в наших центрах обработки данных технологий свободного охлаждения или фрикулинга. Мы искренне надеемся, что Gen 4 позволит полностью отказаться от использования воды. Современные дата-центры расходуют большие объемы воды и так как мы считаем воду следующим редким ресурсом, мы решили принять упреждающие меры и включить экономию воды в свой план.

By sharing this with the industry, we believe everyone can benefit from our methodology. While this concept and approach may be intimidating (or downright frightening) to some in the industry, disclosure ultimately is better for all of us.

Делясь этим опытом с отраслью, мы считаем, что каждый сможет извлечь выгоду из нашей методологией. Хотя эта концепция и подход могут показаться пугающими (или откровенно страшными) для некоторых отраслевых специалистов, раскрывая свои планы мы, в конечном счете, делаем лучше для всех нас.

Gen 4 design (even more than just containers), could reduce the ‘religious’ debates in our industry. With the central spine infrastructure in place, containers or pre-manufactured server halls can be either AC or DC, air-side economized or water-side economized, or not economized at all (though the sanity of that might be questioned). Gen 4 will allow us to decommission, repair and upgrade quickly because everything is modular. No longer will we be governed by the initial decisions made when constructing the facility. We will have almost unlimited use and re-use of the facility and site. We will also be able to use power in an ultra-fluid fashion moving load from critical to non-critical as use and capacity requirements dictate.

Проект Gen 4 позволит уменьшить ‘религиозные’ споры в нашей отрасли. Располагая базовой инфраструктурой, контейнеры или сборные серверные могут оборудоваться системами переменного или постоянного тока, воздушными или водяными экономайзерами, или вообще не использовать экономайзеры. Хотя можно подвергать сомнению разумность такого решения. Gen 4 позволит нам быстро выполнять работы по выводу из эксплуатации, ремонту и модернизации, поскольку все будет модульным. Мы больше не будем руководствоваться начальными решениями, принятыми во время строительства дата-центра. Мы сможем использовать этот дата-центр и инфраструктуру в течение почти неограниченного периода времени. Мы также сможем применять сверхгибкие методы использования электрической энергии, переводя оборудование в режимы критической или некритической нагрузки в соответствии с требуемой мощностью.
Gen 4 – это стандартная платформа

Finally, we believe this is a big game changer. Gen 4 will provide a standard platform that our industry can innovate around. For example, all modules in our Gen 4 will have common interfaces clearly defined by our specs and any vendor that meets these specifications will be able to plug into our infrastructure. Whether you are a computer vendor, UPS vendor, generator vendor, etc., you will be able to plug and play into our infrastructure. This means we can also source anyone, anywhere on the globe to minimize costs and maximize performance. We want to help motivate the industry to further innovate—with innovations from which everyone can reap the benefits.

Наконец, мы уверены, что это будет фактором, который значительно изменит ситуацию. Gen 4 будет представлять собой стандартную платформу, которую отрасль сможет обновлять. Например, все модули в нашем Gen 4 будут иметь общепринятые интерфейсы, четко определяемые нашими спецификациями, и оборудование любого поставщика, которое отвечает этим спецификациям можно будет включать в нашу инфраструктуру. Независимо от того производите вы компьютеры, ИБП, генераторы и т.п., вы сможете включать свое оборудование нашу инфраструктуру. Это означает, что мы также сможем обеспечивать всех, в любом месте земного шара, тем самым сводя до минимума затраты и максимальной увеличивая производительность. Мы хотим создать в отрасли мотивацию для дальнейших инноваций – инноваций, от которых каждый сможет получать выгоду.
Главные характеристики дата-центров четвертого поколения Gen4

To summarize, the key characteristics of our Generation 4 data centers are:

Scalable
Plug-and-play spine infrastructure
Factory pre-assembled: Pre-Assembled Containers (PACs) & Pre-Manufactured Buildings (PMBs)
Rapid deployment
De-mountable
Reduce TTM
Reduced construction
Sustainable measures

Ниже приведены главные характеристики дата-центров четвертого поколения Gen 4:

Расширяемость;
Готовая к использованию базовая инфраструктура;
Изготовление в заводских условиях: сборные контейнеры (PAC) и сборные здания (PMB);
Быстрота развертывания;
Возможность демонтажа;
Снижение времени вывода на рынок (TTM);
Сокращение сроков строительства;
Экологичность;

Map applications to DC Class

We hope you join us on this incredible journey of change and innovation!

Long hours of research and engineering time are invested into this process. There are still some long days and nights ahead, but the vision is clear. Rest assured however, that we as refine Generation 4, the team will soon be looking to Generation 5 (even if it is a bit farther out). There is always room to get better.

Использование систем электропитания постоянного тока.

Мы надеемся, что вы присоединитесь к нам в этом невероятном путешествии по миру изменений и инноваций!

На этот проект уже потрачены долгие часы исследований и проектирования. И еще предстоит потратить много дней и ночей, но мы имеем четкое представление о конечной цели. Однако будьте уверены, что как только мы доведем до конца проект модульного дата-центра четвертого поколения, мы вскоре начнем думать о проекте дата-центра пятого поколения. Всегда есть возможность для улучшений.

So if you happen to come across Goldilocks in the forest, and you are curious as to why she is smiling you will know that she feels very good about getting very close to ‘JUST RIGHT’.

Generations of Evolution – some background on our data center designs

Так что, если вы встретите в лесу девочку по имени Лютик, и вам станет любопытно, почему она улыбается, вы будете знать, что она очень довольна тем, что очень близко подошла к ‘ОПИМАЛЬНОМУ РЕШЕНИЮ’.
Поколения эволюции – история развития наших дата-центров

We thought you might be interested in understanding what happened in the first three generations of our data center designs. When Ray Ozzie wrote his Software plus Services memo it posed a very interesting challenge to us. The winds of change were at ‘tornado’ proportions. That “plus Services” tag had some significant (and unstated) challenges inherent to it. The first was that Microsoft was going to evolve even further into an operations company. While we had been running large scale Internet services since 1995, this development lead us to an entirely new level. Additionally, these “services” would span across both Internet and Enterprise businesses. To those of you who have to operate “stuff”, you know that these are two very different worlds in operational models and challenges. It also meant that, to achieve the same level of reliability and performance required our infrastructure was going to have to scale globally and in a significant way.

Мы подумали, что может быть вам будет интересно узнать историю первых трех поколений наших центров обработки данных. Когда Рэй Оззи написал свою памятную записку Software plus Services, он поставил перед нами очень интересную задачу. Ветра перемен двигались с ураганной скоростью. Это окончание “plus Services” скрывало в себе какие-то значительные и неопределенные задачи. Первая заключалась в том, что Майкрософт собиралась в еще большей степени стать операционной компанией. Несмотря на то, что мы управляли большими интернет-сервисами, начиная с 1995 г., эта разработка подняла нас на абсолютно новый уровень. Кроме того, эти “сервисы” охватывали интернет-компании и корпорации. Тем, кому приходится всем этим управлять, известно, что есть два очень разных мира в области операционных моделей и задач. Это также означало, что для достижения такого же уровня надежности и производительности требовалось, чтобы наша инфраструктура располагала значительными возможностями расширения в глобальных масштабах.

It was that intense atmosphere of change that we first started re-evaluating data center technology and processes in general and our ideas began to reach farther than what was accepted by the industry at large. This was the era of Generation 1. As we look at where most of the world’s data centers are today (and where our facilities were), it represented all the known learning and design requirements that had been in place since IBM built the first purpose-built computer room. These facilities focused more around uptime, reliability and redundancy. Big infrastructure was held accountable to solve all potential environmental shortfalls. This is where the majority of infrastructure in the industry still is today.

Именно в этой атмосфере серьезных изменений мы впервые начали переоценку ЦОД-технологий и технологий вообще, и наши идеи начали выходить за пределы общепринятых в отрасли представлений. Это была эпоха ЦОД первого поколения. Когда мы узнали, где сегодня располагается большинство мировых дата-центров и где находятся наши предприятия, это представляло весь опыт и навыки проектирования, накопленные со времени, когда IBM построила первую серверную. В этих ЦОД больше внимания уделялось бесперебойной работе, надежности и резервированию. Большая инфраструктура была призвана решать все потенциальные экологические проблемы. Сегодня большая часть инфраструктуры все еще находится на этом этапе своего развития.

We soon realized that traditional data centers were quickly becoming outdated. They were not keeping up with the demands of what was happening technologically and environmentally. That’s when we kicked off our Generation 2 design. Gen 2 facilities started taking into account sustainability, energy efficiency, and really looking at the total cost of energy and operations.

Очень быстро мы поняли, что стандартные дата-центры очень быстро становятся устаревшими. Они не поспевали за темпами изменений технологических и экологических требований. Именно тогда мы стали разрабатывать ЦОД второго поколения. В этих дата-центрах Gen 2 стали принимать во внимание такие факторы как устойчивое развитие, энергетическая эффективность, а также общие энергетические и эксплуатационные.

No longer did we view data centers just for the upfront capital costs, but we took a hard look at the facility over the course of its life. Our Quincy, Washington and San Antonio, Texas facilities are examples of our Gen 2 data centers where we explored and implemented new ways to lessen the impact on the environment. These facilities are considered two leading industry examples, based on their energy efficiency and ability to run and operate at new levels of scale and performance by leveraging clean hydro power (Quincy) and recycled waste water (San Antonio) to cool the facility during peak cooling months.

Мы больше не рассматривали дата-центры только с точки зрения начальных капитальных затрат, а внимательно следили за работой ЦОД на протяжении его срока службы. Наши объекты в Куинси, Вашингтоне, и Сан-Антонио, Техас, являются образцами наших ЦОД второго поколения, в которых мы изучали и применяли на практике новые способы снижения воздействия на окружающую среду. Эти объекты считаются двумя ведущими отраслевыми примерами, исходя из их энергетической эффективности и способности работать на новых уровнях производительности, основанных на использовании чистой энергии воды (Куинси) и рециклирования отработанной воды (Сан-Антонио) для охлаждения объекта в самых жарких месяцах.

As we were delivering our Gen 2 facilities into steel and concrete, our Generation 3 facilities were rapidly driving the evolution of the program. The key concepts for our Gen 3 design are increased modularity and greater concentration around energy efficiency and scale. The Gen 3 facility will be best represented by the Chicago, Illinois facility currently under construction. This facility will seem very foreign compared to the traditional data center concepts most of the industry is comfortable with. In fact, if you ever sit around in our container hanger in Chicago it will look incredibly different from a traditional raised-floor data center. We anticipate this modularization will drive huge efficiencies in terms of cost and operations for our business. We will also introduce significant changes in the environmental systems used to run our facilities. These concepts and processes (where applicable) will help us gain even greater efficiencies in our existing footprint, allowing us to further maximize infrastructure investments.

Так как наши ЦОД второго поколения строились из стали и бетона, наши центры обработки данных третьего поколения начали их быстро вытеснять. Главными концептуальными особенностями ЦОД третьего поколения Gen 3 являются повышенная модульность и большее внимание к энергетической эффективности и масштабированию. Дата-центры третьего поколения лучше всего представлены объектом, который в настоящее время строится в Чикаго, Иллинойс. Этот ЦОД будет выглядеть очень необычно, по сравнению с общепринятыми в отрасли представлениями о дата-центре. Действительно, если вам когда-либо удастся побывать в нашем контейнерном ангаре в Чикаго, он покажется вам совершенно непохожим на обычный дата-центр с фальшполом. Мы предполагаем, что этот модульный подход будет способствовать значительному повышению эффективности нашего бизнеса в отношении затрат и операций. Мы также внесем существенные изменения в климатические системы, используемые в наших ЦОД. Эти концепции и технологии, если применимо, позволят нам добиться еще большей эффективности наших существующих дата-центров, и тем самым еще больше увеличивать капиталовложения в инфраструктуру.

This is definitely a journey, not a destination industry. In fact, our Generation 4 design has been under heavy engineering for viability and cost for over a year. While the demand of our commercial growth required us to make investments as we grew, we treated each step in the learning as a process for further innovation in data centers. The design for our future Gen 4 facilities enabled us to make visionary advances that addressed the challenges of building, running, and operating facilities all in one concerted effort.

Это определенно путешествие, а не конечный пункт назначения. На самом деле, наш проект ЦОД четвертого поколения подвергался серьезным испытаниям на жизнеспособность и затраты на протяжении целого года. Хотя необходимость в коммерческом росте требовала от нас постоянных капиталовложений, мы рассматривали каждый этап своего развития как шаг к будущим инновациям в области дата-центров. Проект наших будущих ЦОД четвертого поколения Gen 4 позволил нам делать фантастические предположения, которые касались задач строительства, управления и эксплуатации объектов как единого упорядоченного процесса.

Тематики

• ЦОДы (центры обработки данных)

Синонимы

• модульный ЦОД

EN

• modular data center

Artificial Intelligence

   1) Programs and the Complexity of Human Mental Processes

   In my opinion, none of [these programs] does even remote justice to the complexity of human mental processes. Unlike men, "artificially intelligent" programs tend to be single minded, undistractable, and unemotional. (Neisser, 1967, p. 9)

   2) Artificial Intelligence Is an Engineering Discipline

   Future progress in [artificial intelligence] will depend on the development of both practical and theoretical knowledge.... As regards theoretical knowledge, some have sought a unified theory of artificial intelligence. My view is that artificial intelligence is (or soon will be) an engineering discipline since its primary goal is to build things. (Nilsson, 1971, pp. vii-viii)

   3) A Sceptical View of Artificial Intelligence

   Most workers in AI [artificial intelligence] research and in related fields confess to a pronounced feeling of disappointment in what has been achieved in the last 25 years. Workers entered the field around 1950, and even around 1960, with high hopes that are very far from being realized in 1972. In no part of the field have the discoveries made so far produced the major impact that was then promised.... In the meantime, claims and predictions regarding the potential results of AI research had been publicized which went even farther than the expectations of the majority of workers in the field, whose embarrassments have been added to by the lamentable failure of such inflated predictions....

   When able and respected scientists write in letters to the present author that AI, the major goal of computing science, represents "another step in the general process of evolution"; that possibilities in the 1980s include an all-purpose intelligence on a human-scale knowledge base; that awe-inspiring possibilities suggest themselves based on machine intelligence exceeding human intelligence by the year 2000 [one has the right to be skeptical]. (Lighthill, 1972, p. 17)

   4) Just as Astronomy Succeeded Astrology, the Discovery of Intellectual Processes in Machines Should Lead to a Science, Eventually

   Just as astronomy succeeded astrology, following Kepler's discovery of planetary regularities, the discoveries of these many principles in empirical explorations on intellectual processes in machines should lead to a science, eventually. (Minsky & Papert, 1973, p. 11)

   5) Problems in Machine Intelligence Arise Because Things Obvious to Any Person Are Not Represented in the Program

   Many problems arise in experiments on machine intelligence because things obvious to any person are not represented in any program. One can pull with a string, but one cannot push with one.... Simple facts like these caused serious problems when Charniak attempted to extend Bobrow's "Student" program to more realistic applications, and they have not been faced up to until now. (Minsky & Papert, 1973, p. 77)

   6) The Meaning of a Symbolic Description

   What do we mean by [a symbolic] "description"? We do not mean to suggest that our descriptions must be made of strings of ordinary language words (although they might be). The simplest kind of description is a structure in which some features of a situation are represented by single ("primitive") symbols, and relations between those features are represented by other symbols-or by other features of the way the description is put together. (Minsky & Papert, 1973, p. 11)

   7) The Principle of Artificial Intelligence

   [AI is] the use of computer programs and programming techniques to cast light on the principles of intelligence in general and human thought in particular. (Boden, 1977, p. 5)

   8) Artificial Intelligence Recognizes the Need for Knowledge in Its Systems

   The word you look for and hardly ever see in the early AI literature is the word knowledge. They didn't believe you have to know anything, you could always rework it all.... In fact 1967 is the turning point in my mind when there was enough feeling that the old ideas of general principles had to go.... I came up with an argument for what I called the primacy of expertise, and at the time I called the other guys the generalists. (Moses, quoted in McCorduck, 1979, pp. 228-229)

   9) Artificial Intelligence Is Psychology in a Particularly Pure and Abstract Form

   The basic idea of cognitive science is that intelligent beings are semantic engines-in other words, automatic formal systems with interpretations under which they consistently make sense. We can now see why this includes psychology and artificial intelligence on a more or less equal footing: people and intelligent computers (if and when there are any) turn out to be merely different manifestations of the same underlying phenomenon. Moreover, with universal hardware, any semantic engine can in principle be formally imitated by a computer if only the right program can be found. And that will guarantee semantic imitation as well, since (given the appropriate formal behavior) the semantics is "taking care of itself" anyway. Thus we also see why, from this perspective, artificial intelligence can be regarded as psychology in a particularly pure and abstract form. The same fundamental structures are under investigation, but in AI, all the relevant parameters are under direct experimental control (in the programming), without any messy physiology or ethics to get in the way. (Haugeland, 1981b, p. 31)

    10) There Are Many Types of Reasoning

   There are many different kinds of reasoning one might imagine:

    Formal reasoning involves the syntactic manipulation of data structures to deduce new ones following prespecified rules of inference. Mathematical logic is the archetypical formal representation. Procedural reasoning uses simulation to answer questions and solve problems. When we use a program to answer What is the sum of 3 and 4? it uses, or "runs," a procedural model of arithmetic. Reasoning by analogy seems to be a very natural mode of thought for humans but, so far, difficult to accomplish in AI programs. The idea is that when you ask the question Can robins fly? the system might reason that "robins are like sparrows, and I know that sparrows can fly, so robins probably can fly."

    Generalization and abstraction are also natural reasoning process for humans that are difficult to pin down well enough to implement in a program. If one knows that Robins have wings, that Sparrows have wings, and that Blue jays have wings, eventually one will believe that All birds have wings. This capability may be at the core of most human learning, but it has not yet become a useful technique in AI.... Meta- level reasoning is demonstrated by the way one answers the question What is Paul Newman's telephone number? You might reason that "if I knew Paul Newman's number, I would know that I knew it, because it is a notable fact." This involves using "knowledge about what you know," in particular, about the extent of your knowledge and about the importance of certain facts. Recent research in psychology and AI indicates that meta-level reasoning may play a central role in human cognitive processing. (Barr & Feigenbaum, 1981, pp. 146-147)

    11) Programs Are Beginning to Do Things That Critics Have Asserted to Be Impossible

   Suffice it to say that programs already exist that can do things-or, at the very least, appear to be beginning to do things-which ill-informed critics have asserted a priori to be impossible. Examples include: perceiving in a holistic as opposed to an atomistic way; using language creatively; translating sensibly from one language to another by way of a language-neutral semantic representation; planning acts in a broad and sketchy fashion, the details being decided only in execution; distinguishing between different species of emotional reaction according to the psychological context of the subject. (Boden, 1981, p. 33)

    12) The Synthesis of Man and Machine

   Can the synthesis of Man and Machine ever be stable, or will the purely organic component become such a hindrance that it has to be discarded? If this eventually happens-and I have... good reasons for thinking that it must-we have nothing to regret and certainly nothing to fear. (Clarke, 1984, p. 243)

    13) The Thesis of Good Old-Fashioned Artificial Intelligence (GOFAI)

   The thesis of GOFAI... is not that the processes underlying intelligence can be described symbolically... but that they are symbolic. (Haugeland, 1985, p. 113)

    14) Artificial Intelligence Provides a Useful Approach to Psychological and Psychiatric Theory Formation

   It is all very well formulating psychological and psychiatric theories verbally but, when using natural language (even technical jargon), it is difficult to recognise when a theory is complete; oversights are all too easily made, gaps too readily left. This is a point which is generally recognised to be true and it is for precisely this reason that the behavioural sciences attempt to follow the natural sciences in using "classical" mathematics as a more rigorous descriptive language. However, it is an unfortunate fact that, with a few notable exceptions, there has been a marked lack of success in this application. It is my belief that a different approach-a different mathematics-is needed, and that AI provides just this approach. (Hand, quoted in Hand, 1985, pp. 6-7)

    15) Four Kinds of Artificial Intelligence

   We might distinguish among four kinds of AI.

   ♦ Nonpsychological AI

   Research of this kind involves building and programming computers to perform tasks which, to paraphrase Marvin Minsky, would require intelligence if they were done by us. Researchers in nonpsychological AI make no claims whatsoever about the psychological realism of their programs or the devices they build, that is, about whether or not computers perform tasks as humans do.

   ♦ Weak Psychological AI

   Research here is guided by the view that the computer is a useful tool in the study of mind. In particular, we can write computer programs or build devices that simulate alleged psychological processes in humans and then test our predictions about how the alleged processes work. We can weave these programs and devices together with other programs and devices that simulate different alleged mental processes and thereby test the degree to which the AI system as a whole simulates human mentality. According to weak psychological AI, working with computer models is a way of refining and testing hypotheses about processes that are allegedly realized in human minds.

   ♦ Strong Psychological AI

... According to this view, our minds are computers and therefore can be duplicated by other computers. Sherry Turkle writes that the "real ambition is of mythic proportions, making a general purpose intelligence, a mind." (Turkle, 1984, p. 240) The authors of a major text announce that "the ultimate goal of AI research is to build a person or, more humbly, an animal." (Charniak & McDermott, 1985, p. 7)

   ♦ Suprapsychological AI

   Research in this field, like strong psychological AI, takes seriously the functionalist view that mentality can be realized in many different types of physical devices. Suprapsychological AI, however, accuses strong psychological AI of being chauvinisticof being only interested in human intelligence! Suprapsychological AI claims to be interested in all the conceivable ways intelligence can be realized. (Flanagan, 1991, pp. 241-242)

    16) Determination of Relevance of Rules in Particular Contexts

   Even if the [rules] were stored in a context-free form the computer still couldn't use them. To do that the computer requires rules enabling it to draw on just those [ rules] which are relevant in each particular context. Determination of relevance will have to be based on further facts and rules, but the question will again arise as to which facts and rules are relevant for making each particular determination. One could always invoke further facts and rules to answer this question, but of course these must be only the relevant ones. And so it goes. It seems that AI workers will never be able to get started here unless they can settle the problem of relevance beforehand by cataloguing types of context and listing just those facts which are relevant in each. (Dreyfus & Dreyfus, 1986, p. 80)

    17) Form and Content Are Not Fundamentally Different

   Perhaps the single most important idea to artificial intelligence is that there is no fundamental difference between form and content, that meaning can be captured in a set of symbols such as a semantic net. (G. Johnson, 1986, p. 250)

    18) The Assumption That the Mind Is a Formal System

   Artificial intelligence is based on the assumption that the mind can be described as some kind of formal system manipulating symbols that stand for things in the world. Thus it doesn't matter what the brain is made of, or what it uses for tokens in the great game of thinking. Using an equivalent set of tokens and rules, we can do thinking with a digital computer, just as we can play chess using cups, salt and pepper shakers, knives, forks, and spoons. Using the right software, one system (the mind) can be mapped into the other (the computer). (G. Johnson, 1986, p. 250)

    19) A Statement of the Primary and Secondary Purposes of Artificial Intelligence

   The primary goal of Artificial Intelligence is to make machines smarter.

   The secondary goals of Artificial Intelligence are to understand what intelligence is (the Nobel laureate purpose) and to make machines more useful (the entrepreneurial purpose). (Winston, 1987, p. 1)

    20) Mathematical Logic Provides the Basis for Theory in AI

   The theoretical ideas of older branches of engineering are captured in the language of mathematics. We contend that mathematical logic provides the basis for theory in AI. Although many computer scientists already count logic as fundamental to computer science in general, we put forward an even stronger form of the logic-is-important argument....

   AI deals mainly with the problem of representing and using declarative (as opposed to procedural) knowledge. Declarative knowledge is the kind that is expressed as sentences, and AI needs a language in which to state these sentences. Because the languages in which this knowledge usually is originally captured (natural languages such as English) are not suitable for computer representations, some other language with the appropriate properties must be used. It turns out, we think, that the appropriate properties include at least those that have been uppermost in the minds of logicians in their development of logical languages such as the predicate calculus. Thus, we think that any language for expressing knowledge in AI systems must be at least as expressive as the first-order predicate calculus. (Genesereth & Nilsson, 1987, p. viii)

    21) Perceptual Structures Can Be Represented as Lists of Elementary Propositions

   In artificial intelligence studies, perceptual structures are represented as assemblages of description lists, the elementary components of which are propositions asserting that certain relations hold among elements. (Chase & Simon, 1988, p. 490)

    22) Definitions of Artificial Intelligence

   Artificial intelligence (AI) is sometimes defined as the study of how to build and/or program computers to enable them to do the sorts of things that minds can do. Some of these things are commonly regarded as requiring intelligence: offering a medical diagnosis and/or prescription, giving legal or scientific advice, proving theorems in logic or mathematics. Others are not, because they can be done by all normal adults irrespective of educational background (and sometimes by non-human animals too), and typically involve no conscious control: seeing things in sunlight and shadows, finding a path through cluttered terrain, fitting pegs into holes, speaking one's own native tongue, and using one's common sense. Because it covers AI research dealing with both these classes of mental capacity, this definition is preferable to one describing AI as making computers do "things that would require intelligence if done by people." However, it presupposes that computers could do what minds can do, that they might really diagnose, advise, infer, and understand. One could avoid this problematic assumption (and also side-step questions about whether computers do things in the same way as we do) by defining AI instead as "the development of computers whose observable performance has features which in humans we would attribute to mental processes." This bland characterization would be acceptable to some AI workers, especially amongst those focusing on the production of technological tools for commercial purposes. But many others would favour a more controversial definition, seeing AI as the science of intelligence in general-or, more accurately, as the intellectual core of cognitive science. As such, its goal is to provide a systematic theory that can explain (and perhaps enable us to replicate) both the general categories of intentionality and the diverse psychological capacities grounded in them. (Boden, 1990b, pp. 1-2)

    23) The Computer Can Not Be a Model of the Mind

   Because the ability to store data somewhat corresponds to what we call memory in human beings, and because the ability to follow logical procedures somewhat corresponds to what we call reasoning in human beings, many members of the cult have concluded that what computers do somewhat corresponds to what we call thinking. It is no great difficulty to persuade the general public of that conclusion since computers process data very fast in small spaces well below the level of visibility; they do not look like other machines when they are at work. They seem to be running along as smoothly and silently as the brain does when it remembers and reasons and thinks. On the other hand, those who design and build computers know exactly how the machines are working down in the hidden depths of their semiconductors. Computers can be taken apart, scrutinized, and put back together. Their activities can be tracked, analyzed, measured, and thus clearly understood-which is far from possible with the brain. This gives rise to the tempting assumption on the part of the builders and designers that computers can tell us something about brains, indeed, that the computer can serve as a model of the mind, which then comes to be seen as some manner of information processing machine, and possibly not as good at the job as the machine. (Roszak, 1994, pp. xiv-xv)

    24) Computers Will Not Always Be Inferior to Human Brains

   The inner workings of the human mind are far more intricate than the most complicated systems of modern technology. Researchers in the field of artificial intelligence have been attempting to develop programs that will enable computers to display intelligent behavior. Although this field has been an active one for more than thirty-five years and has had many notable successes, AI researchers still do not know how to create a program that matches human intelligence. No existing program can recall facts, solve problems, reason, learn, and process language with human facility. This lack of success has occurred not because computers are inferior to human brains but rather because we do not yet know in sufficient detail how intelligence is organized in the brain. (Anderson, 1995, p. 2)

CA

1) Общая лексика: канада, примерно, Corporate Affairs (SEIC), рак (заболевание)

2) Компьютерная техника: Clip Art, Collision Avoidance, Computer Accuracy, Computer Aided

3) Авиация: cabin address

4) Медицина: Углеводный раковый антиген (онкомаркер) (carbohydrate antigen), (Chief Administrator) главный администратор, активация соударением (в масс-спектрометрии) (Collisional Activation)

5) Американизм: Clean Air, Continuous Assessment

6) Военный термин: COMSEC Account, Can't Add, Canadian Army, Combat Arms, Combat Assessment, Command Authority, Commercial Activities, Common Applications, Communication Area, Complete Annihilation, Comptroller of the Army, Confederate Army, Configuration Audit, Controller of Aircraft, Controlling Authority, Crewman's Associate, Cryptanalysis, Heavy Cruiser, chief accountant, civic action, civil administration, civil affairs, civil aircraft, civil applications, civil authorities, closest approach, coast artillery, coaxial, combat actions, combat aircrew, combat aptitude, combat assault, combined arms, command accountant, command action, commandant assistant, commitment authorization, component analysis, concealed aircraft, contingencies of the Army, contract administration, contract authorization, contract award, control assembly, control augmentation, controlled airspace, corps area, correct or amplify, corrective action, cost analysis, cost of arms, counterair, court of appeal, cumulative amount

7) Психиатрия: cateholamine

8) Техника: Cassegrain antenna, capacitor, cascade amplifier, certified accountant, channel adapter, channel address, channel amplifier, charge amplifier, chicken adenovirus, chopper amplifier, circular array, clipping amplifier, clutter attenuation, computer assembly, computer-aided, constant amplitude, construction authorization, control air, course angle, critical assembly, cylindrical array, sonar commutator assembly, полный угол (Complete Angle)

9) Сельское хозяйство: carotid artery

10) Шутливое выражение: Constant Acquisitions

11) Химия: Carbon Alpha, Cinnamic Acid, Chemical Abstracts

12) Железнодорожный термин: Chesapeake and Albemarle Railroad

13) Бухгалтерия: capital allowance, chargeable assets

14) Грубое выражение: Candy Ass, Chic Anonymous, Computer Assholes

15) География: Калифорния

16) Оптика: clear aperture

17) Политика: Canada

18) Телекоммуникации: (certification authority) сертифицирующая организация, (certification authority) сертифицирующее агентство, (certification authority) сертифицирующее ведомство, (certification authority) сертифицирующий орган, (certification authority) центр сертификации

19) Сокращение: Canada A, Canadian Authors' Association, Catalan, Charge d'Affaires, Chartered Accountant, Chronological Age, Civil Aviation, Coastal Artillery, College of Arms, Concentric Action, Conformal-array Aerial, Consumers'Association, Controller Aircraft, Controller of Accounts, Crank Angle, Bromobenzyl cyanide (Chemical warfare agent), Canada (NATO country code), California (US state), Gun Cruiser (USA), Compania Anonima (Venezuela), Collision Avoidance (as in CSMA/CA (q.v.))

20) Физиология: Caucasian adult, Cooley's Anemia, Coronary Artery

21) Электроника: CIM architecture, Common Amplification

22) Вычислительная техника: Computer Animation, certificate authority, common application, current awareness, Cell Arrival (ATM), Computer Associates (Hersteller), Certification Authority (Verschluesselung, PKI), Collision Avoidance (as in CSMA/CA), computer associates

23) Нефть: elevation correction

24) Кардиология: common atrium (общее предсердие)

25) Биохимия: Chromic Acid

26) Онкология: Cancer Antigen, Cancer Associated

27) Картография: catchment area

28) Банковское дело: текущий банковский счёт (current account)

29) Транспорт: Cab To Axle, Conflict Alert, Contract Air

30) Фирменный знак: Carrier, Continental Accessories

31) Холодильная техника: controlled atmosphere

32) Энергетика: Contingency Analysis, система, позволяющая просчитать возможность возникновения аварийных ситуаций на стадии планирования режимов

33) СМИ: Creatures Adventures

34) Деловая лексика: Card Advantage, Circa About, дипломированный бухгалтер высшей квалификации (chartered accountant), присяжный бухгалтер (chartered accountant)

35) Глоссарий компании Сахалин Энерджи: Construction Assistance

36) Образование: Cultural Awareness

37) Инвестиции: Court of Appeals, current account

38) Сетевые технологии: Channel Access, Client Active, Continuous Access, communication adapter, коммуникационный адаптер

39) Полимеры: cellulose acetate, chlorendic anhydride, continuity additive ( агент непрерывности)

40) Программирование: Clear All

41) Контроль качества: ПЗ

42) Пластмассы: Cyanoacrylate Adhesive

43) Сахалин Р: Certifying Authority, Contract Amendments

44) Сахалин А: corrosion allowance

45) Химическое оружие: chemical warfare agents, chemical warfare agents munition, combustion air, cost account, criticality analysis, сhemical agent

46) Безопасность: Conditional Access

47) Расширение файла: Certification Authority, Initial cache data for root domain servers (Telnet)

48) SAP.тех. контрольная область

49) Нефть и газ: Central Asia

50) Электротехника: contact ammeter

51) США: California

52) Майкрософт: центр сертификации

53) Должность: Canada As, Cartoon Artist, Cognitive Apprenticeship, Community Associate, Computer Assistant

54) NYSE. Computer Associates International, Inc.

55) Единицы измерений: Cranking Amperes

56) Общая лексика: competent authority

CAC

1) Общая лексика: Collective action clause

2) Военный термин: Central Advisory Council, Civil Administration Committee, Civil Affairs Command, Common Access Card, Continental Air Command, Continental Army Command, U.S. Army Combined Arms Command, chief artillery controller, civic action center, clear all channels, combat air command, combat aircrew, combined action company, combined arms center, command analysis center, command and control, computer-aided classification, constant alert cycle, contract administration control, contract award committee, control and analysis center, control and coordination, cooperation and coordination, current action center, Combined Arms Center (formerly Combined Arms Command), command aviation company

3) Техника: California Arts Council, Contemporary Arts Center, changing to approach control, contact area commander, containment atmosphere control, control air compressor, УДЦ, Учебно-демонстрационный центр, Customer Application Center

4) Строительство: центральная система кондиционирования воздуха

5) Страхование: Cost and charges

6) Металлургия: carbon-arc cutting

7) Сокращение: Canadian Armoured Corps, Capital Area Conference, Central Advisory Committee, Chengdu Aircraft Industry Corp. (China), City Administration Center, Coast Artillery Corps, Coastal Artillery Computer, Combat Air Crew, Combat Assessment Capability, Combined Arms Center (USA), Consumer Advisory Council, Consumer Affairs Council, Consumer Association of Canada, Control & Analysis Center (USA), Corrective Action Code (address list, 2006, works with CARL), County Administration Centre, Custom Armoring Corp. (USA), Chroma Amplitude Corrector, Codex Alimentarius Commission, CECOM (Army Communications and Electronics Command) Acquisition Center (US Army), CableAmerica Corporation, Cache File, Cadet Advisory Council, Cairo American College (Egypt), Calculated Age at Commencement (UK criminal system; mainly prison & probation services), California Acupuncture College, California Administrative Code, California Apple Commission, California Asparagus Commission, California Association of Criminalists, California Avocado Commission, Call Access Control, Call Admission Control, Calling All Cars (Playstation 3 game), Calling-Card Authorization Center, Calling-card Authorization Computer (Sprint), Callingcard Authorization Center, Campaign Against Censorship, Canadian Advisory Committee, Canadian Airports Council, Canadian Association for Conservation, Canadian Aviation Corps (World War I), Capital Allocation Committee, Capital Athletic Conference, Carbohydrate Awareness Council, Cardiac Accelerator Center, Cardioacceleratory Center, Career Assistance Counseling, Caribbean Air Command, Carrier Access Charge, Carrier Access Code, Carrier Access Corporation (Boulder, CO, USA), Carrier Advisory Committee, Carrier Air Patrol, Casualty Area Command, Casualty Area Commander, Catawba Animal Clinic (Rock Hill, South Carolina), Catchment Area Council, Categorical Assistance Code, Categorization & Custody, Cauliflower Alley Club, Ceiling Attenuation Class, Cement Association of Canada, Center for Advanced Communications (Villanova University), Central Accessory Compartment, Central Air Command (Pakistan Air Force), Central Air Conditioner (real estate), Central Alarm Cabinet, Central American and Caribbean, Central Arizona College, Central de Atendimento a Clientes, Centre Alge'rien de la Cine'matographie (Algeria), Centre d'Action Culturelle (French), Certificat d'Aptitute Au Championat (FCI dog show reserve champion), Certificat d'Aptitute au Championnat (European dog shows), Certified Addictions Counselor, Certified Annuity Consultant, Change Area Coordinator (Sprint), Change to Approach Control, Channel Access Code, Charged Air Cooler (turbochargers), Cheese and Crackers, Chemometrics in Analytical Chemistry (conference), Chengdu Aircraft Company (China), Chicago Artists' Coalition, Child Activity Center, Child Advocacy Center, Chinese Alliance Church, Chinese Annual Conference (of the Methodist Church in Singapore), Christ Apostolic Church, Circuit Access Code, Circuit Administration Center, Citizens Action Coalition, Citizens Advisory Council, Citizens' Advisory Committee, Civil Affairs Coordinator, Civil Applications Committee, Civilian Advisory Conference, Clean Air Council, Clear Acquisition Code (GPS), Clear All Corridors (hospital), Client Acceptance Committee, Climate Analysis Center, Clinical Advisory Committee, Closed Air Circuit, Clostridium Acetobutylicum, Coaching Association of Canada, Coal Association of Canada, Coalition for America's Children, Coastal Assistant Controller, Cognitive-Affective-Conative, Collection Accounting Classification, Collection Advisory Center, Color Access Control, Combat Analysis Capability, Combined Arms Center (Ft Leavenworth, Kansas), Combined Arms Center/Command, Command & Control, Commander's Access Channel, Commandos d'Action Cubains (French), Commissaire Aux Comptes (French, financial), Commission on Accreditation for Corrections, Common Access Card (smart card technology used in DoD), Common And COTS, Common Avionics Computer, Communication Aid Centre (UK), Communication Architecture for Clusters, Community Action Council, Community Activities Center, Community Activity Center, Community Affairs Committee, Community Affairs Council, Community Agriculture Centre, Community Alliance Church, Community Amenity Contribution (Canada), Commuting Area Candidate, Compandored Analog Carrier, Competition Appeal Court, Complaints Advisory Committee, Complex Advisory Council, Compound Access Control, Compressed Aeronautical Chart, Compressor After Cooler, Computer Access Center, Computer Aided Crime, Computer Asset Controller, Computer-Aided Construction, Computer-Aided Cost/Classification, Computer-Assisted Cartography, Computing Accreditation Commission (ABET), Concord Automation and Controls, Conditional Acceptance Certificate, Conformity Assessment Certificate, Connection Acceptance Control, Connection Admission Control (Asynchronous Transfer Mode), Connection Asset Customer, Connection Assurance Check, Conseil des Ae'roports du Canada (Canadian Airports Council), Conservatief Accoord, Console Alarm Card, Consulting and Audit Canada, Consumer Affairs Commission (Jamaica), Consumers Association of Canada, Contact Agility Club, Contact Approach Control, Context-Aware Computing, Continuity Army Council (IRA), Contract Audit Coordinator (DCAA), Contract Awards Committee, Contractor's Approach to CALS, Control Analysis Center, Coomera Anglican College (Gold Coast, Australia), Cooper Aerobics Center, Coronary Artery Calcium, Corporate Affairs Commission (Nigeria), Corps Aviation Company, Cost Account Code, Cost At Completion, Cotation Assiste'e En Continu (French: Continuous-Time Computer-Assisted Quotation System), Cotation Assistee En Continue (French Stock Exchange Index), Counselors Advisory Committee (B'ham Al Crisis Center), Cow Appreciation Campaign, Create A Card (online gaming), Creative Arts Center (West Virginia University), Credentialed Addictions Counselor, Credit Association of Canada, Crew Available Cycle, Crimes Against Children, Crisis Action Cell, Crisis Action Center, Criteria Air Containment, Crossroads of America Council (Boy Scout council comprising most of Indiana, USA), Cumulative Average Cost, Cumulative Average Curve, Custom Arms Company, Inc., Customer Administration Center, Customer Advisory Council, Customer Assistance Center, Cyclists Advisory Committee (Alberta, Canada), current actions center (US DoD), charge air coder

8) Университет: Campus Advisory Council, College And Career

9) Вычислительная техника: computer-aided composition, connection-admission control, применение компьютера для создания музыкальных композиций, Channel Access Code (Bluetooth), Connection Admission Control (UNI, ATM)

10) Нефть: Central Asia central pipeline, трубопровод Средняя Азия-Центр (Central Asia Central pipeline)

11) Токсикология: Комиссия "Кодекс Алиментариус"

12) Банковское дело: поправочный валютный коэффициент (сокр. от currency adjustment charge)

13) Воздухоплавание: Commonwealth Aircraft Corporation (Aust.)

14) Экология: Center for Analysis of Climate, Climate Advisory Committee

15) Энергетика: Учебно-демонстрационный центр (GE)

16) СМИ: Comic Arts Conference

17) Деловая лексика: Compagnie des Agents de Change

18) Глоссарий компании Сахалин Энерджи: Central Asia - Center

19) Океанография: Computer Advisory Committee

20) Общая лексика: charge air cooler

21) Расширение файла: dBASE IV executable when caching on/ off

22) Нефть и газ: pipeline "Central Asia-Centre", трубопровод «Центральная Азия – Центр», pipeline ‘Central Asia – Centre’

23) Военно-политический термин: Combined Arms Command

24) МИД: (CODEX Alimentarius Commission) КАК (Комиссия "КОДЕКС Алиментариус")

25) Собаководство: CAC

26) Водоснабжение: содержание производных хлора

27) Должность: Certified Addiction Counselor

28) AMEX. Camden National Corporation

29) Международные перевозки: currency adjustment charge