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Supermini robot
| Глоссарий по робототехнике |
Супер
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Супер, русский
Самая сильная атака бойца
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Robot, английский
- Traffic light
- A robot is a general-purpose system that can perform multiple tasks under conditions that might not be known a priori. robots can include such things as sensors and other input devices, a computer-based controller, and some form of an actuator, such as a mechanical hand or drill that it can use upon its environment. the japanese have classified industrial robots into five categories: slave manipulators operated by humans, limited sequence manipulators, "teach-replay" robots, computer-controlled robots, and "intelligent" robots. the united states robotic industries association defines a robot as ``a reprogrammable, multifunctional manipulator (or device) designed to move material, parts, tools, or specialized devices through variable programmed motions for the performance of a variety of tasks."
- Remote control device with closed circuit television (cctv) monitoring, used mainly in localised repair work, such as cutting away obstructions, re-opening lateral connections, grinding and re-filling defective areas and injecting resin into cracks and cavities.
Robot area, английский
Оперативная зона действия робота (напр., обслуживающего гибкий производственный модуль)
Robot arm, английский
Рука робота; механическая рука
Robot base, английский
Основание (станина) робота
Robot body, английский
Манипулятор робота
Robot brain i., английский
Мозг робота;2. автоматическая вычислительная машина, автоматическая управляющая маши- на, система управления (роботом) cm. аrtifiсiаl brаin, соntrоllеr, rоbоt соntrоllеr
Robot bush, английский
Robot camera, английский
Видеодатчик робота; роботизированный датчик видения (напр., для опознавания деталей на входе гибкого производственного модуля)
Robot development work, английский
Создание роботехнических средств
Robot execution program, английский
Robot eye, английский
Система.искусственного (технического) зрения робота, глаз робота
Robot industry, английский
Роботостроение
Robot lanquage, английский
Язык программирования робота
Robot life, английский
Срок полной амортизации робота
Robot loader, английский
Robot navigation, английский
Навигация робота
Robot off-line programming i., английский
Обучение робота в автономном режиме 2. автономная (автоматизированная) подготовка управляющих программ для робота (путем обучения)
Robot operating stand, английский
Выносной, пульт управления (роботом)
Robot painter, английский
Окрасочный робот см. также painting robot
Robot part loading, английский
Роботизированная загрузка деталей
Robot population, английский
Поколение роботов
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Schemata, английский
Схематика
Reasoning, английский
- Суждение
- This term can have multiple meanings. it can refer to the ability to draw conclusions from a set of facts or assumptions, the ability to analyze or organize information, the ability to solve problems, and the ability to persuade. in one form or another, it is the basis for most ai programs with the notable exception of the last meaning. reasoning, causal reasoning about the behavior of systems for the purpose of explaining the causes of past events or from a current state to future events. reasoning, default a generic term for the ability of a reasoning system to reach conclusions that are not strict consequences of the current state. a default reasoning ability allows a system to continue to operate on partial data. the implementation varies with the system designer as there is no hard definition of default reasoning. it usually takes the form of some local generalizations or presumptions that attempt to bridge any gaps in the knowledge. some logic systems that can apply here include monotone logic and nonmonotone logic, and bayesian, fuzzy or similar logic based on measures of certainty or uncertainty. such systems can also use belief selection systems to choose among alternate belief systems, and corresponding methods to revise those beliefs as additional information becomes available. reasoning, precise and imprecise reasoning systems can be described by the amount of precision they use in making any reasoning steps. at the most precise end are reasoning systems that are only concerned with logically valid relationships known with certainty. an obvious example would be classical aristotelian systems, mathematics, and other classical logic systems. in these cases, the conclusions are true if the premises are true. at the other end are systems such a probabilistic or fuzzy systems that reason about things that are either ill-defined and/or not known with certainty. in these systems, additional information about the truth, certainty, or precision of the premises are included in the computation and evaluation of any conclusions. the imprecise systems are used in many expert systems and embedded systems controllers.
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