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1 complex representation
Большой англо-русский и русско-английский словарь > complex representation
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2 complex representation
Математика: комплексное представлениеУниверсальный англо-русский словарь > complex representation
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3 complex representation
English-russian dictionary of physics > complex representation
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4 complex representation
комплексное представлениеEnglish-Russian dictionary of technical terms > complex representation
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5 complex representation
English-Russian scientific dictionary > complex representation
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6 representation
1) изображение2) отображение; представление•- completely irreducible representation - completely reduced representation - completely reducible representation - discrete representation - finitely related representation - identity representation - locally constant representation - locally faithful representation - strongly rational representation - totally reducible representation -
7 complex quantity notation
complex quantity notation ( complex quantity representation) komplexe Darstellung f [Schreibweise f ]; symbolisches Rechenverfahren nEnglish-German dictionary of Electrical Engineering and Electronics > complex quantity notation
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8 representation
1) представление; отображение3) обозначение4) изображение; воспроизведение•representation in a system of numeration — представление ( числа) в системе счисления-
analog representation
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array representation
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binary-coded representation
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binary representation
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binary-coded decimal representation
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boundary representation
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character representation
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circuit representation
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coded representation
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complex plane representation
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data representation
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decimal representation
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declarative representation
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digital representation
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discrete representation
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external representation
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feature representation
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finite representation
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fixed-point representation
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floating-point representation
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frequency-domain representation
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geometric representation
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graphical representation
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graphic representation
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hardware representation
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hexadecimal representation
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iconic representation
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incremental representation
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input representation
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knowledge representation
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Laplace representation
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linear representation
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list representation
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machine representation
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moving average representation
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number representation
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numerical representation
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numeric representation
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octal representation
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output representation
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parametric representation
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physical representation
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pictorial representation
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positional representation
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procedural representation
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reference representation
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skeleton representation
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spectral representation
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tensor representation
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time-domain representation
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time representation
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trigonometric representation
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vector representation -
9 complex node representation
комплексное представление узла
Набор параметров состояния узла, обеспечивающих детальную информацию о данном узле.
[ http://www.lexikon.ru/dict/net/index.html]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > complex node representation
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10 complex plane representation
изображение на комплексной плоскостиБольшой англо-русский и русско-английский словарь > complex plane representation
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11 complex plane representation
Англо-русский словарь технических терминов > complex plane representation
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12 Complex Node Representation
Сетевые технологии: сложное представление узла (Набор параметров состояния узла, обеспечивающих детальную информацию о данном узле)Универсальный англо-русский словарь > Complex Node Representation
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13 complex plane representation
Техника: изображение на комплексной плоскостиУниверсальный англо-русский словарь > complex plane representation
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14 complex-plane representation
Техника: изображение на комплексной плоскостиУниверсальный англо-русский словарь > complex-plane representation
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15 complex group representation
English-russian dictionary of physics > complex group representation
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16 complex-conjugate representation
English-russian dictionary of physics > complex-conjugate representation
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17 complex node representation
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18 Thinking
But what then am I? A thing which thinks. What is a thing which thinks? It is a thing which doubts, understands, [conceives], affirms, denies, wills, refuses, which also imagines and feels. (Descartes, 1951, p. 153)I have been trying in all this to remove the temptation to think that there "must be" a mental process of thinking, hoping, wishing, believing, etc., independent of the process of expressing a thought, a hope, a wish, etc.... If we scrutinize the usages which we make of "thinking," "meaning," "wishing," etc., going through this process rids us of the temptation to look for a peculiar act of thinking, independent of the act of expressing our thoughts, and stowed away in some particular medium. (Wittgenstein, 1958, pp. 41-43)Analyse the proofs employed by the subject. If they do not go beyond observation of empirical correspondences, they can be fully explained in terms of concrete operations, and nothing would warrant our assuming that more complex thought mechanisms are operating. If, on the other hand, the subject interprets a given correspondence as the result of any one of several possible combinations, and this leads him to verify his hypotheses by observing their consequences, we know that propositional operations are involved. (Inhelder & Piaget, 1958, p. 279)In every age, philosophical thinking exploits some dominant concepts and makes its greatest headway in solving problems conceived in terms of them. The seventeenth- and eighteenth-century philosophers construed knowledge, knower, and known in terms of sense data and their association. Descartes' self-examination gave classical psychology the mind and its contents as a starting point. Locke set up sensory immediacy as the new criterion of the real... Hobbes provided the genetic method of building up complex ideas from simple ones... and, in another quarter, still true to the Hobbesian method, Pavlov built intellect out of conditioned reflexes and Loeb built life out of tropisms. (S. Langer, 1962, p. 54)Experiments on deductive reasoning show that subjects are influenced sufficiently by their experience for their reasoning to differ from that described by a purely deductive system, whilst experiments on inductive reasoning lead to the view that an understanding of the strategies used by adult subjects in attaining concepts involves reference to higher-order concepts of a logical and deductive nature. (Bolton, 1972, p. 154)There are now machines in the world that think, that learn and create. Moreover, their ability to do these things is going to increase rapidly until-in the visible future-the range of problems they can handle will be coextensive with the range to which the human mind has been applied. (Newell & Simon, quoted in Weizenbaum, 1976, p. 138)But how does it happen that thinking is sometimes accompanied by action and sometimes not, sometimes by motion, and sometimes not? It looks as if almost the same thing happens as in the case of reasoning and making inferences about unchanging objects. But in that case the end is a speculative proposition... whereas here the conclusion which results from the two premises is an action.... I need covering; a cloak is a covering. I need a cloak. What I need, I have to make; I need a cloak. I have to make a cloak. And the conclusion, the "I have to make a cloak," is an action. (Nussbaum, 1978, p. 40)It is well to remember that when philosophy emerged in Greece in the sixth century, B.C., it did not burst suddenly out of the Mediterranean blue. The development of societies of reasoning creatures-what we call civilization-had been a process to be measured not in thousands but in millions of years. Human beings became civilized as they became reasonable, and for an animal to begin to reason and to learn how to improve its reasoning is a long, slow process. So thinking had been going on for ages before Greece-slowly improving itself, uncovering the pitfalls to be avoided by forethought, endeavoring to weigh alternative sets of consequences intellectually. What happened in the sixth century, B.C., is that thinking turned round on itself; people began to think about thinking, and the momentous event, the culmination of the long process to that point, was in fact the birth of philosophy. (Lipman, Sharp & Oscanyan, 1980, p. xi)The way to look at thought is not to assume that there is a parallel thread of correlated affects or internal experiences that go with it in some regular way. It's not of course that people don't have internal experiences, of course they do; but that when you ask what is the state of mind of someone, say while he or she is performing a ritual, it's hard to believe that such experiences are the same for all people involved.... The thinking, and indeed the feeling in an odd sort of way, is really going on in public. They are really saying what they're saying, doing what they're doing, meaning what they're meaning. Thought is, in great part anyway, a public activity. (Geertz, quoted in J. Miller, 1983, pp. 202-203)Everything should be made as simple as possible, but not simpler. (Einstein, quoted in Minsky, 1986, p. 17)What, in effect, are the conditions for the construction of formal thought? The child must not only apply operations to objects-in other words, mentally execute possible actions on them-he must also "reflect" those operations in the absence of the objects which are replaced by pure propositions. Thus, "reflection" is thought raised to the second power. Concrete thinking is the representation of a possible action, and formal thinking is the representation of a representation of possible action.... It is not surprising, therefore, that the system of concrete operations must be completed during the last years of childhood before it can be "reflected" by formal operations. In terms of their function, formal operations do not differ from concrete operations except that they are applied to hypotheses or propositions [whose logic is] an abstract translation of the system of "inference" that governs concrete operations. (Piaget, quoted in Minsky, 1986, p. 237)[E]ven a human being today (hence, a fortiori, a remote ancestor of contemporary human beings) cannot easily or ordinarily maintain uninterrupted attention on a single problem for more than a few tens of seconds. Yet we work on problems that require vastly more time. The way we do that (as we can observe by watching ourselves) requires periods of mulling to be followed by periods of recapitulation, describing to ourselves what seems to have gone on during the mulling, leading to whatever intermediate results we have reached. This has an obvious function: namely, by rehearsing these interim results... we commit them to memory, for the immediate contents of the stream of consciousness are very quickly lost unless rehearsed.... Given language, we can describe to ourselves what seemed to occur during the mulling that led to a judgment, produce a rehearsable version of the reaching-a-judgment process, and commit that to long-term memory by in fact rehearsing it. (Margolis, 1987, p. 60)Historical dictionary of quotations in cognitive science > Thinking
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19 number
1) номер
2) балл
3) занумеровать
4) занумеровывать
5) код числа
6) колонцифра
7) насчитывать
8) насчитываться
9) номерной
10) нумеровать
11) перенумеровывать
12) цифровать
13) численность
14) число
15) количество
16) выпуск
17) считать
18) подсчитывать
19) перенумеровать
20) числительное
21) числовой
22) пронумеровать
– absolute number
– abundant number
– acceptance number
– acetone number
– acid number
– alcohol number
– algebraic number
– atomic number
– Beaufort number
– Betti number
– binary number
– Biot number
– biquinary number
– bridging number
– called number
– cardinal number
– cavitation number
– cetane number
– clock number
– coincidence number
– complex number
– composite number
– concrete number
– congruent number
– contact number
– coordination number
– cube of a number
– Damkohler number
– decimal number
– denominate number
– denomination of a number
– designation number
– dial a number
– dimensionless number
– directed number
– direction number
– divide by number
– double-precision number
– equilibrium number
– ester number
– even number
– express number
– figurate number
– fixed-point number
– flight number
– floating-point number
– fourier number
– general number
– golden number
– Grashof number
– Grashoff number
– Guchman number
– hardness number
– hydrogen number
– hydroxyl number
– imaginary number
– incidence number
– iodine number
– irrational number
– Karman number
– Lawson number
– linking number
– lucky number
– mass number
– minor number
– mixed number
– multidigit number
– multipartite number
– multiperfect number
– multiplace number
– natural number
– negative number
– neutralization number
– neutron number
– no such number
– nonnegative number
– nonnormalized number
– nonworking number
– number address
– number axes
– number bus
– number cruncher
– number exponent
– number filling
– number grouping
– number in the thousands
– number language
– number line
– number nail
– number of conductors
– number of cords
– number of gears
– number plate
– number register
– number scale
– number system
– number translation
– number wheel
– number wire
– Nusselt number
– octane number
– odd number
– ordiecutive number
– ordinal number
– oxidation number
– oxygen number
– perfect number
– permanganate number
– peroxide number
– prime number
– pseudoprime number
– pure number
– pythagorean number
– quantum number
– rational number
– real number
– registration number
– represent number
– representation of number
– reversion of a number
– ringing number
– root of a number
– round number
– round off number
– saponification number
– screening number
– serial number
– signed number
– standard number
– Stroud number
– tanning number
– telephone number
– thiocyanogen number
– transference number
– transonic M number
– transport number
– unsigned number
– wave number
– Weber number
– weight number
– wrong number
equiprobable number generator — генератор равновероятных цифр
hexadecimal number system — шестнадцатиричная система счисления
international customer number — междугородный номер абонента
mass exchange number — <phys.> критерий массообменный
number checking arrangement — блокировка цепи вызванного абонента
number transfer bus — числовая шина, шина передачи чисел
phase transformation number — <phys.> критерий фазового превращения
random number generator — <comput.> датчик случайных чисел
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20 Mind
It becomes, therefore, no inconsiderable part of science... to know the different operations of the mind, to separate them from each other, to class them under their proper heads, and to correct all that seeming disorder in which they lie involved when made the object of reflection and inquiry.... It cannot be doubted that the mind is endowed with several powers and faculties, that these powers are distinct from one another, and that what is really distinct to the immediate perception may be distinguished by reflection and, consequently, that there is a truth and falsehood which lie not beyond the compass of human understanding. (Hume, 1955, p. 22)Let us then suppose the mind to be, as we say, white Paper, void of all Characters, without any Ideas: How comes it to be furnished? Whence comes it by that vast store, which the busy and boundless Fancy of Man has painted on it, with an almost endless variety? Whence has it all the materials of Reason and Knowledge? To this I answer, in one word, from Experience. (Locke, quoted in Herrnstein & Boring, 1965, p. 584)The kind of logic in mythical thought is as rigorous as that of modern science, and... the difference lies, not in the quality of the intellectual process, but in the nature of things to which it is applied.... Man has always been thinking equally well; the improvement lies, not in an alleged progress of man's mind, but in the discovery of new areas to which it may apply its unchanged and unchanging powers. (Leґvi-Strauss, 1963, p. 230)MIND. A mysterious form of matter secreted by the brain. Its chief activity consists in the endeavor to ascertain its own nature, the futility of the attempt being due to the fact that it has nothing but itself to know itself with. (Bierce, quoted in Minsky, 1986, p. 55)[Philosophy] understands the foundations of knowledge and it finds these foundations in a study of man-as-knower, of the "mental processes" or the "activity of representation" which make knowledge possible. To know is to represent accurately what is outside the mind, so to understand the possibility and nature of knowledge is to understand the way in which the mind is able to construct such representation.... We owe the notion of a "theory of knowledge" based on an understanding of "mental processes" to the seventeenth century, and especially to Locke. We owe the notion of "the mind" as a separate entity in which "processes" occur to the same period, and especially to Descartes. We owe the notion of philosophy as a tribunal of pure reason, upholding or denying the claims of the rest of culture, to the eighteenth century and especially to Kant, but this Kantian notion presupposed general assent to Lockean notions of mental processes and Cartesian notions of mental substance. (Rorty, 1979, pp. 3-4)Under pressure from the computer, the question of mind in relation to machine is becoming a central cultural preoccupation. It is becoming for us what sex was to Victorians-threat, obsession, taboo, and fascination. (Turkle, 1984, p. 313)7) Understanding the Mind Remains as Resistant to Neurological as to Cognitive AnalysesRecent years have been exciting for researchers in the brain and cognitive sciences. Both fields have flourished, each spurred on by methodological and conceptual developments, and although understanding the mechanisms of mind is an objective shared by many workers in these areas, their theories and approaches to the problem are vastly different....Early experimental psychologists, such as Wundt and James, were as interested in and knowledgeable about the anatomy and physiology of the nervous system as about the young science of the mind. However, the experimental study of mental processes was short-lived, being eclipsed by the rise of behaviorism early in this century. It was not until the late 1950s that the signs of a new mentalism first appeared in scattered writings of linguists, philosophers, computer enthusiasts, and psychologists.In this new incarnation, the science of mind had a specific mission: to challenge and replace behaviorism. In the meantime, brain science had in many ways become allied with a behaviorist approach.... While behaviorism sought to reduce the mind to statements about bodily action, brain science seeks to explain the mind in terms of physiochemical events occurring in the nervous system. These approaches contrast with contemporary cognitive science, which tries to understand the mind as it is, without any reduction, a view sometimes described as functionalism.The cognitive revolution is now in place. Cognition is the subject of contemporary psychology. This was achieved with little or no talk of neurons, action potentials, and neurotransmitters. Similarly, neuroscience has risen to an esteemed position among the biological sciences without much talk of cognitive processes. Do the fields need each other?... [Y]es because the problem of understanding the mind, unlike the wouldbe problem solvers, respects no disciplinary boundaries. It remains as resistant to neurological as to cognitive analyses. (LeDoux & Hirst, 1986, pp. 1-2)Since the Second World War scientists from different disciplines have turned to the study of the human mind. Computer scientists have tried to emulate its capacity for visual perception. Linguists have struggled with the puzzle of how children acquire language. Ethologists have sought the innate roots of social behaviour. Neurophysiologists have begun to relate the function of nerve cells to complex perceptual and motor processes. Neurologists and neuropsychologists have used the pattern of competence and incompetence of their brain-damaged patients to elucidate the normal workings of the brain. Anthropologists have examined the conceptual structure of cultural practices to advance hypotheses about the basic principles of the mind. These days one meets engineers who work on speech perception, biologists who investigate the mental representation of spatial relations, and physicists who want to understand consciousness. And, of course, psychologists continue to study perception, memory, thought and action.... [W]orkers in many disciplines have converged on a number of central problems and explanatory ideas. They have realized that no single approach is likely to unravel the workings of the mind: it will not give up its secrets to psychology alone; nor is any other isolated discipline-artificial intelligence, linguistics, anthropology, neurophysiology, philosophy-going to have any greater success. (Johnson-Laird, 1988, p. 7)Historical dictionary of quotations in cognitive science > Mind
См. также в других словарях:
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