large arithmetic circuit

large arithmetic circuit

БИС арифметического устройства

circuit

1) схема; цепь; контур см. тж gate, network

2) канал

3) т. граф. простая цепь, контур

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- absolute-value circuit

- active circuit
- acyclic circuit
- adding circuit
- add circuit
- addressing circuit
- advancing circuit
- alarm circuit
- amplifying circuit
- analogous circuit
- analog circuit
- AND-to-OR circuit
- antialiasing circuit
- anticoincidence circuit
- antihunting circuit
- antihunt circuit
- aperiodic circuit
- arithmetic circuit
- arithmetical circuit
- astable circuit
- averaging circuit
- balanced circuit
- basis circuit
- beam-lead integrated circuit
- benchmark circuit
- binary-valued digital circuit
- binary-valued circuit
- bipolar circuit
- bistable circuit
- blanking circuit
- bleeder circuit
- bridge circuit
- buffer circuit
- carry circuit
- character selection circuit
- checking circuit
- check circuit
- clamping circuit
- clocked circuit
- clock-recovery circuit
- closed circuit
- code disjoint circuit
- coincidence circuit
- combinational circuit
- combinatorial circuit
- communication circuit
- comparator circuit
- compare circuit
- comparison circuit
- complementary circuit
- complementary integrated circuit
- complementary transistor logic circuit
- complex function circuit
- computer circuit
- computer test circuit
- computing circuit
- control circuit
- core-diode circuit
- core-transistor circuit
- correcting circuit
- correction circuit
- counter circuit
- counting circuit
- coupling circuit
- current-limit circuit
- current-operated circuit
- current-summation circuit
- custom product integrated circuit
- custom integrated circuit
- custom-wired integrated circuit
- cutoff circuit
- cycle circuit
- cyclic circuit
- dead-on-arrival integrated circuit
- decode circuit
- decoding circuit
- deenergizing circuit
- deflection circuit
- delay circuit
- densely packed circuit
- differentiating circuit
- digital computing circuit
- diode circuit
- diode-coupled circuit
- diode-transistor logic circuit
- direct-coupled circuit
- direct-coupled transistor logic circuit
- direct-current circuit
- discrete component circuit
- discrete logic-level
- discrete wired circuit
- display circuit
- divide-by-two circuit
- dividing circuit
- double-sided printed circuit
- doubling circuit
- drive circuit
- dry circuit
- dual circuit
- duplex circuit
- Eccles-Jordan circuit
- edge-activated circuit
- emitter-coupled circuit
- emitter-coupled logic circuit
- emitter-emitter-coupled logic circuit
- equality circuit
- equivalent circuit
- etched circuit
- Euler circuit
- except circuit
- fanout-free circuit
- fast-switching circuit
- fault detection circuit
- fault-free circuit
- fault-secure circuit
- faulty circuit
- feedback circuit
- ferrite-diode circuit
- ferrite-transistor circuit
- ferroresonant computing circuit
- film integrated circuit
- flag-testing circuit
- flat-pack integrated circuit
- flexible printed circuit
- flexible circuit
- flip-chip integrated circuit
- flip-flop circuit
- frame-grounding circuit
- frequency-halving circuit
- function circuit
- gate circuit
- Goto-pair circuit
- half-duplex circuit
- halving circuit
- Hamilton circuit
- hand-designed circuit
- hardwired circuit
- high-speed circuit
- high-threshold logic circuit
- holding circuit
- hybrid circuit
- idler circuit
- imbedded circuit
- IMOS circuit
- impulse circuit
- inhibit circuit
- input circuit
- integrated circuit
- integrating circuit
- integro-differential circuit
- interchange circuit
- interface circuit
- interfacing circuit
- interlock circuit
- invert circuit
- ion-implanted MOS circuit
- irredundant circuit
- Josephson integrated circuit
- junction transistor circuit
- ladder circuit
- lag-lead circuit
- laminar circuit
- large arithmetic circuit
- large-scale integrated circuit
- large-scale integration circuit
- latch circuit
- lead-lag circuit
- leased circuit
- level circuit
- linear circuit
- linear integrated circuit
- linearity circuit
- liquid logic circuit
- load circuit
- locked pair circuit
- locking circuit
- logic circuit
- logical circuit
- low-threshold integrated circuit
- LSI circuit
- lumped circuit
- magnetic circuit
- magnetic-core circuit
- majority circuit
- match circuit
- material equivalence circuit
- matrix circuit
- maximum-remembering circuit
- measuring circuit
- medium-scale integration circuit
- memory circuit
- memory-decoder circuit
- message circuit
- metal-oxide-semiconductor circuit
- microamp circuit
- microelectronic integrated circuit
- microminiature circuit
- microwave circuit
- mil spec integrated circuit
- milliwatt circuit
- miniature circuit
- minimum-remembering circuit
- mixed-level circuit
- mixing circuit
- modularized circuit
- molecular integrated circuit
- monitoring circuit
- monolithic integrated circuit
- monostable circuit
- MOS circuit
- MOS integrated circuit
- MOS LSI circuit
- MSI circuit
- multichip integrated circuit
- multifunction integrated circuit
- multilayer circuit
- multilevel circuit
- multiple output circuit
- multiplying circuit
- multipoint circuit
- multistable circuit
- multistage circuit
- nanosecond circuit
- n-channel circuit
- network circuit
- noise-balancing circuit
- noncoincidence circuit
- noncutoff circuit
- non-self-checking circuit
- one-core-per-bit circuit
- one-generator equivalent circuit
- one-out-of-four selecting circuit
- one-shot circuit
- open circuit
- optical commutation circuit
- optical memory circuit
- optically coupled circuit
- optoelectronic circuit
- output circuit
- packaged circuit
- packed circuit
- p-channel circuit
- phantom circuit
- phase-comparison circuit
- phase-inverting circuit
- picosecond circuit
- pilot circuit
- plastic-embedded circuit
- point-to-point circuit
- power circuit
- power monitoring circuit
- power-fail circuit
- printed circuit
- priority circuit
- propagation circuit
- protection circuit
- pulse circuit
- pulse-actuated circuit
- pulse-broadening circuit
- pulse-regenerating circuit
- pulse-shaping circuit
- pulse-stretching circuit
- pulse-switching circuit
- pumped tunnel-diode transistor logic circuit
- pumping circuit
- quenching circuit
- race-free circuit
- radio-frequency circuit
- random-logic circuit
- ratioed circuit
- reading circuit
- received-data circuit
- receiving circuit
- reconfigurable integrated circuit
- redundant circuit
- reference circuit
- refreshing circuit
- relaxation circuit
- reset circuit
- retriggerable circuit
- rewriting circuit
- ring circuit
- rounding circuit
- sample-hold circuit
- saturated circuit
- scale-of-N circuit
- scale-of-two circuit
- scaling circuit
- schematic circuit
- Schmitt trigger circuit
- Schmitt circuit
- screen printed circuit
- selection circuit
- select circuit
- self-checking circuit
- self-testing circuit
- self-timed circuit
- semiconductor circuit
- send-request circuit
- sequential circuit
- shifting circuit
- shift circuit
- short circuit
- shunt-peaking circuit
- sign-controlled circuit
- silicon integrated circuit
- silicon-on-sapphire integrated circuit
- simplex circuit
- single-chip circuit
- single-ended circuit
- single-level circuit
- single-phase circuit
- single-shot circuit
- small-scale integration circuit
- solid-state circuit
- solid circuit
- SOS integrated circuit
- squaring circuit
- SSI circuit
- stabilizing circuit
- stamped circuit
- start-stop circuit
- steering circuit
- storage circuit
- storage-selection circuit
- strongly fault-secure circuit
- subtraction circuit
- summing circuit
- sweep circuit
- switching circuit
- symbolic circuit
- synchronizing circuit
- synthesis circuit
- thick-film circuit
- thin-film circuit
- threshold circuit
- time-anticoincidence circuit
- time-base circuit
- time-coincidence circuit
- time-delay circuit
- toll circuit
- totally self-checking circuit
- transistor circuit
- transistor-core circuit
- transistor-resistor circuit
- transistor-transistor-logic circuit
- translation circuit
- transmitted-data circuit
- transmitting circuit
- tree circuit
- trigger -action circuit
- trigger circuit
- trunk circuit
- tunnel diode circuit
- twin-tunnel-diode circuit
- twin circuit
- two-cores-per-bit circuit
- two-input circuit
- two-level circuit
- two-way circuit
- ultra-large-scale integration circuit
- unidirectional circuit
- unpackaged circuit
- unpacked circuit
- very-high-speed integrated circuit
- very-large-scale integration circuit
- virtual circuit
- VLSI circuit
- voice circuit
- voice-grade circuit
- voltage-control circuit
- voltage-doubling circuit
- voltage-multiplying circuit
- voltage-summation circuit
- voter circuit
- wave-shaping circuit
- whole-wafer circuit
- wired AND circuit
- wired OR circuit
- wire-wrapped circuit
- writing circuit
- zero circuit

БИС арифметического устройства

large arithmetic circuit

Computers

   1) A Comparison of the Digital Computer and the Brain

   The brain has been compared to a digital computer because the neuron, like a switch or valve, either does or does not complete a circuit. But at that point the similarity ends. The switch in the digital computer is constant in its effect, and its effect is large in proportion to the total output of the machine. The effect produced by the neuron varies with its recovery from [the] refractory phase and with its metabolic state. The number of neurons involved in any action runs into millions so that the influence of any one is negligible.... Any cell in the system can be dispensed with.... The brain is an analogical machine, not digital. Analysis of the integrative activities will probably have to be in statistical terms. (Lashley, quoted in Beach, Hebb, Morgan & Nissen, 1960, p. 539)

   2) Computers Do Not Crunch Numbers, They Manipulate Symbols

   It is essential to realize that a computer is not a mere "number cruncher," or supercalculating arithmetic machine, although this is how computers are commonly regarded by people having no familiarity with artificial intelligence. Computers do not crunch numbers; they manipulate symbols.... Digital computers originally developed with mathematical problems in mind, are in fact general purpose symbol manipulating machines....

   The terms "computer" and "computation" are themselves unfortunate, in view of their misleading arithmetical connotations. The definition of artificial intelligence previously cited-"the study of intelligence as computation"-does not imply that intelligence is really counting. Intelligence may be defined as the ability creatively to manipulate symbols, or process information, given the requirements of the task in hand. (Boden, 1981, pp. 15, 16-17)

   3) Getting Computers to Explain Things to Themselves

   The task is to get computers to explain things to themselves, to ask questions about their experiences so as to cause those explanations to be forthcoming, and to be creative in coming up with explanations that have not been previously available. (Schank, 1986, p. 19)

   4) Some Limits of Artificial Intelligence

   In What Computers Can't Do, written in 1969 (2nd edition, 1972), the main objection to AI was the impossibility of using rules to select only those facts about the real world that were relevant in a given situation. The "Introduction" to the paperback edition of the book, published by Harper & Row in 1979, pointed out further that no one had the slightest idea how to represent the common sense understanding possessed even by a four-year-old. (Dreyfus & Dreyfus, 1986, p. 102)

   5) The Computer as a Humanizing Influence

   A popular myth says that the invention of the computer diminishes our sense of ourselves, because it shows that rational thought is not special to human beings, but can be carried on by a mere machine. It is a short stop from there to the conclusion that intelligence is mechanical, which many people find to be an affront to all that is most precious and singular about their humanness.

   In fact, the computer, early in its career, was not an instrument of the philistines, but a humanizing influence. It helped to revive an idea that had fallen into disrepute: the idea that the mind is real, that it has an inner structure and a complex organization, and can be understood in scientific terms. For some three decades, until the 1940s, American psychology had lain in the grip of the ice age of behaviorism, which was antimental through and through. During these years, extreme behaviorists banished the study of thought from their agenda. Mind and consciousness, thinking, imagining, planning, solving problems, were dismissed as worthless for anything except speculation. Only the external aspects of behavior, the surface manifestations, were grist for the scientist's mill, because only they could be observed and measured....

   It is one of the surprising gifts of the computer in the history of ideas that it played a part in giving back to psychology what it had lost, which was nothing less than the mind itself. In particular, there was a revival of interest in how the mind represents the world internally to itself, by means of knowledge structures such as ideas, symbols, images, and inner narratives, all of which had been consigned to the realm of mysticism. (Campbell, 1989, p. 10)

   6) The Intentionality of Computers Is Essentially Borrowed, Hence Derivative

   [Our artifacts] only have meaning because we give it to them; their intentionality, like that of smoke signals and writing, is essentially borrowed, hence derivative. To put it bluntly: computers themselves don't mean anything by their tokens (any more than books do)-they only mean what we say they do. Genuine understanding, on the other hand, is intentional "in its own right" and not derivatively from something else. (Haugeland, 1981a, pp. 32-33)

   7) The Possibility of Computer Thought

   he debate over the possibility of computer thought will never be won or lost; it will simply cease to be of interest, like the previous debate over man as a clockwork mechanism. (Bolter, 1984, p. 190)

   8) We Are Getting Better at Building Even Better Computers, an Ever- Escalating Upward Spiral

   t takes us a long time to emotionally digest a new idea. The computer is too big a step, and too recently made, for us to quickly recover our balance and gauge its potential. It's an enormous accelerator, perhaps the greatest one since the plow, twelve thousand years ago. As an intelligence amplifier, it speeds up everything-including itself-and it continually improves because its heart is information or, more plainly, ideas. We can no more calculate its consequences than Babbage could have foreseen antibiotics, the Pill, or space stations.

   Further, the effects of those ideas are rapidly compounding, because a computer design is itself just a set of ideas. As we get better at manipulating ideas by building ever better computers, we get better at building even better computers-it's an ever-escalating upward spiral. The early nineteenth century, when the computer's story began, is already so far back that it may as well be the Stone Age. (Rawlins, 1997, p. 19)

   9) Weak Artificial Intelligence and Strong Artificial Intelligence

   According to weak AI, the principle value of the computer in the study of the mind is that it gives us a very powerful tool. For example, it enables us to formulate and test hypotheses in a more rigorous and precise fashion than before. But according to strong AI the computer is not merely a tool in the study of the mind; rather the appropriately programmed computer really is a mind in the sense that computers given the right programs can be literally said to understand and have other cognitive states. And according to strong AI, because the programmed computer has cognitive states, the programs are not mere tools that enable us to test psychological explanations; rather, the programs are themselves the explanations. (Searle, 1981b, p. 353)

    10) Why People Are Smarter Than Computers

   What makes people smarter than machines? They certainly are not quicker or more precise. Yet people are far better at perceiving objects in natural scenes and noting their relations, at understanding language and retrieving contextually appropriate information from memory, at making plans and carrying out contextually appropriate actions, and at a wide range of other natural cognitive tasks. People are also far better at learning to do these things more accurately and fluently through processing experience.

   What is the basis for these differences? One answer, perhaps the classic one we might expect from artificial intelligence, is "software." If we only had the right computer program, the argument goes, we might be able to capture the fluidity and adaptability of human information processing. Certainly this answer is partially correct. There have been great breakthroughs in our understanding of cognition as a result of the development of expressive high-level computer languages and powerful algorithms. However, we do not think that software is the whole story.

   In our view, people are smarter than today's computers because the brain employs a basic computational architecture that is more suited to deal with a central aspect of the natural information processing tasks that people are so good at.... hese tasks generally require the simultaneous consideration of many pieces of information or constraints. Each constraint may be imperfectly specified and ambiguous, yet each can play a potentially decisive role in determining the outcome of processing. (McClelland, Rumelhart & Hinton, 1986, pp. 3-4)