component variety

component variety

номенклатура обрабатываемых деталей

component variety

Техника: номенклатура обрабатываемых деталей

component variety

номенклатура обрабатываемых деталей

variety

1) ряд; множество

2) номенклатура; набор; комплекс

3) разнообразие; многообразие

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- component variety

- high variety of components
- part variety
- process variety
- product variety
- tooling variety
- transfer variety
- workpiece variety

variety

1) разнообразие

2) вид; разновидность

3) сорт

•

-
commercial variety
-
component variety
-
table variety

component [part] variety

номенклатура обрабатываемых деталей

manufacturing

1) производство; изготовление || производственный; промышленный; технологический

2) обработка

•

- lights-out manufacturing

- advanced manufacturing
- agile manufacturing
- batch manufacturing
- batch-lot manufacturing
- cell manufacturing
- cellular manufacturing
- computer-aided manufacturing
- computer-assisted manufacturing
- computer-integrated manufacturing
- conventional manufacturing
- data-driven manufacturing
- die-mold manufacturing
- discrete batch manufacturing
- discrete component manufacturing
- discrete parts manufacturing
- engineering manufacturing
- environmentally conscious manufacturing
- extensive manufacturing
- family-of-parts manufacturing
- feature-based manufacturing
- flexible automated manufacturing
- flexible manufacturing
- gear manufacturing
- hands-off manufacturing
- high-mix manufacturing
- high-variety manufacturing
- high-velocity manufacturing
- high-volume manufacturing
- high-volume/low-variety manufacturing
- human integrated manufacturing
- human-centered manufacturing
- infrequent small lot manufacturing
- integrated manufacturing
- just-in-time manufacturing
- large-batch manufacturing
- large-scale manufacturing
- laser-integrated flexible manufacturing
- lean manufacturing
- low-staffed manufacturing
- low-variety manufacturing
- low-volume/high-variety manufacturing
- market integrated manufacturing
- mass manufacturing
- mass-production manufacturing
- medium-batch manufacturing
- medium-run manufacturing
- medium-volume manufacturing
- metal-working manufacturing
- mid-variety manufacturing
- mid-volume/mid-variety manufacturing
- minimally manned manufacturing
- multipart manufacturing
- multiproduct manufacturing
- NC manufacturing
- near-net-shape manufacturing
- physically integrated manufacturing
- process-specialized manufacturing
- quantity manufacturing
- quick-change manufacturing
- random manufacturing
- random order manufacturing
- real-time manufacturing
- sales integrated manufacturing
- series manufacturing
- short-series manufacturing
- six sigma manufacturing
- small-batch manufacturing
- small-lot manufacturing
- small-scale manufacturing
- unmanned manufacturing
- untended manufacturing
- zero defect manufacturing

production

1) производство; изготовление; обработка || производственный; технологический

2) объём выпуска, выпуск; выработка; производительность

3) продукция

4) правило вывода, порождающее правило ( в экспертных системах)

•

production in terms of cash — производительность в стоимостном выражении

production in terms of finished components — производительность, выраженная в количестве обработанных деталей

production per man — выработка на одного работающего

to put into production — вводить в эксплуатацию

- adaptable production

- automatic production
- average-scale production
- batch production
- captive production
- chip production per time unit
- CNC production
- continuous production
- customized production
- dedicated production
- defect production
- duplicate production
- electronically gaged production
- family-of-parts production
- faulty production
- flexible production
- flow production
- flow-line production
- gross production
- group production
- hands-off production
- high production
- high-run production
- high-speed production
- high-variety production
- high-volume/low-variety production
- infrequent small lot production
- in-line production
- integrated production
- jigless production
- JIT production
- job lot production
- job shop production
- just-in-time production
- labor production
- large batch production
- large lot production
- large quantity production
- large scale production
- large series production
- lean production
- light production
- limited manning production
- limited manpower production
- line production
- long-run production
- lot production
- low production
- low-quantity repetition production
- low-volume/high-variety production
- mass production
- mechanical assembly production
- medium batch production
- medium quantity production
- medium run production
- medium size production
- medium volume production
- metalworking production
- mid-variety production
- mid-volume/mid-variety production
- mixed production
- mixed quantity production
- multikind production
- multipart production
- multiple production
- NC production
- net production
- net shape production
- nonstop production
- one setup production
- one-hit production
- one-off component production
- one-off production
- option production
- part family production
- piece production
- pilot production
- powertrain production
- prototype production
- quantity production
- random production
- repetition production
- repetitive batch production
- repetitive lot production
- replacement part production
- round-the-clock production
- run-out production
- semicontinuous production
- serial production
- series production
- shop floor production
- short-run production
- short-scale production
- single-operation production
- single-piece production
- small batch production
- small lot production
- small series production
- small volume production
- small-size production
- stop-and-go production
- substandard production
- turned part production
- unattended production
- unmanned production
- untended production
- variety-of-parts production
- volume production

Flax

FLAX

The following terms as given under the authority of the Ministry of Supply, are reprinted here with their permission. Flax Plants - of the species Linum usitatissimum cultivated for the production of seed or fibre or both. Flax, Fibre (Fibre Flax) - The variety of flax cultivated mainly for fibre production. Flax, fibre strands, or bundles - The aggregates, about 32 in number, of ultimate fibres which run from the level of the seed leaves up to the top of the branches of the flax straw. They are each composed of large numbers of ultimate fibres overlapping each other. Flax Fibres, Ultimate - The component cellulose fibres, about 1¹/₄-in. long by 1/1000-in. wide, making up the fibre system of the flax straw. Flax, Linseed - The variety of flax cultivated mainly for seed production. Flax Seed - The term usually applied to the seed of fibre flax. A bag of flax seed in Ireland is sometimes 3¹/₂ bushels, but it is more usual now to put up seed in 1-cwt. bags as in England. A peck of flax seed weighs approximately 14-lb. Flax Seed, Blue Blossom - Seed of a blue-flowered variety of flax. Flax Seed, Commercial - Flax seed usually named after its country or place of origin, but without a pedigree and without guarantee as to colour of flower. Flax Seed Germination - That percentage by number of a sample of seed which shows visible signs of growth within a stated time when kept under standard conditions of temperature and moisture. Flax Seed Germination, Standard - An arbitrary standard of germination of 90 per cent or more, incorporated in the flax growers' contract of the Ministry of Supply. Flax Seed, Lital - The generic name given to pedigree flax seed of several strains bred by the Linen Industry Research Association, Lambeg, and derived from those initials. Flax Seed, Minty - Seed which has been attacked by species of mites, usually owing to it being cracked and too damp. It is characterised by a dusty appearance and a distinct musty sweet smell. Flax Seed, Mixed Blue Blossom - A term used in Northern Ireland for seed from two or more blue-blossomed pedigree flaxes mixed together. Flax Seed, Pedigree - Seed of a strain of flax which has been improved by some recognised system of flax breeding and originally derived from the bulking of the seed from a single flax plant. Flax Seed, Plimmed - A local term for seed which has swollen through excess of moisture. Flax Seed Purity - That percentage by weight of seed taken from bulk which consists of whole flax seeds. Flax Seed Purity, Standard - An arbitrary standard of purity of 96 per cent or more with a weed seed content of 0.25 per cent or less, incorporated in the flax growers' contract of the Ministry of Supply. Flax Seed, Sowing - Seed of a germination and, purity making it acceptable for sowing. Flax Seed, Stormont - The generic name given to pedigree flax seed produced by the Plant Breeding Division, Ministry of Agriculture, Northern Ireland. Flax Seed, Weight per 1,000 - The weight in grams of 1,000 flax seeds picked at random from a sample. It is used as a measure of the plumpness and general quality of seed. Flax Seed, White Blossom - Seed of a white-flowered variety of flax. Flax Variety, Cross breeding - A method of flax breeding, based on fertilising the seed of a single plant of one strain by the pollen of a single plant of another strain and the study of the progeny. Flax Variety, Single Plant Selection - A method of flax breeding based on the study of a single self-fertilised flax plant and its progeny in subsequent generations. Linseed - The seed of linseed flax: and also of fibre flax when it is used for the same purposes as linseed. Moisture Content - To conform with the International ruling for seed testing the moisture content of flax seed should be expressed as a percentage of the original weight; the moisture content of other flax products being expressed as a percentage of the dry weight. Nomersan - A proprietary powder for dusting on flax seed as a prevention of certain seed-bome fungal diseases. Pickle - The term often applied to a single flax seed, i.e., a sample of seed is said to he of a large pickle or a small pickle. Weed Seed - The seed of any other species of plant present in a sample of flax seed.

номенклатура обрабатываемых деталей

spectrum of workpieces, part(s) spectrum, component [part] variety

nilpotent

нильпотентный, нильстепенный even nilpotent element ≈ четный нильпотентный элемент locally nilpotent algebra ≈ локально нильпотентная алгебра locally nilpotent endomorphism ≈ локально нильпотентный эндоморфизм locally nilpotent group ≈ локально нильпотентная группа locally nilpotent homomorphism ≈ локально нильпотентный гомоморфизм locally nilpotent ideal ≈ локально нильпотентный идеал locally nilpotent radical ≈ локально нильпотентный радикал locally nilpotent ring ≈ локально нильпотентное кольцо properly nilpotent element ≈ собственно нильпотентный элемент residually nilpotent group ≈ резидуально нильпотентная группа semigroup without nilpotent ideals ≈ полугруппа без нильпотентных идеалов strongly nilpotent element ≈ строго нильпотентный элемент - generalized nilpotent - locally nilpotent - nilpotent algebra - nilpotent automaton - nilpotent chain - nilpotent complex - nilpotent component - nilpotent divisor - nilpotent element - nilpotent endomorphism - nilpotent factor - nilpotent group - nilpotent homomorphism - nilpotent lattice - nilpotent length - nilpotent matrix - nilpotent module - nilpotent operator - nilpotent product - nilpotent radical - nilpotent semigroup - nilpotent set - nilpotent space - nilpotent subalgebra - nilpotent subgroup - nilpotent subring - nilpotent transformation - nilpotent value - nilpotent variety - properly nilpotent - regular nilpotent - semiregular nilpotent - strongly nilpotent - topological nilpotent

номенклатура обрабатываемых деталей

spectrum of workpieces, part(s) spectrum, component [part\] variety

management education

HR

formal instruction in the principles and techniques of management, and in related subjects, leading to a qualification. Management education strives to develop management knowledge, understanding, and competence through classroom or distance-based methods. Management education is a main component of management development, and differs from management training in that the latter may exploit any one of a variety of formal or informal methods, tends to be focused on a specific skill, and does not result directly in a formal qualification.

Boole, George

SUBJECT AREA: Electronics and information technology

[br]

b. 2 November 1815 Lincoln, England

d. 8 December 1864 Ballintemple, Coounty Cork, Ireland

[br]

English mathematician whose development of symbolic logic laid the foundations for the operating principles of modern computers.

[br]

Boole was the son of a tradesman, from whom he learned the principles of mathematics and optical-component manufacturing. From the early age of 16 he taught in a number of schools in West Yorkshire, and when only 20 he opened his own school in Lincoln. There, at the Mechanical Institute, he avidly read mathematical journals and the works of great mathematicians such as Lagrange, Laplace and Newton and began to tackle a variety of algebraic problems. This led to the publication of a constant stream of original papers in the newly launched Cambridge Mathematical Journal on topics in the fields of algebra and calculus, for which in 1844 he received the Royal Society Medal.

In 1847 he wrote The Mathematical Analysis of Logic, which applied algebraic symbolism to logical forms, whereby the presence or absence of properties could be represented by binary states and combined, just like normal algebraic equations, to derive logical statements about a series of operations. This laid the foundations for the binary logic used in modern computers, which, being based on binary on-off devices, greatly depend on the use of such operations as "and", "nand" ("not and"), "or" and "nor" ("not or"), etc. Although he lacked any formal degree, this revolutionary work led to his appointment in 1849 to the Chair of Mathematics at Queen's College, Cork, where he continued his work on logic and also produce treatises on differential equations and the calculus of finite differences.

[br]

Principal Honours and Distinctions

Royal Society Medal 1844. FRS 1857.

Bibliography

Boole's major contributions to logic available in republished form include George Boole: Investigation of the Laws of Thought, Dover Publications; George Boole: Laws of Thought, Open Court, and George Boole: Studies in Logic \& Probability, Open Court.

1872, A Treatise on Differential Equations.

Further Reading

W.Kneale, 1948, "Boole and the revival of logic", Mind 57:149.

G.C.Smith (ed.), 1982, George Boole \& Augustus de Morgan. Correspondence 1842– 1864, Oxford University Press.

—, 1985, George Boole: His Life and Work, McHale.

E.T.Bell, 1937, Men of Mathematics, London: Victor Gollancz.

KF

Lanston, Tolbert

SUBJECT AREA: Paper and printing

[br]

b. 3 February 1844 Troy, Ohio, USA

d. 18 February 1913 Washington, DC, USA

[br]

American inventor of the Monotype typesetting machine.

[br]

Although reared in a farming community, Lanston was able to develop his mechanical talent. After serving in the American Civil War he secured a clerkship in the Pensions Office in Washington, where he remained for twenty-two years. He studied law in his spare time and was called to the Bar. At the same time, he invented a whole variety of mechanical devices, many of which he patented. Around 1883 Lanston began taking an interest in machines for composing printers' type, probably stimulated by Ottmar Mergenthaler, who was then in Washington and working in this field. Four years' work were rewarded on 7 June 1887 by the grant of a patent, followed by three more, for a machine "to produce justified lines of type". The machine, the Monotype, consisted of two components: first a keyboard unit produced a strip of paper tape with holes punched in patterns corresponding to the characters required; this tape controlled the matrices in the caster, the second and "hot metal" component, from which types were ejected singly and fed to an assembly point until a complete line of type had been formed. Lanston resigned his post and set up the Lanston Type Machine Company in Washington. He laboured for ten years to convert the device defined in his patents into a machine that could be made and used commercially. In 1897 the perfected Monotype appeared. The company was reorganized as the Lanston Monotype Manufacturing Company of Philadelphia, and Lanston devoted himself to promoting and improving the machine. Monotype, with Mergenthaler's Linotype, steadily supplanted hand-setting and the various inadequate mechanical methods that were then in use, and by the 1920s they reigned supreme, until the 1960s, when they themselves began to be superseded by computer-controlled photosetting methods.

[br]

Principal Honours and Distinctions

Franklin Institute Cresson Gold Medal 1896.

Further Reading

Obituary, 1913, American Printer (March).

L.A.Legros and J.C.Grant, 1916, Typographical Printing Surfaces, London.

J.Moran, 1964, The Composition of Reading Matter, London.

LRD

MAPI

A messaging architecture that enables multiple applications to interact with multiple messaging systems across a variety of hardware platforms. MAPI is built on the Component Object Model (COM) foundation.

MAPI

Messaging Application Programming Interface

A messaging architecture that enables multiple applications to interact with multiple messaging systems across a variety of hardware platforms. MAPI is built on the Component Object Model (COM) foundation.

واجهة برمجة تطبيقات الرسائل

Knowledge

   1) To Exist Is to Be Perceived

   It is indeed an opinion strangely prevailing amongst men, that houses, mountains, rivers, and, in a word, all sensible objects, have an existence, natural or real, distinct from their being perceived by the understanding. But, with how great an assurance and acquiescence soever this principle may be entertained in the world, yet whoever shall find in his heart to call it into question may, if I mistake not, perceive it to involve a manifest contradiction. For, what are the forementioned objects but things we perceive by sense? and what do we perceive besides our own ideas or sensations? and is it not plainly repugnant that any one of these, or any combination of them, should exist unperceived? (Berkeley, 1996, Pt. I, No. 4, p. 25)

   2) Abstract Science or Demonstration Is a More Perfect Species of Knowledge

   It seems to me that the only objects of the abstract sciences or of demonstration are quantity and number, and that all attempts to extend this more perfect species of knowledge beyond these bounds are mere sophistry and illusion. As the component parts of quantity and number are entirely similar, their relations become intricate and involved; and nothing can be more curious, as well as useful, than to trace, by a variety of mediums, their equality or inequality, through their different appearances.

   But as all other ideas are clearly distinct and different from each other, we can never advance farther, by our utmost scrutiny, than to observe this diversity, and, by an obvious reflection, pronounce one thing not to be another. Or if there be any difficulty in these decisions, it proceeds entirely from the undeterminate meaning of words, which is corrected by juster definitions. That the square of the hypotenuse is equal to the squares of the other two sides cannot be known, let the terms be ever so exactly defined, without a train of reasoning and enquiry. But to convince us of this proposition, that where there is no property, there can be no injustice, it is only necessary to define the terms, and explain injustice to be a violation of property. This proposition is, indeed, nothing but a more imperfect definition. It is the same case with all those pretended syllogistical reasonings, which may be found in every other branch of learning, except the sciences of quantity and number; and these may safely, I think, be pronounced the only proper objects of knowledge and demonstration. (Hume, 1975, Sec. 12, Pt. 3, pp. 163-165)

   3) Knowledge Derives from Two Fundamental Sources of the Mind

   Our knowledge springs from two fundamental sources of the mind; the first is the capacity of receiving representations (the ability to receive impressions), the second is the power to know an object through these representations (spontaneity in the production of concepts).

   Through the first, an object is given to us; through the second, the object is thought in relation to that representation.... Intuition and concepts constitute, therefore, the elements of all our knowledge, so that neither concepts without intuition in some way corresponding to them, nor intuition without concepts, can yield knowledge. Both may be either pure or empirical.... Pure intuitions or pure concepts are possible only a priori; empirical intuitions and empirical concepts only a posteriori. If the receptivity of our mind, its power of receiving representations in so far as it is in any way affected, is to be called "sensibility," then the mind's power of producing representations from itself, the spontaneity of knowledge, should be called "understanding." Our nature is so constituted that our intuitions can never be other than sensible; that is, it contains only the mode in which we are affected by objects. The faculty, on the other hand, which enables us to think the object of sensible intuition is the understanding.... Without sensibility, no object would be given to us; without understanding, no object would be thought. Thoughts without content are empty; intuitions without concepts are blind. It is therefore just as necessary to make our concepts sensible, that is, to add the object to them in intuition, as to make our intuitions intelligible, that is to bring them under concepts. These two powers or capacities cannot exchange their functions. The understanding can intuit nothing, the senses can think nothing. Only through their union can knowledge arise. (Kant, 1933, Sec. 1, Pt. 2, B74-75 [p. 92])

   4) The Means by Which Metaphysics Can Be Perfected as a Science

   Metaphysics, as a natural disposition of Reason is real, but it is also, in itself, dialectical and deceptive.... Hence to attempt to draw our principles from it, and in their employment to follow this natural but none the less fallacious illusion can never produce science, but only an empty dialectical art, in which one school may indeed outdo the other, but none can ever attain a justifiable and lasting success. In order that, as a science, it may lay claim not merely to deceptive persuasion, but to insight and conviction, a Critique of Reason must exhibit in a complete system the whole stock of conceptions a priori, arranged according to their different sources-the Sensibility, the understanding, and the Reason; it must present a complete table of these conceptions, together with their analysis and all that can be deduced from them, but more especially the possibility of synthetic knowledge a priori by means of their deduction, the principles of its use, and finally, its boundaries....

   This much is certain: he who has once tried criticism will be sickened for ever of all the dogmatic trash he was compelled to content himself with before, because his Reason, requiring something, could find nothing better for its occupation. Criticism stands to the ordinary school metaphysics exactly in the same relation as chemistry to alchemy, or as astron omy to fortune-telling astrology. I guarantee that no one who has comprehended and thought out the conclusions of criticism, even in these Prolegomena, will ever return to the old sophistical pseudo-science. He will rather look forward with a kind of pleasure to a metaphysics, certainly now within his power, which requires no more preparatory discoveries, and which alone can procure for reason permanent satisfaction. (Kant, 1891, pp. 115-116)

   5) Knowledge Is Only Real in the Form of System

   Knowledge is only real and can only be set forth fully in the form of science, in the form of system. Further, a so-called fundamental proposition or first principle of philosophy, even if it is true, it is yet none the less false, just because and in so far as it is merely a fundamental proposition, merely a first principle. It is for that reason easily refuted. The refutation consists in bringing out its defective character; and it is defective because it is merely the universal, merely a principle, the beginning. If the refutation is complete and thorough, it is derived and developed from the nature of the principle itself, and not accomplished by bringing in from elsewhere other counter-assurances and chance fancies. It would be strictly the development of the principle, and thus the completion of its deficiency, were it not that it misunderstands its own purport by taking account solely of the negative aspect of what it seeks to do, and is not conscious of the positive character of its process and result. The really positive working out of the beginning is at the same time just as much the very reverse: it is a negative attitude towards the principle we start from. Negative, that is to say, in its one-sided form, which consists in being primarily immediate, a mere purpose. It may therefore be regarded as a refutation of what constitutes the basis of the system; but more correctly it should be looked at as a demonstration that the basis or principle of the system is in point of fact merely its beginning. (Hegel, 1910, pp. 21-22)

   6) Knowledge, Action, and Evaluation Are Interconnected

   Knowledge, action, and evaluation are essentially connected. The primary and pervasive significance of knowledge lies in its guidance of action: knowing is for the sake of doing. And action, obviously, is rooted in evaluation. For a being which did not assign comparative values, deliberate action would be pointless; and for one which did not know, it would be impossible. Conversely, only an active being could have knowledge, and only such a being could assign values to anything beyond his own feelings. A creature which did not enter into the process of reality to alter in some part the future content of it, could apprehend a world only in the sense of intuitive or esthetic contemplation; and such contemplation would not possess the significance of knowledge but only that of enjoying and suffering. (Lewis, 1946, p. 1)

   7) The Evolution of Knowledge

   "Evolutionary epistemology" is a branch of scholarship that applies the evolutionary perspective to an understanding of how knowledge develops. Knowledge always involves getting information. The most primitive way of acquiring it is through the sense of touch: amoebas and other simple organisms know what happens around them only if they can feel it with their "skins." The knowledge such an organism can have is strictly about what is in its immediate vicinity. After a huge jump in evolution, organisms learned to find out what was going on at a distance from them, without having to actually feel the environment. This jump involved the development of sense organs for processing information that was farther away. For a long time, the most important sources of knowledge were the nose, the eyes, and the ears. The next big advance occurred when organisms developed memory. Now information no longer needed to be present at all, and the animal could recall events and outcomes that happened in the past. Each one of these steps in the evolution of knowledge added important survival advantages to the species that was equipped to use it.

   Then, with the appearance in evolution of humans, an entirely new way of acquiring information developed. Up to this point, the processing of information was entirely intrasomatic.... But when speech appeared (and even more powerfully with the invention of writing), information processing became extrasomatic. After that point knowledge did not have to be stored in the genes, or in the memory traces of the brain; it could be passed on from one person to another through words, or it could be written down and stored on a permanent substance like stone, paper, or silicon chips-in any case, outside the fragile and impermanent nervous system. (Csikszentmihalyi, 1993, pp. 56-57)