drawing properties

drawing properties

• характеристики деформируемости при волочении

• характеристики деформируемости при глубокой вытяжке

drawing properties

Металлургия: характеристики деформируемости при волочении, характеристики деформируемости при глубокой вытяжке

характеристики деформируемости при волочении

Metallurgy: drawing properties

характеристики деформируемости при глубокой вытяжке

Metallurgy: drawing properties

cybermetría

= webometrics.

Ex. Since the mid 1990s a new research field has emerged called ' webometrics', investigating the nature and properties of the Web drawing on modern informetric methodologies.

* * *

= webometrics.

Ex: Since the mid 1990s a new research field has emerged called ' webometrics', investigating the nature and properties of the Web drawing on modern informetric methodologies.

webmetría

= webometrics.

Ex. Since the mid 1990s a new research field has emerged called ' webometrics', investigating the nature and properties of the Web drawing on modern informetric methodologies.

* * *

= webometrics.

Ex: Since the mid 1990s a new research field has emerged called ' webometrics', investigating the nature and properties of the Web drawing on modern informetric methodologies.

webometría

= webometrics.

Ex. Since the mid 1990s a new research field has emerged called ' webometrics', investigating the nature and properties of the Web drawing on modern informetric methodologies.

* * *

= webometrics.

Ex: Since the mid 1990s a new research field has emerged called ' webometrics', investigating the nature and properties of the Web drawing on modern informetric methodologies.

Kirkaldy, David

SUBJECT AREA: Metallurgy, Ports and shipping

[br]

b. 4 April 1820 Mayfield, Dundee, Scotland

d. 25 January 1897 London, England

[br]

Scottish engineer and pioneer in materials testing.

[br]

The son of a merchant of Dundee, Kirkaldy was educated there, then at Merchiston Castle School, Edinburgh, and at Edinburgh University. For a while he worked in his father's office, but with a preference for engineering, in 1843 he commenced an apprenticeship at the Glasgow works of Robert Napier. After four years in the shops he was transferred to the drawing office and in a very few years rose to become Chief. Here Kirkaldy demonstrated a remarkable talent both for the meticulous recording of observations and data and for technical drawing. His work also had an aesthetic appeal and four of his drawings of Napier steamships were shown at the Paris Exhibition of 1855, earning both Napier and Kirkaldy a medal. His "as fitted" set of drawings of the Cunard Liner Persia, which had been built in 1855, is now in the possession of the National Maritime Museum at Greenwich, London; it is regarded as one of the finest examples of its kind in the world, and has even been exhibited at the Royal Academy in London.

With the impending order for the Royal Naval Ironclad Black Prince (sister ship to HMS Warrior, now preserved at Portsmouth) and for some high-pressure marine boilers and engines, there was need for a close scientific analysis of the physical properties of iron and steel. Kirkaldy, now designated Chief Draughtsman and Calculator, was placed in charge of this work, which included comparisons of puddled steel and wrought iron, using a simple lever-arm testing machine. The tests lasted some three years and resulted in Kirkaldy's most important publication, Experiments on Wrought Iron and Steel (1862, London), which gained him wide recognition for his careful and thorough work. Napier's did not encourage him to continue testing; but realizing the growing importance of materials testing, Kirkaldy resigned from the shipyard in 1861. For the next two and a half years Kirkaldy worked on the design of a massive testing machine that was manufactured in Leeds and installed in premises in London, at The Grove, Southwark.

The works was open for trade in January 1866 and engineers soon began to bring him specimens for testing on the great machine: Joseph Cubitt (son of William Cubitt) brought him samples of the materials for the new Blackfriars Bridge, which was then under construction. Soon The Grove became too cramped and Kirkaldy moved to 99 Southwark Street, reopening in January 1874. In the years that followed, Kirkaldy gained a worldwide reputation for rigorous and meticulous testing and recording of results, coupled with the highest integrity. He numbered the most distinguished engineers of the time among his clients.

After Kirkaldy's death, his son William George, whom he had taken into partnership, carried on the business. When the son died in 1914, his widow took charge until her death in 1938, when the grandson David became proprietor. He sold out to Treharne \& Davies, chemical consultants, in 1965, but the works finally closed in 1974. The future of the premises and the testing machine at first seemed threatened, but that has now been secured and the machine is once more in working order. Over almost one hundred years of trading in South London, the company was involved in many famous enquiries, including the analysis of the iron from the ill-fated Tay Bridge (see Bouch, Sir Thomas).

[br]

Principal Honours and Distinctions

Institution of Engineers and Shipbuilders in Scotland Gold Medal 1864.

Bibliography

1862, Results of an Experimental Inquiry into the Tensile Strength and Other Properties of Wrought Iron and Steel (originally presented as a paper to the 1860–1 session of the Scottish Shipbuilders' Association).

Further Reading

D.P.Smith, 1981, "David Kirkaldy (1820–97) and engineering materials testing", Transactions of the Newcomen Society 52:49–65 (a clear and well-documented account).

LRD / FMW

растяжимость

1) General subject: expansibility

2) Biology: compliance

3) Medicine: distensibility

4) Engineering: extensibility, stress-optic properties, stretch, stretchability, tensibility

5) Construction: drawability, drawing ability

6) Mathematics: expandability, tensile strength

7) Polymers: elongation, expansivity, stretching property

8) Automation: expansibiluty

9) Makarov: ductility, resistance to extension (теста), resistance to stretching (теста), stretchability (напр. теста), stretching properties, tensility

10) Cement: dilatability

эластичность

1) General subject: ductility, elasticity, resilience, spring, springiness, loft

2) Medicine: compliance (ткани или органа), elastance, elastans, flexibility

3) Engineering: drawability, drawing ability, give, spring power, springing, stretch, stretchability, tractility

4) Economy: malleability

5) Accounting: elasticity (отражает характер зависимости двух факторов, напр., изменение спроса в зависимости от изменения цен)

6) Optics: (контактной линзы) modulus (также elastic или Young's module, мера сопротивляемости материала деформации, определяется как отношение воздействия к деформации (stress/strain))

7) Perfume: plasticity

8) Coolers: smoothness (моророженого)

9) Drilling: resiliency

10) Aviation medicine: deflection

11) Makarov: elasticity (процент изменения величины одной переменной в результате изменения на одну единицу величины др. переменной; товары считаются менее "эластичными", если изменения цен мало влияют на имеющийся на них спрос)

12) Gold mining: elasicity

13) Laser medicine: pliability

14) Cement: elastic properties

परि _pari _ _री _rī _ _णामः _ṇāmḥ

परि (री) णामः 1 Alteration, change, transforma- tion.

-2 Digestion; अन्नं न सम्यक् परिणाममेति Suśr.; भुक्तस्य परिणामहेतुरौदर्यम् T.S.; Pt.4.22.

-3 Result, consequ- ence, issue, effect; अप्रियस्यापि पथ्यस्य परिणामः सुखावहः H.2.124; Mk.3.1; परिणामसुखे गरीयसि (वचसि औषधे च) Ki.2.4; Bg.18.37,38.

-4 Ripening, maturity, full development; उपैति शस्यं परिणामरम्यताम् Ki.4.22; फलभर- परिणामश्यामजम्बू &c. U.2.2; Māl.9.24.

-5 End, ter- mination, conclusion, close, decline; दिवसाः परिणामरमणीयाः Ś.1.3; वयःपरिणामपाण्डुरशिरसम् K.1; परिणाममुपैति दिवसः K.254 'the day is drawing to a close'.

-6 Old age; परिणामे हि दिलीपवंशजाः R.8.11.

-7 Lapse (of time).

-8 (In Rhet.) A figure of speech allied to रूपक, by which the properties of any object are transferred to that with which it is compared. (The Chandrāloka thus defines and illustrates it:-- परिणामः क्रियार्थश्चेद्विषयी विषयात्मना । प्रसन्नेन दृगब्जेन वीक्षते मदिरेक्षणा ॥ 5.18; see R. G. also under परिणाम).

-Comp. -जम् Violent or painful indigestion (see शूलम् below).

-दर्शिन् a. prudent, fore-sighted.

-दृष्टि a. prudent. (

-ष्टिः f.) prudence, providence.

-पथ्य a. salutary in the end.

-मुख a. about to termi- nate.

-वादः the S&amacrṅkhya doctrine of evolution.

-शूलम् violent or painful indigestion, colic, flatulence with pain.

масло

acid refined oil, butter, (растительное, минеральное, смазочное) oil

* * *

ма́сло с.

1. ( техническое) oil

вари́ть ма́сло — boil an oil

вводи́ть загусти́тель в ма́сло — thicken an oil

вводи́ть приса́дки в ма́сло — dope an oil

ма́сло вспе́нивается — the oil churns [foams]

загуща́ть ма́сло — give (more) body to an oil

ма́сло застыва́ет — the oil solidifies

ма́сло коксу́ется — the oil has carbon-forming properties

компаунди́ровать ма́сло — blend (the) oil

обесцве́чивать ма́сло — decolourize oil

осветля́ть ма́сло — clarify oil

отбе́ливать ма́сло — bleach oil

отжима́ть ма́сло — isolate oil by pressing [by expression]

очища́ть ма́сло — refine oil

продува́ть ма́сло ( для окисления примесей) — blow the oil

прокача́ть ма́сло — circulate oil (through a system)

уплотня́ть ма́сло — body oil

2. ( коровье) butter; ( растительное) oil

ма́сло ма́сло го́ркнет — butter becomes rancid

па́хтать [сбива́ть] ма́сло — churn butter

авиацио́нное ма́сло — aviation oil

автотра́кторное ма́сло — motor oil

ара́хисовое ма́сло — peanut [ground-nut] oil

ацето́новое ма́сло — acetone oil

бе́лое ма́сло — white oil

вазели́новое ма́сло — petrolatum, petroleum jelly

веретё́нное ма́сло — spindle oil

всесезо́нное ма́сло авто — multigrade oil

высыха́ющее ма́сло — drying oil

подверга́ть высыха́ющее ма́сло обрабо́тке путё́м нагрева́ния — beat-treat a drying oil

вя́зкое ма́сло — thick oil

га́зовое ма́сло — gas oil

гидравли́ческое ма́сло — hydraulic oil

густо́е ма́сло — thick oil

дегтя́рное ма́сло — tar oil

ди́зельное ма́сло — diesel oil

дисперги́рующее ма́сло — dispersion oil

дистилля́тное ма́сло — distillate oil

ма́сло для волоче́ния метал. — drawing oil

ма́сло для сма́зки форм — mould oil

живо́тное ма́сло — animal oil

зака́лочное ма́сло — quenching oil

зелё́ное ма́сло — green oil

изоляцио́нное ма́сло — insulating oil

и́мпульсное ма́сло — impulse oil

индустриа́льное ма́сло — industrial oil

ка́бельное ма́сло — cable oil

каменноу́гольное ма́сло — coal-tar oil

канифо́льное ма́сло — resin oil

касто́ровое ма́сло — castor oil

катализи́рованное ма́сло — catalyzed oil

коже́венное ма́сло — curriers [leather] oil

коко́совое ма́сло — coconut oil

компаунди́рованное ма́сло — compounded [blended] oil

компре́ссорное ма́сло — compressor oil

конденса́торное ма́сло — condenser [capacitor] oil

кукуру́зное ма́сло — corn oil

лё́гкое ма́сло — light [thin] oil

лету́чее ма́сло — volatile oil

льняно́е ма́сло — linseed oil

льняно́е, ла́ковое ма́сло — varnish linseed oil

маши́нное ма́сло — machine oil

минера́льное ма́сло — petroleum oil

морозосто́йкое ма́сло — non-freezable oil

мото́рное ма́сло — motor oil

напо́рное ма́сло — power oil

нафтали́новое ма́сло — naphthalene oil

невысыха́ющее ма́сло — non-drying oil

непищево́е ма́сло — inedible oil

несма́зочное ма́сло — non-lubricating oil

нефтяно́е ма́сло — petroleum oil

оли́вковое ма́сло — olive oil

осево́е ма́сло — axle oil

освети́тельное ма́сло — illuminating oil

оста́точное ма́сло — residual oil

отрабо́тавшее ма́сло — used [waste] oil

отсто́йное ма́сло — sump oil

очи́щенное ма́сло — refined oil

парафи́новое ма́сло — paraffin oil

пери́лловое ма́сло — perilla oil

печа́тное ма́сло — lithographic oil

пищево́е ма́сло — edible oil

поглоти́тельное ма́сло — absorption [absorbent, scrubbing] oil; ( в коксохимическом производстве) wash [straw] oil

подви́жное ма́сло — thin on

полимеризо́ванное ма́сло — polymerized [bodied] oil

препари́рованное ма́сло — prepared oil

прибо́рное ма́сло — instrument oil

противозади́рное ма́сло — high-pressure [extreme-pressure] oil

тпылесбива́ющее ма́сло — road oil

рабо́чее ма́сло — power oil; pressure oil; relay oil

ра́псовое ма́сло — rapeseed on

раствори́мое ма́сло — soluble oil

расти́тельное ма́сло — vegetable oil

расти́тельное, жи́рное ма́сло — fatty [fixed] (vegetable) oil

реакти́вное ма́сло — jet-engine oil

регенери́рованное ма́сло — refiltered oil

рези́новое ма́сло — rubber oil

синтети́ческое ма́сло — synthetic oil

скипида́рное ма́сло — turpentine essence

скру́бберное ма́сло — wash oil

сма́зочное ма́сло — lubricating oil

сма́зочное, фильтро́ванное ма́сло — filter stock

сма́зочно-охлажда́ющее ма́сло — cutting oil

смоляно́е ма́сло — resin [tar] oil

со́евое ма́сло — soybean oil

соля́ровое ма́сло — straw oil

сополимеризо́ванное ма́сло — copolymerized oil

сре́днее ма́сло — middle oil

стеари́новое ма́сло — stearine oil

сыро́е ма́сло — crude oil

технологи́ческое ма́сло — process oil

трансмиссио́нное ма́сло — transmission [gear-box] oil

трансформа́торное ма́сло — transformer oil

ту́нговое ма́сло — tung oil

турби́нное ма́сло — turbine oil

углеводоро́дное ма́сло — hydrocarbon oil

уплотнё́нное ма́сло — bodied oil

фено́льное ма́сло — carbolic oil

флотацио́нное древесносмоляно́е ма́сло — wood-resin flotation oil

хло́пковое ма́сло — cottonseed oil

цили́ндровое ма́сло — cylinder oil

шве́йное ма́сло — sewing(-machine) oil

шпалопропи́точное ма́сло — sleeper impregnation oil

электроизоляцио́нное ма́сло — electrical insulating oil

эмульсио́нное ма́сло — cutting oil

эфи́рное ма́сло — essential oil

mechanical

mechanical admittance

mechanical air filter

mechanical analysis

mechanical behavior test

mechanical behaviour test

mechanical bond

mechanical boy

mechanical broom

mechanical chopper

mechanical classifier

mechanical collector

mechanical component

mechanical concentration

mechanical contactor

mechanical cutter

mechanical decanning

mechanical decladding

mechanical dividing head

mechanical draftsman

mechanical draughtsman

mechanical drawing

mechanical drive

mechanical editing

mechanical efficiency

mechanical end stop

mechanical endurance

mechanical energy

mechanical engineer

mechanical engineering

mechanical equivalent of heat

mechanical error

mechanical exhaust air installations

mechanical filter

mechanical firing

mechanical fuel pump

mechanical grab

mechanical hazard

mechanical impedance

mechanical instability

mechanical interlock

mechanical isolation

mechanical latch

mechanical life

mechanical locking

mechanical milking

mechanical modulation

mechanical operation

mechanical optical switch

mechanical oscillation

mechanical overlay

mechanical piping

mechanical polishing

mechanical properties

mechanical pulp

mechanical-pulp board

mechanical reactance

mechanical recorder

mechanical recording

mechanical refrigeration

mechanical resistance

mechanical resonance

mechanical sample

mechanical setting

mechanical shearing

mechanical shock test

mechanical spin attachment

mechanical splice

mechanical stability

mechanical stage

mechanical stage control

mechanical stoker

mechanical stop unit

mechanical system

mechanical testing

mechanical tint

mechanical transmission

mechanical transmission system

mechanical trencher

mechanical tripping device

mechanical vibration

mechanical wave

mechanical wear

mechanical weathering

mechanical woodpulp

mechanical woodpulp board

mechanical woodpulp paper

mechanical zero adjustment

Brewster, Sir David

SUBJECT AREA: Photography, film and optics

[br]

b. 11 December 1781 Jedburgh, Roxburghshire, Scotland

d. 10 February 1868 Allerly, Scotland

[br]

Scottish scientist and popularizer of science, inventor of the kaleidoscope and lenticular stereoscope.

[br]

Originally destined to follow his father into the Church, Brewster studied divinity at Edinburgh University, where he met many distinguished men of science. He began to take a special interest in optics, and eventually abandoned the clerical profession. In 1813 he presented his first paper to the Royal Society on the properties of light, and within months invented the principle of the kaleidoscope. In 1844 Brewster described a binocular form of Wheatstone's reflecting stereoscope where the mirrors were replaced with lenses or prisms. The idea aroused little interest at the time, but in 1850 a model taken to Paris was brought to the notice of L.J. Duboscq, who immediately began to manufacture Brewster's stereoscope on a large scale; shown at the Great Exhibition of 1851, it attracted the attention of Queen Victoria. Stereoscopic photography rapidly became one of the fashionable preoccupations of the day arid did much to popularize photography. Although originally marketed as a scientific toy and drawing-room pastime, stereoscopy later found scientific application in such fields as microscopy, photogrammetry and radiography. Brewster was a prolific scientific author throughout his life. His income was derived mainly from his writing and he was one of the nineteenth century's most distinguished popularizers of science.

[br]

Principal Honours and Distinctions

Knighted 1832. FRS 1815.

Further Reading

Dictionary of National Biography, 1973, Vol. II, Oxford, pp. 1,207–11.

A.D.Morrison-Low and J.R.R.Christie (eds), 1984, Martyr of Science, Edinburgh (proceedings of a Bicentenary Symposium).

JW

Carnot, Nicolas Léonard Sadi

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 1 June 1796 Paris, France

d. 24 August 1831 Paris, France

[br]

French laid the foundations for modern thermodynamics through his book Réflexions sur la puissance motrice du feu when he stated that the efficiency of an engine depended on the working substance and the temperature drop between the incoming and outgoing steam.

[br]

Sadi was the eldest son of Lazare Carnot, who was prominent as one of Napoleon's military and civil advisers. Sadi was born in the Palais du Petit Luxembourg and grew up during the Napoleonic wars. He was tutored by his father until in 1812, at the minimum age of 16, he entered the Ecole Polytechnique to study stress analysis, mechanics, descriptive geometry and chemistry. He organized the students to fight against the allies at Vincennes in 1814. He left the Polytechnique that October and went to the Ecole du Génie at Metz as a student second lieutenant. While there, he wrote several scientific papers, but on the Restoration in 1815 he was regarded with suspicion because of the support his father had given Napoleon. In 1816, on completion of his studies, Sadi became a second lieutenant in the Metz engineering regiment and spent his time in garrison duty, drawing up plans of fortifications. He seized the chance to escape from this dull routine in 1819 through an appointment to the army general staff corps in Paris, where he took leave of absence on half pay and began further courses of study at the Sorbonne, Collège de France, Ecole des Mines and the Conservatoire des Arts et Métiers. He was inter-ested in industrial development, political economy, tax reform and the fine arts.

It was not until 1821 that he began to concentrate on the steam-engine, and he soon proposed his early form of the Carnot cycle. He sought to find a general solution to cover all types of steam-engine, and reduced their operation to three basic stages: an isothermal expansion as the steam entered the cylinder; an adiabatic expansion; and an isothermal compression in the condenser. In 1824 he published his Réflexions sur la puissance motrice du feu, which was well received at the time but quickly forgotten. In it he accepted the caloric theory of heat but pointed out the impossibility of perpetual motion. His main contribution to a correct understanding of a heat engine, however, lay in his suggestion that power can be produced only where there exists a temperature difference due "not to an actual consumption of caloric but to its transportation from a warm body to a cold body". He used the analogy of a water-wheel with the water falling around its circumference. He proposed the true Carnot cycle with the addition of a final adiabatic compression in which motive power was con sumed to heat the gas to its original incoming temperature and so closed the cycle. He realized the importance of beginning with the temperature of the fire and not the steam in the boiler. These ideas were not taken up in the study of thermodynartiics until after Sadi's death when B.P.E.Clapeyron discovered his book in 1834.

In 1824 Sadi was recalled to military service as a staff captain, but he resigned in 1828 to devote his time to physics and economics. He continued his work on steam-engines and began to develop a kinetic theory of heat. In 1831 he was investigating the physical properties of gases and vapours, especially the relationship between temperature and pressure. In June 1832 he contracted scarlet fever, which was followed by "brain fever". He made a partial recovery, but that August he fell victim to a cholera epidemic to which he quickly succumbed.

[br]

Bibliography

1824, Réflexions sur la puissance motrice du feu; pub. 1960, trans. R.H.Thurston, New York: Dover Publications; pub. 1978, trans. Robert Fox, Paris (full biographical accounts are provided in the introductions of the translated editions).

Further Reading

Dictionary of Scientific Biography, 1971, Vol. III, New York: C.Scribner's Sons. T.I.Williams (ed.), 1969, A Biographical Dictionary of Scientists, London: A. \& C.

Black.

Chambers Concise Dictionary of Scientists, 1989, Cambridge.

D.S.L.Cardwell, 1971, from Watt to Clausius. The Rise of Thermodynamics in the Early Industrial Age, London: Heinemann (discusses Carnot's theories of heat).

RLH

Language

   1) The Book of Nature Is Written in the Language of Mathematics

   Philosophy is written in that great book, the universe, which is always open, right before our eyes. But one cannot understand this book without first learning to understand the language and to know the characters in which it is written. It is written in the language of mathematics, and the characters are triangles, circles, and other figures. Without these, one cannot understand a single word of it, and just wanders in a dark labyrinth. (Galileo, 1990, p. 232)

   2) Arranging Speech so as to Reply Appropriately

   It never happens that it [a nonhuman animal] arranges its speech in various ways in order to reply appropriately to everything that may be said in its presence, as even the lowest type of man can do. (Descartes, 1970a, p. 116)

   3) No Other Animal Has the Language Capacity of the Human

   It is a very remarkable fact that there are none so depraved and stupid, without even excepting idiots, that they cannot arrange different words together, forming of them a statement by which they make known their thoughts; while, on the other hand, there is no other animal, however perfect and fortunately circumstanced it may be, which can do the same. (Descartes, 1967, p. 116)

   4) Human Beings Do Not Live Only in the World of Objects

   Human beings do not live in the object world alone, nor alone in the world of social activity as ordinarily understood, but are very much at the mercy of the particular language which has become the medium of expression for their society. It is quite an illusion to imagine that one adjusts to reality essentially without the use of language and that language is merely an incidental means of solving specific problems of communication or reflection. The fact of the matter is that the "real world" is to a large extent unconsciously built on the language habits of the group.... We see and hear and otherwise experience very largely as we do because the language habits of our community predispose certain choices of interpretation. (Sapir, 1921, p. 75)

   5) Language Powerfully Conditions All Our Thinking

   It powerfully conditions all our thinking about social problems and processes.... No two languages are ever sufficiently similar to be considered as representing the same social reality. The worlds in which different societies live are distinct worlds, not merely the same worlds with different labels attached. (Sapir, 1985, p. 162)

   6) A List of Language Games

   [A list of language games, not meant to be exhaustive:]

   Giving orders, and obeying them- Describing the appearance of an object, or giving its measurements- Constructing an object from a description (a drawing)Reporting an eventSpeculating about an eventForming and testing a hypothesisPresenting the results of an experiment in tables and diagramsMaking up a story; and reading itPlay actingSinging catchesGuessing riddlesMaking a joke; and telling it

   Solving a problem in practical arithmeticTranslating from one language into another

   LANGUAGE Asking, thanking, cursing, greeting, and praying-. (Wittgenstein, 1953, Pt. I, No. 23, pp. 11 e-12 e)

   7) Language Constrains Certain Modes of Interpretation

   We dissect nature along lines laid down by our native languages.... The world is presented in a kaleidoscopic flux of impressions which has to be organized by our minds-and this means largely by the linguistic systems in our minds.... No individual is free to describe nature with absolute impartiality but is constrained to certain modes of interpretation even while he thinks himself most free. (Whorf, 1956, pp. 153, 213-214)

   8) We Dissect Nature in Accordance with Our Native Languages

   We dissect nature along the lines laid down by our native languages.

   The categories and types that we isolate from the world of phenomena we do not find there because they stare every observer in the face; on the contrary, the world is presented in a kaleidoscopic flux of impressions which has to be organized by our minds-and this means largely by the linguistic systems in our minds.... We are thus introduced to a new principle of relativity, which holds that all observers are not led by the same physical evidence to the same picture of the universe, unless their linguistic backgrounds are similar or can in some way be calibrated. (Whorf, 1956, pp. 213-214)

   9) The Forms of a Person's Thoughts Are Controlled by Unperceived Patterns of His Own Language

   The forms of a person's thoughts are controlled by inexorable laws of pattern of which he is unconscious. These patterns are the unperceived intricate systematizations of his own language-shown readily enough by a candid comparison and contrast with other languages, especially those of a different linguistic family. (Whorf, 1956, p. 252)

    10) The Analysis of Certain Types of Utterances

   It has come to be commonly held that many utterances which look like statements are either not intended at all, or only intended in part, to record or impart straightforward information about the facts.... Many traditional philosophical perplexities have arisen through a mistake-the mistake of taking as straightforward statements of fact utterances which are either (in interesting non-grammatical ways) nonsensical or else intended as something quite different. (Austin, 1962, pp. 2-3)

    11) The Dictionary of a Language Is a System of Concepts

   In general, one might define a complex of semantic components connected by logical constants as a concept. The dictionary of a language is then a system of concepts in which a phonological form and certain syntactic and morphological characteristics are assigned to each concept. This system of concepts is structured by several types of relations. It is supplemented, furthermore, by redundancy or implicational rules..., representing general properties of the whole system of concepts.... At least a relevant part of these general rules is not bound to particular languages, but represents presumably universal structures of natural languages. They are not learned, but are rather a part of the human ability to acquire an arbitrary natural language. (Bierwisch, 1970, pp. 171-172)

    12) Talk about the Evolution of the Language Capacity is Beside the Point

   In studying the evolution of mind, we cannot guess to what extent there are physically possible alternatives to, say, transformational generative grammar, for an organism meeting certain other physical conditions characteristic of humans. Conceivably, there are none-or very few-in which case talk about evolution of the language capacity is beside the point. (Chomsky, 1972, p. 98)

    13) The Development of Language

   [It is] truth value rather than syntactic well-formedness that chiefly governs explicit verbal reinforcement by parents-which renders mildly paradoxical the fact that the usual product of such a training schedule is an adult whose speech is highly grammatical but not notably truthful. (R. O. Brown, 1973, p. 330)

    14) Sentential and Conceptual Levels in Language

   he conceptual base is responsible for formally representing the concepts underlying an utterance.... A given word in a language may or may not have one or more concepts underlying it.... On the sentential level, the utterances of a given language are encoded within a syntactic structure of that language. The basic construction of the sentential level is the sentence.

   The next highest level... is the conceptual level. We call the basic construction of this level the conceptualization. A conceptualization consists of concepts and certain relations among those concepts. We can consider that both levels exist at the same point in time and that for any unit on one level, some corresponding realizate exists on the other level. This realizate may be null or extremely complex.... Conceptualizations may relate to other conceptualizations by nesting or other specified relationships. (Schank, 1973, pp. 191-192)

    15) Linguistic Realities Have Not Yet Been Captured by Theoretical Models

   The mathematics of multi-dimensional interactive spaces and lattices, the projection of "computer behavior" on to possible models of cerebral functions, the theoretical and mechanical investigation of artificial intelligence, are producing a stream of sophisticated, often suggestive ideas.

   But it is, I believe, fair to say that nothing put forward until now in either theoretic design or mechanical mimicry comes even remotely in reach of the most rudimentary linguistic realities. (Steiner, 1975, p. 284)

    16) The Final Steps to Human Language

   The step from the simple tool to the master tool, a tool to make tools (what we would now call a machine tool), seems to me indeed to parallel the final step to human language, which I call reconstitution. It expresses in a practical and social context the same understanding of hierarchy, and shows the same analysis by function as a basis for synthesis. (Bronowski, 1977, pp. 127-128)

    17) The Inadequacy of Formal Linguistic Models for Ordinary Language Usage

    t is the language donn eґ in which we conduct our lives.... We have no other. And the danger is that formal linguistic models, in their loosely argued analogy with the axiomatic structure of the mathematical sciences, may block perception.... It is quite conceivable that, in language, continuous induction from simple, elemental units to more complex, realistic forms is not justified. The extent and formal "undecidability" of context-and every linguistic particle above the level of the phoneme is context-bound-may make it impossible, except in the most abstract, meta-linguistic sense, to pass from "pro-verbs," "kernals," or "deep deep structures" to actual speech. (Steiner, 1975, pp. 111-113)

    18) When a Language Is an Abstract Machine

   A higher-level formal language is an abstract machine. (Weizenbaum, 1976, p. 113)

    19) Metaphor and Metonymy Underpin the Formation of Linguistic Signs

   Jakobson sees metaphor and metonymy as the characteristic modes of binarily opposed polarities which between them underpin the two-fold process of selection and combination by which linguistic signs are formed.... Thus messages are constructed, as Saussure said, by a combination of a "horizontal" movement, which combines words together, and a "vertical" movement, which selects the particular words from the available inventory or "inner storehouse" of the language. The combinative (or syntagmatic) process manifests itself in contiguity (one word being placed next to another) and its mode is metonymic. The selective (or associative) process manifests itself in similarity (one word or concept being "like" another) and its mode is metaphoric. The "opposition" of metaphor and metonymy therefore may be said to represent in effect the essence of the total opposition between the synchronic mode of language (its immediate, coexistent, "vertical" relationships) and its diachronic mode (its sequential, successive, lineal progressive relationships). (Hawkes, 1977, pp. 77-78)

    20) Language and the Analysis of Nature

   It is striking that the layered structure that man has given to language constantly reappears in his analyses of nature. (Bronowski, 1977, p. 121)

    21) Correspondence Rules for Mapping Old Theory into Subsets of New Theory

   First, [an ideal intertheoretic reduction] provides us with a set of rules"correspondence rules" or "bridge laws," as the standard vernacular has it-which effect a mapping of the terms of the old theory (T o) onto a subset of the expressions of the new or reducing theory (T n). These rules guide the application of those selected expressions of T n in the following way: we are free to make singular applications of their correspondencerule doppelgangers in T o....

   Second, and equally important, a successful reduction ideally has the outcome that, under the term mapping effected by the correspondence rules, the central principles of T o (those of semantic and systematic importance) are mapped onto general sentences of T n that are theorems of Tn. (P. Churchland, 1979, p. 81)

    22) The Inclusion of Non- linguistic Factors in a Theory of Grammar

   If non-linguistic factors must be included in grammar: beliefs, attitudes, etc. [this would] amount to a rejection of the initial idealization of language as an object of study. A priori such a move cannot be ruled out, but it must be empirically motivated. If it proves to be correct, I would conclude that language is a chaos that is not worth studying.... Note that the question is not whether beliefs or attitudes, and so on, play a role in linguistic behavior and linguistic judgments... [but rather] whether distinct cognitive structures can be identified, which interact in the real use of language and linguistic judgments, the grammatical system being one of these. (Chomsky, 1979, pp. 140, 152-153)

    23) Language Is Inevitably Influenced by Specific Contexts of Human Interaction

   Language cannot be studied in isolation from the investigation of "rationality." It cannot afford to neglect our everyday assumptions concerning the total behavior of a reasonable person.... An integrational linguistics must recognize that human beings inhabit a communicational space which is not neatly compartmentalized into language and nonlanguage.... It renounces in advance the possibility of setting up systems of forms and meanings which will "account for" a central core of linguistic behavior irrespective of the situation and communicational purposes involved. (Harris, 1981, p. 165)

    24) The Genetic Blueprints of Language

   By innate [linguistic knowledge], Chomsky simply means "genetically programmed." He does not literally think that children are born with language in their heads ready to be spoken. He merely claims that a "blueprint is there, which is brought into use when the child reaches a certain point in her general development. With the help of this blueprint, she analyzes the language she hears around her more readily than she would if she were totally unprepared for the strange gabbling sounds which emerge from human mouths. (Aitchison, 1987, p. 31)

    25) Languages Are Machines

   Looking at ourselves from the computer viewpoint, we cannot avoid seeing that natural language is our most important "programming language." This means that a vast portion of our knowledge and activity is, for us, best communicated and understood in our natural language.... One could say that natural language was our first great original artifact and, since, as we increasingly realize, languages are machines, so natural language, with our brains to run it, was our primal invention of the universal computer. One could say this except for the sneaking suspicion that language isn't something we invented but something we became, not something we constructed but something in which we created, and recreated, ourselves. (Leiber, 1991, p. 8)