110 résultats
200973245Basel, Birkhäuser (Birkhäuser Advanced Texts), 2009. XIX, 575 S. (24 cm) Pappband / gebundene Ausgabe
200473213New York/Berlin, Springer (Grundlehren Text Editions / GLT), 2004. IX, 363 S. (24 cm) Paperback / kartonierte Ausgabe
Mm 175x245 Ristampa anastatica su quella originale del 1929. Brossura originale a stampa, xi-573 pp. Timbri di biblioteca privata dismessa in alcune pagine, tracce di nastro adesivo alla prima ed ultima carta, peraltro il libro è in buone-ottime condizioni. Spedizione in 24 ore dalla conferma dell'ordine.
Mm 175x245 Ristampa anastatica su quella originale del 1929. Volume nella sua brossura originale, xi-573 pagine. Copia eccellente poco o nulla consultata. Spedizione in 24 ore dalla conferma dell'ordine.
177946989Paris Ph.-D. Pierres 1779. 4to. Nice recent vellum titlelabel with gilt lettering on spine. 4XXVIII471 pp. Wide-margined clean and fine. <br/><br/><em>First edition of Bezout's main work - a fundamental contribution to algebraic geometry - in which he prooved the so called ´Bezout's theorem. The theorem was essentially stated by Isaac Newton in his proof of lemma 28 of volume 1 of his Principia where he claims that two curves have a number of intersection points given by the product of their degrees.Bézout's theorem is a statement in algebraic geometry concerning the number of common points or intersection points of two plane algebraic curves. The theorem claims that the number of common points of two such curves X and Y is equal to the product of their degrees. The work stimulated many investigations in the modern theory of elimination including Cauchy’s refinements of elimination procedure and Sylvester’s work on resultants and inertia forms. Bezout’s theorem is crucial to the study of the intersection of manifolds in algebraic geometry."It was not until 1779 that Bezout published his Théorie des équations algébriques his major work on elimination theory. Its best-known achievement is the statement and proof of Bezout’s theorem: "The degree of the final equation resulting from any number of complete equations in the same number of unknowns and of any degrees is equal to the product of the degrees of the equations." Bezout following Euler defined a complete polynomial as one that contains each possible combination of the unknowns whose degree is no more than the degree of the polynomial. Bezout also computed that the degree of the resultant equation is less than the product of the degrees for various systems of incomplete equations. Here we shall consider only the complete case.The proof makes one marvel at the ingenuity of Bezout who like Euler not only could manipulate formulas but also had the ability to choose those manipulations that would be fruitful. He was compelled to justify his nth-order results by a naive "induction" from the observed truth of the statements for 1 2 3 ···. Also numbered subscripts had not yet come into use and the notations available were clumsy."DSB. </em> hardcover
191130628École Polytechnique 1911 in-4° 246 pp autographiées et 10 pages dactylographiées à la fin , une page déchirée sans manque
In 4°; (10 inclusa errata), 86 pp. Legatura coeva in mezza-pelle con titolo e fregi in oro al dorso. Piatti foderati con carta marmorizzata coeva (qualche lieve segno del tempo alla legatura). All'interno esemplare in ottime condizioni di conservazione. Prima non comune edizione di questa importante opera matematica del celebre matematico francese, Ferdinand François Désiré Budan de Boislaurent (28 settembre 1761 - 6 ottobre 1840) che divenne famoso proprio grazie al trattato qui presentato. Iniziato a studiare a Juilly, proseguì poi a Parigi, dove si iscrisse a medicina, ottenendo il dottorato con una tesi su una questione di “Economia medica” dove sosteneva la necessità di informare in modo corretto un paziente sulla sua situazione medica. Raggiunse la celebrità quando nel 1807 pubblicò il suo “Nouvelle Methode” nel quale alla stregua di Fourier ma in modo diverso e prima di questi (il lavoro Budan lo aveva già compiuto e finito nel 1803, spiega “given a monic polynomial p(x), the coefficients of p(x+1) can be obtained by developing a Pascal-like triangle with first row the coefficients of p(x), rather than by expanding successive powers of x+1, as in Pascal's triangle proper, and then summing”. Questa regola è ancora nota come il Teorema di Budan ed è un teorema di delimitazione il numero di radici reali di un polinomio in un intervallo e calcolando la parità di questo numero. Il lavoro di Budan fu ripreso, tra gli altri, da Pierre Louis Marie Bourdon (1779-1854), nel suo celebre libro di algebra, ma con il tempo , venne eclissato dal Teorema di Fourier che garantiva un risultato equivalente. Il Teorema di Budan è però stato fortemente recuperato a partire dalla fine del XIX° secolo quando ci si accorse che alcuni risultati computazionali erano più facilmente deducibili da esso che dalla versione offerta da Fourier. In particolare, furono Collins e Akritas nel 1976 a recuperarlo, per la fornitura, in computer algebra, di un algoritmo efficiente per l'isolamento di radici nei computer. All'uscita dell'opera, la fama di Boudan, iniziò ad aumentare esponenzialmente anche oltre Manica, tanto da venir citato da numerosi importanti matematici e studiosi come ad esempio Peter Barlow o Horner. Barlow lo nominò alla voce “Approssimazione” nel suo Dizionario del 1814, sebbene, erroneamente lo affiancasse al metodo di Joseph-Louis Lagrange, definendolo come accurato ma più di interesse teorico che pratico. Horner descrivendo il lavoro di Budan sull'Approsimazione nel suo celebre articolo sulle Transazioni filosofiche presentato alla Royal Society di Londra nel 1819, articolo che diede origine al termine metodo di Horner, commentò in modo scettico i risultati di Budan ma in articoli seguenti, cambiò completamente opinione, riconoscendone il valore intrinseco. Il lavoro di Budan sembra anticipare anche quello di Paolo Ruffini del 1804. Si legge in D. S. B., II, 573 : :"Budan is known in the theory of equations as one of the independent discoverers of the rule of Budan and Fourier, which gives necessary conditions for a polynomial equation to have n real roots between two given real numbers. He announced his discovery of the rule and described its use (...) and published the paper with explanatory notes, as 'Nouvelle méthode pour la résolution des équations numériques', in 1807. (...) The need for such a rule as his was suggested to Budan by Lagrange's 'Traite de la resolution des equations numeriques' (1767). (. . .) Budan's goal was to solve Lagrange's problem - between which real numbers do real roots lie? - purely by means of elementary arithmetic. Accordingly, the chief concern of Budan's 'Nouvelle méthode' was to give the reader a mechanical process for calculating the coefficients of the transformed equation in (x - p). He did not appeal to the theory of finite differences or to the calculus for these coefficients, preferring to give them 'by means of simple additions and subtractions.' (...) Budan's rule remains the most convenient for computation". Proprio grazie agli sviluppi tecnologici della fine del novecento ed essendo usato in moderni algoritmi veloci per isolare le radici reali di polinomi, l'opera qui presentata è diventata, oggi, un classico della matematica ed è qui presentata in prima edizione, in legatura coeva ed in buone-ottime condizioni di conservazione. Non comune. First edition, good copy. Rif. Bibl.: D.S.B.,II,573.
Appendix by Norbert Wiener. 392 pages. Includes Index. Allen H. Schooley's owner's stamp on front free endpaper and title page. Small name label of Erwin Tomash at lower corner of front pastedown. Light wear to cover extremities. Page edges greyed.
19961259601996 Cambridge University Press - 1996 - Reprint with corrections - In-8 broché, couverture illustrée - 355 pages - Texte en anglais
184149105Paris Bachelier 1841. 4to. Without wrappers. In "Comptes rendus hebdomadaires des séances de l’Académie des sciences" Vol. XII No 6. Pp. 267- 316. Entire issue offered. Cauchy's paper: pp. 283-298. Some scattered brownspots. <br/><br/><em>First printing of an importent paper in information theory - the paper stating the earliest version of what will later be known as the "Nyquist Sampling Theorem" describing how many and what kind of samples are needed to construct a curve."The theorem will be formulated more completely in 1928 and become one of the cornerstones of information theory" Bryan Bunch 1841 M. </em> unknown
185842295London Richard Taylor and William Francis 1858 and Taylor and Francis 1866. 4to. No wrappers as extracted from "Philosophical Transactions" Vol. 148 - Part I. Pp. 17-37 and Vol. 156 - Part I Pp. 25-35. Clean and fine. <br/><br/><em>First appearance of this outstanding contribution to mathematics announcing his invention and developments of the ALGEBRA OF MATRICES what is now called the Cayley-Hamilton theorem for square matrices of any order. "The subject originated in a memoir of 1858 the paper offered and grew directly out of simple observations on the way in which the transformations linear of the theory of algebraic invariants are combined.a distinctive feature of these rules is that multiplication is not commutative.we get different results according to the order in which we do the multiplication. it seems about as far from anything of scientific or practical use as anything could possible be. Yet sixty seven years after Cayley's invented it HEISENBERG in 1925 recognized in the algebra of matrices exactly the tool which he neede for his revolutionary work in QUANTUM MECHANICS."Bell Men of Mathematics."It was in connection with the study of invariants under linear transformation that Cayley first introduced matrices to simplify the notation involved. Here he gave some basic notions. This was followed by his first major paper on the subject "A Memoir on the Theory of Matrices." the paper offered here. Kline Mathematical Thought.p. 806. </em> unknown
187941917London Edward Stanford 1879. Without wrappers in "Proceedings of the Royal Geographical Society and monthly Record of Geography" April issue with titlepage to vol. 1 1879. Pp.2 225-288 a. 2 folded maps. Cayley's paper: pp. 259-261 <br/><br/><em>Fitrst appearance of Cayley's famous paper on the Four-Colour-Problem"The four-colour map problem to prove that on any map only four colours are needed to separate countries is celebrated in mathematics. It resisted the attempts of able mathematicians for over a century and when it was successfully proved in 1976 the ‘computer proof’ was controversial: it did not allow scrutiny in the conventional way. At the height of his influence in 1878 Arthur Cayley had drawn attention to the problem at a meeting of the London Mathematical Society and it was duly ‘announced’ in print. the paper offered. He made a short contribution himself and he encouraged the young A. B. Kempe to publish a paper on the subject. Though ultimately unsuccessful the work of Cayley and Kempe in the late 1870s brought valuable insights. Francis Galton is revealed as the ‘go-between’ in suggesting Cayley publish his observations in Proceedings of the Royal Geographical Society." Tony Crilly.The Four-Colour-Theorem was proved in 1976 by Kenneth Appel and Wolfgang Haken. It was the first major mathematical theorem to be proved using a computer. </em> unknown
19701253071970 Springer-Verlag Berlin / Heidelberg / New York - Collection "Die Grundlehren der matematischenn Wissenschaften in Einzeldarstellungen" vol. 167 - 1970 - In-8, reliure pleine toile sous jaquette - XI-231 pages - Texte en anglais
47123Dunod.2003.2 vols.in-8,couv.souples illustrées.1: Calcul propositionnel algèbre de Boole,calcul des prédicats.385 p. 2: Fonctions récursives,théorème de Godel, théorie des ensembles,théorie des modèles.347 p. TBE.
35654Paris. Librairie Vuibert. 1923. In-8. Br. Nbrs figs. mathématiques. 102 p. Très bon état intérieur. Rousseurs sur la couv. et tache d'encre.
184846603Berlin Haude et Spener 1848-52. 4to. No wrappers as extracted from "Mémoires de l'Academie Royale des Sciences et Belles-Lettres" tome II 1846 tome IV tome VI a. tome VI. Pp. 182-224 pp. 249-291 pp. 361- 378 pp. 413-416 and 1 folded engraved plate. <br/><br/><em>First apperance of d'Alembert's 3 importent papers on the Calculus of Integration a branch of mathematical science which is greatly indepted to him. He here gives the proof of THE FUNDAMENTAL THEOREM OF ALGEBRA called d'Alembert's theorem and later corrected by Gauss 1799.The theorem is based on these three assumptions:Every polynomial with real coefficients which is of odd order has a real root. This is a corollary of the intermediate value theorem. Every second order polynomial with complex coefficients has two complex roots. For every polynomial p with real coefficients there exists a field E in which the polynomial may be factored into linear terms.Also with an importent paper by Leonhard Euler "Mémoire sur l'Effet de la Propagation successive de la Lumiere dans l'Apparition tant des Planetes que des Cometes" Memoir on the effect of the successive propogation of light in the appeareance of both comets and planets. Pp. 141-181 and 2 folded engraved plates. - The paper is founded on Euler's theory of light as waves and not as particles. It is from the same year as his fundamental work on light as waves: "Nova Theoria" - Enestroem E 104. </em> unknown
5641Deux tomes en deux volumes in 8 brochés,couverture d’attente,étiquette de titre imprimée.Tome 1:faux-titre, titre,XII,480 pages, non rogné.Tome 2:faux-titre titre 418 pages non rogné, Charles Pougen Paris Berger Levrault Strasbourg 1799 vieux style (an VII) édition originale Très bon état à très grandes marges
2 volumes [6]-510 pages + [4]-428 pages, 32 planches demi chagrin havane, dos à nerfs 1876, 1876, in-8, 2 volumes [6]-510 pages + [4]-428 pages, 32 planches, demi chagrin havane, dos à nerfs, Rare édition des Oeuvres complètes du célèbre géomètre du XVIIe siècle Desargues procurée par l'historien et spécialiste de l'histoire des mathématiques, Noël Germinal Poudra (1794-1894). Relié in fine : POUDRA et HOSSARD, Question de probabilité résolue par la géométrie. Paris, J. Corréard, 1859. [4]-23 pages, une planche Exemplaire provenant de la bibliothèque de la Faculté catholique de Paris, avec cachet annulé ; et étiquette de la librairie de Henri Vieillard, dont sa veuve, Mme Vieillard, fit don à l'Institut Catholique en 1902. Légères épidermures au dos
199473610Berlin/New York, Springer (Universitext), 1994. VIII, 118 S. Paperback / kartonierte Ausgabe
35371Paris. Albert Blanchard. 1971. In-8. Br. 58 p. TBE.
1979100133734Springer 1979 969 pages 14 86x21 41x1 85cm. 1979. Broché. 2 volume(s). 969 pages.
105953Paris, Berger-Levrault & Cie Editeurs, rue des Beaux-Arts, 5, sans date [1907], 1 volume in-8 de 225x145 mm environ, viii-301 pages, 1f. (table des matières), demi-reliure à coisn en veauu havane, signée Jaquet-Lyon, dos à nerfs portant titres dorés sur pièce de titre rouge, orné de petits fleurons dorés aux entrenerfs, cuir souligné d'un double filet doré sur les plats, gardes marbrées, tête dorée, couvertures conservées. Petits frottements, légères épidermures et quelques rousseurs sur le cuir, intérieur bon état.
175042900Petropoli St. Petersbourg 1750. 4to. Uncut without wrappers. Extracted from "Novi Commentarii Academiae Scientiarum Imperialis Petropolitanae" Tom. I. ad Annum 1747 et 1748. Pp. 3-19 a. 1 engraved plate. and pp. 20-48. <br/><br/><em>First printing of both papers. The second is important as it contains Euler'is second proof of the Euler-Fermat theorem which Euler presents as a consequence of the theorem that abp = apbp mod p. This paper also includes results about possible divisors of a2n b2n and Euler uses this to show again that F5 is not prime. - Enestroem No. 133 a. 134. </em> unknown
177041596Berlin Haude et Spener 1770. 4to. No wrappers as issued in "Mémoires de l'Academie Royale des Sciences et Belles-Lettres" Tome V pp. 203-221 1 plate and pp. 222-288 1 engraved plate. <br/><br/><em>Both papers first edition. The first paper is Euler's discussion of "Cramers Paradox" and it contains his inventions of 2 kinds of curves "Cusps of first kind" or keratoid cusp and "Cups of second kind" or ramphoid cusp. - Enestroem E 169.The second paper contains Euler's famous proof of "The fundamental Theorem of Algebra". - Enestroem E 170. </em> unknown