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1994BN187453Wiley-VCH Verlag GmbH 1994. 1994. Hardcover. Partial Differential Equations: Models in Physics and Biology Mathematical Research Band 82 <br/><br/>Partial Differential Equations: Models in Physics and Biology Mathematical Research Band 82 Belgian-French Meeting on Partial Differential Equations 1993 Han-sur Wiley-VCH Verlag GmbH hardcover
1980x-0824769961Marcel Dekker Inc 1980. Paperback. New. 1st edition. 504 pages. 10.00x7.25x1.00 inches. Marcel Dekker Inc paperback
2003x-9812381724World Scientific Pub Co Inc 2003. Hardcover. New. 344 pages. 9.00x6.00x0.75 inches. World Scientific Pub Co Inc hardcover
20022-0824707923Marcel Dekker Inc 2002. Paperback. New. 474 pages. 9.75x6.75x1.00 inches. Marcel Dekker Inc paperback
0243468563.Gpaperback. Good. Access codes and supplements are not guaranteed with used items. May be an ex-library book. paperback
1334652589.Gpaperback. Good. Access codes and supplements are not guaranteed with used items. May be an ex-library book. paperback
1999x-905699669XG & B Science Pub 1999. Hardcover. New. 1st edition. 363 pages. 9.00x6.00x1.00 inches. G & B Science Pub hardcover
176946556Berlin Haude et Spener 1769. 4to. Without wrappers as issued in "Mémoires de l'Academie Royale des Sciences et Belles-Lettres" Année 1767 Tome XXXIII pp. 311-352. <br/><br/><em>First edition of a monumental paper in the theory of equations by "one of the greatest mathematicians of all times" Cajori. In this memoir which deals with the solutiuon of numerical equations Lagrange examines the roots of algebraic equations and provides methods of separating the real and imaginary roots and of approximating the real roots with continued fractions.Parkinson "Breakthroughs" 1767 P. </em> unknown
177644968Paris Imprimerie Royale 1776. 4to. Extracts from "Mémoires de Mathematique et de Physique Présentés à l'Academie des Sciences par divers Savans" Année 1773. Pp. 305-327. Clean and fine. <br/><br/><em>First printing of Monge's second paper on the theory of partial differential equations.In this memoir Monge continued his investigations in "a field of study that was to hold his interest for many years: the theory of partial differential equations. In particular he undertook the parallel examination of certain equations of this type and of the families of corresponding surfaces. The geometric construction of a particular solution of the equations under consideration allowed him to determine the general nature of the arbitrary function involved in the solutions of a partial differential equation. Moreover this finding enabled him to take a position on a question then being disputed by d Alembert Euler and Daniel Bernoulli."DSB. </em> unknown
182149138Paris Crochard 1821. No wrappers. In 'Annales de Chimie et de Physique' Volume 19 Cahier 3. Pp. 225-236 Entire issue offered with halftitle to vol. 19. Navier's paper: pp. 244-260. A few scattered brownspots. Some browning to halftitlepage. <br/><br/><em>First appearance of Navier's famous paper in which he describes the relations between fluid flow and friction giving the FUNDAMENTAL EQUATIONS OF THE MATHEMATICAL THEORY OF ELASTICITY. The full paper was not published until 1828. Stokes's analysis of the internal friction of fluids was published in 1845 and as he was not familiar with the French litterature of mathematical physics he derived independently his own equations which accounts for the double-name of the equations. "The Navier-Stokes equation is now regarded as the universal basis of fluid mechanics no matter how complex and unpredictable the behavior of its solutions may be. It is also known to be the only hydrodynamic equation that is compatible with the isotropy and linearity of the stress-strain relation." Olivier Darrigol."Navier studied the motion of solid and liquid bodies deriving the partial differential equations to which he applied Fourier's methods to find particular solutions. This theoretical research led him to formulate the well-known equation identified with his name and that of Stokes. Navier viewed bodies as made up of particles which are close to each other and which act on each other by means of two opposing forces - one of attraction and one of repulsion - which when in a state of equilibrium cancel each otherout. The repelling force resulted from the caloric that a body possessed. When equilibrium is disturbed in a solid a restoring force acts which is proportional to the change in distance between the particles."DSB X p. 4."The equations are useful because they describe the physics of many things of academic and economic interest. They may be used to model the weather ocean currents water flow in a pipe and air flow around a wing. The Navier-Stokes equations in their full and simplified forms help with the design of aircraft and cars the study of blood flow the design of power stations the analysis of pollution and many other things. Coupled with Maxwell's equations they can be used to model and study magnetohydrodynamics. "Wikipedia. </em> unknown
182147074Paris Crochard 1821. Contemp. hcalf. Spine gilt with tome-and titlelabels with gilt lettering. Wear to top of spine. A crack along first hinge but cover not loose. In 'Annales de Chimie et de Physique' Volume 19. Entire volume offered. 448 pp. a. 2 plates. Navier's paper: pp. 244-260. A faint dampstain to margins of the first 20 leaves and a bit seen on the following pages decreasing. <br/><br/><em>First appearance of Navier's famous paper in which he describes the relations between fluid flow and friction giving the FUNDAMENTAL EQUATIONS OF THE MATHEMATICAL THEORY OF ELASTICITY. The full paper was not published until 1828. Stokes's analysis of the internal friction of fluids was published in 1845 and as he was not familiar with the French litterature of mathematical physics he derived independently his own equations which accounts for the double-name of the equations. "The Navier-Stokes equation is now regarded as the universal basis of fluid mechanics no matter how complex and unpredictable the behavior of its solutions may be. It is also known to be the only hydrodynamic equation that is compatible with the isotropy and linearity of the stress-strain relation." Olivier Darrigol."Navier studied the motion of solid and liquid bodies deriving the partial differential equations to which he applied Fourier's methods to find particular solutions. This theoretical research led him to formulate the well-known equation identified with his name and that of Stokes. Navier viewed bodies as made up of particles which are close to each other and which act on each other by means of two opposing forces - one of attraction and one of repulsion - which when in a state of equilibrium cancel each otherout. The repelling force resulted from the caloric that a body possessed. When equilibrium is disturbed in a solid a restoring force acts which is proportional to the change in distance between the particles."DSB X p. 4."The equations are useful because they describe the physics of many things of academic and economic interest. They may be used to model the weather ocean currents water flow in a pipe and air flow around a wing. The Navier-Stokes equations in their full and simplified forms help with the design of aircraft and cars the study of blood flow the design of power stations the analysis of pollution and many other things. Coupled with Maxwell's equations they can be used to model and study magnetohydrodynamics. "Wikipedia. </em> unknown
182143864Paris Crochard 1821. Without wrappers. In 'Annales de Chimie et de Physique' Volume 19 Cahier 3. Titlepage to vol. 19. Pp. 225-335. Navier's paper: pp. 244-260. Verso of titlepage with small stamps. Clean and fine. <br/><br/><em>First appearance of Navier's famous paper in which he describes the relations between fluid flow and friction giving the FUNDAMENTAL EQUATIONS OF THE MATHEMATICAL THEORY OF ELASTICITY. The full paper was not published until 1828. Stokes's analysis of the internal friction of fluids was published in 1845 and as he was not familiar with the French litterature of mathematical physics he derived independently his own equations which accounts for the double-name ofthe equations. "The Navier-Stokes equation is now regarded as the universal basis of fluid mechanics no matter how complex and unpredictable the behavior of its solutions may be. It is also known to be the only hydrodynamic equation that is compatible with the isotropy and linearity of the stress-strain relation." Olivier Darrigol."Navier studied the motion of solid and liquid bodies deriving the partial differential equations to which he applied Fourier's methods to find particular solutions. This theoretical research led him to formulate the well-known equation identified with his name and that of Stokes. Navier viewed bodies as made up of particles which are close to each other and which act on each other by means of two opposing forces - one of attraction and one of repulsion - which when in a state of equilibrium cancel each otherout. The repelling force resulted from the caloric that a body possessed. When equilibrium is disturbed in a solid a restoring force acts which is proportional to the change in distance between the particles."DSB X p. 4."The equations are useful because they describe the physics of many things of academic and economic interest. They may be used to model the weather ocean currents water flow in a pipe and air flow around a wing. The Navier-Stokes equations in their full and simplified forms help with the design of aircraft and cars the study of blood flow the design of power stations the analysis of pollution and many other things. Coupled with Maxwell's equations they can be used to model and study magnetohydrodynamics. "Wikipedia. </em> unknown
19659444-nnew. unknown
19659444like new. unknown
0470054565-GUsed - Good. A Good Used Book has a good binding with some shelf wear. May have minimal notes or highlighting. A Good Used Book has a good binding with some shelf wear. May have minimal notes or highlighting. unknown
0470054565-VGUsed - Very Good. Very Good Condition! Crisp copy with a sturdy binding and light shelf wear. May have minimal notes or highlighting. Very Good Condition! Crisp copy with a sturdy binding and light shelf wear. May have minimal notes or highlighting. unknown
183441606Berlin G. Reimer 1834 4to. No wrappers. Extracted from "Journal für die reine und angewandte Mathematik. Hrsg. von A.L. Crelle" Bd.12. - Plücker's paper pp. 105-108. <br/><br/><em>First printing of the paper containing the famous "Plücker Equations". ".one of Plücker's great achievements published in Crelle's Journal for 1834 was the discovery of four equations bearing his name the paper offered that relate the class and order of a curve with the singularities of the curve." Boyer. History of Mathematics. </em> unknown
1981HVD-25173-A-0Prentice-Hall Inc. Good. 1981. Hardcover. Prentice-Hall Series In Computational Mathematics; Ex-Library copy with usual identifiers. - Good overall condition. General wear. No major blemishes. No writing. ; - We're committed to your satisfaction. We offer free returns and respond promptly to all inquiries. Your item will be carefully wrapped in bubble wrap and securely boxed. All orders ship on the same or next business day. Buy with confidence. . Prentice-Hall, Inc. hardcover
20012-0824706722Marcel Dekker Inc 2001. Paperback. New. 308 pages. 10.00x6.75x0.75 inches. Marcel Dekker Inc paperback
2001__0824706722Marcel Dekker Inc 2001. Paperback. New. 308 pages. 10.00x6.75x0.75 inches. Marcel Dekker Inc paperback