Presentation is loading. Please wait.

Presentation is loading. Please wait.

Augustin Louis Cauchy (1789-1857) Laplace and Lagrange were visitors at the Cauchy family In1805 he took the entrance examination for the École Polytechnique.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Augustin Louis Cauchy (1789-1857) Laplace and Lagrange were visitors at the Cauchy family In1805 he took the entrance examination for the École Polytechnique."— Presentation transcript:

1 Augustin Louis Cauchy (1789-1857) Laplace and Lagrange were visitors at the Cauchy family In1805 he took the entrance examination for the École Polytechnique. He was examined by Biota and placed second. At the École Polytechnique his analysis tutor was Ampère. In 1807 he graduated from the École Polytechnique and entered the engineering school École des Ponts et Chaussées. In 1810 Cauchy took up his first job in Cherbourg to work on port facilities for Napoleon's English invasion fleet In 1816 he won the Grand Prix of the French Academy of Science for a work on waves. He achieved real fame however when he submitted a paper to the Institute solving one of Fermat's claims on polygonal numbers made to Marlene. 1817 lectured on methods of integration at the Collège de France. His text Cours d'analyse in 1821 was designed for students at École Polytechnique and was concerned with developing the basic theorems of the calculus as rigorously as possible. In 1831 Cauchy went to Turin and after some time there he accepted an offer from the King of Piedmont of a chair of theoretical physics. In 1833 Cauchy went from Turin to Prague in order to follow Charles X and to tutor his grandson. Met with Bolzano. Cauchy returned to Paris in 1838 and regained his position at the Academy Numerous terms in mathematics bear Cauchy's name:- the Cauchy integral theorem, in the theory of complex functions, the Cauchy-Kovalevskaya existence theorem for the solution of partial differential equations, the Cauchy-Riemann equations and Cauchy sequences. He produced 789 mathematics papers,

2 Augustin Louis Cauchy (1789-1857) Lectures on the Infinitesimal Calculus. First Lesson: Introduces the notions of limits and defines infinitesimals in terms of limits. An infinitesimal variable is considered to be a sequence whose limit is zero. Second Lesson: Definition of continuity f(x+i)-f(x) is infinitesimal Third Lesson: Definition of derivative: Twenty-First Lesson: Definition of integration –Partition [x 0,X] into [x 0,x 1 ], …,[x n-1,X] –Sum: S= (x 1 -x 0 )f(x 0 )+(x 2 -x 1 )f(x 1 )+ … + (X-x n-1 )f(x n-1 ) –Take the limit with more and more intermediate values. Fixing  x=h=dx rewrite S=  h f(x)=  f(x)  x which becomes in the limit. The notation for the bounds is due to Fourier. The additivity propriety of the integral with respect to the domain is also given.

3 Augustin Louis Cauchy (1789-1857) Lectures on the Infinitesimal Calculus. Twenty-Sixth Lesson: Indefinite integrals are defined and using the Intermediate Value Theorem for Integrals, it is shown that F (x) is continuous. Moreover F (x) is differentiable and F (x)’(x)=f(x). This is a version of the Fundamental Theorem. Applications: –Q.: Solve  ’(x)=0! A.:  (x)=c. –Q.: Solve y’=f(x)! A.: with  ’(x)=0 or y=∫f(x)dx=F(x)+  (x), where F(x) a particular solution. –Set F (x)= then F (x)=F(X)-F(x 0 ) for any particular solution F of F’(x)=f(x)

4 Further Developments Bernhard Riemann (1826 -1866) improved Cauchy’s definition by using the sums S= (x 1 -x 0 )f(c 0 )+(x 2 -x 1 )f(c 1 )+ … + (X-x n-1 )f(c n-1 ) with x i ≤c i ≤x i+1. which are now called Riemann sums. With this definition it is possible to integrate more functions. Henri Léon Lebesgue (1875-1941) found a new way to define integrals, with which it is possible to integrate even more functions. For this one uses so- called simple functions as an approximation and measures their contribution by what is called a Lebesgue mesure. This is technically more difficult and outside the scope of usual calculus classes. It is however the integral of choice and is used e.g. in quantum mechanics. The Lebesgue integral can for instance be used to integrate the function f(x) defined by Dirichlet which is given by f(x)=1 if x is irrational and f(x)=0 if x is rational. The answer is 1. Notice that the limit of the Riemann sums does not exist, however.

Download ppt "Augustin Louis Cauchy (1789-1857) Laplace and Lagrange were visitors at the Cauchy family In1805 he took the entrance examination for the École Polytechnique."

Similar presentations

The Natural Logarithmic Function

The Natural Logarithmic Function
Boyce/DiPrima 9th ed, Ch 2.8: The Existence and Uniqueness Theorem Elementary Differential Equations and Boundary Value Problems, 9th edition, by William.

Boyce/DiPrima 9th ed, Ch 2.8: The Existence and Uniqueness Theorem Elementary Differential Equations and Boundary Value Problems, 9th edition, by William.
1 Week 4 Complex numbers: analytic functions 1. Differentiation of complex functions 2. Cauchy’s Integral Theorem.

1 Week 4 Complex numbers: analytic functions 1. Differentiation of complex functions 2. Cauchy’s Integral Theorem.
A Soulwinning Mathematician

A Soulwinning Mathematician
中華大學 資訊工程系 Fall 2002 Chap 5 Fourier Series. Page 2 Fourier Analysis Fourier Series Fourier Series Fourier Integral Fourier Integral Discrete Fourier Transform.

中華大學 資訊工程系 Fall 2002 Chap 5 Fourier Series. Page 2 Fourier Analysis Fourier Series Fourier Series Fourier Integral Fourier Integral Discrete Fourier Transform.
MULTIPLE INTEGRALS 16. 2 MULTIPLE INTEGRALS Recall that it is usually difficult to evaluate single integrals directly from the definition of an integral.

MULTIPLE INTEGRALS MULTIPLE INTEGRALS Recall that it is usually difficult to evaluate single integrals directly from the definition of an integral.
CHAPTER 4 THE DEFINITE INTEGRAL.

CHAPTER 4 THE DEFINITE INTEGRAL.
Evariste Galois (1811-1832) 1827 developed interest for mathematics 1828 failed the entrance exam to the Ecole Polytechnique, but continues to work on.

Evariste Galois ( ) 1827 developed interest for mathematics 1828 failed the entrance exam to the Ecole Polytechnique, but continues to work on.
Lesson 5 Method of Weighted Residuals. Classical Solution Technique The fundamental problem in calculus of variations is to obtain a function f(x) such.

Lesson 5 Method of Weighted Residuals. Classical Solution Technique The fundamental problem in calculus of variations is to obtain a function f(x) such.
1 Chapter 9 Differential Equations: Classical Methods A differential equation (DE) may be defined as an equation involving one or more derivatives of an.

1 Chapter 9 Differential Equations: Classical Methods A differential equation (DE) may be defined as an equation involving one or more derivatives of an.
Nathan Carter Senior Seminar Project Spring 2012.

Nathan Carter Senior Seminar Project Spring 2012.
3.7 Graphs of Rational Functions

3.7 Graphs of Rational Functions
Augustin-Louis Cauchy and Derivatives.  Warm-Up.

Augustin-Louis Cauchy and Derivatives.  Warm-Up.
Logarithmic, Exponential, and Other Transcendental Functions Copyright © Cengage Learning. All rights reserved.

Logarithmic, Exponential, and Other Transcendental Functions Copyright © Cengage Learning. All rights reserved.
Integration. Antiderivatives and Indefinite Integration.

Integration. Antiderivatives and Indefinite Integration.
David M. Bressoud Macalester College, St. Paul, Minnesota AP National Conference, Houston, TX July 17, 2005.

David M. Bressoud Macalester College, St. Paul, Minnesota AP National Conference, Houston, TX July 17, 2005.
Calculus Mrs. Dougherty’s Class. drivers Start your engines.

Calculus Mrs. Dougherty’s Class. drivers Start your engines.
AP CALCULUS PERIODIC REVIEW. 1: Limits and Continuity A function y = f(x) is continuous at x = a if: i) f(a) is defined (it exists) ii) iii) Otherwise,

AP CALCULUS PERIODIC REVIEW. 1: Limits and Continuity A function y = f(x) is continuous at x = a if: i) f(a) is defined (it exists) ii) iii) Otherwise,
6.1 Antiderivatives and Slope Fields Objectives SWBAT: 1)construct antiderivatives using the fundamental theorem of calculus 2)solve initial value problems.

6.1 Antiderivatives and Slope Fields Objectives SWBAT: 1)construct antiderivatives using the fundamental theorem of calculus 2)solve initial value problems.
Academy Algebra II/Trig 5.5: The Real Zeros of a Polynomial Functions HW: p.387 (14, 27, 30, 31, 37, 38, 46, 51)

Academy Algebra II/Trig 5.5: The Real Zeros of a Polynomial Functions HW: p.387 (14, 27, 30, 31, 37, 38, 46, 51)

Similar presentations

Ads by Google