Implicit Differentiation with Microscopes

Similar documents
From Newton s Fluxions to Virtual Microscopes

Intuitive infinitesimals in the calculus

Perceiving the Infinite and the Infinitesimal World: Unveiling and Optical Diagrams in the Construction of Mathematical Concepts

Differential and Integral Calculus in Ultrapower Fields, without the Transfer Principle of Nonstandard Analysis, or any Topological Type Structures

Principles of Real Analysis I Fall I. The Real Number System

Does Really Equal 1?

Comparative Statics. Autumn 2018

Hyperreals and a Brief Introduction to Non-Standard Analysis Math 336

September Math Course: First Order Derivative

Foundations of Analysis. Joseph L. Taylor. University of Utah

A RING HOMOMORPHISM IS ENOUGH TO GET NONSTANDARD ANALYSIS

Integral. For example, consider the curve y = f(x) between x = 0 and x = 1, with f(x) = x. We ask:

Math 1120 Calculus, section 2 Test 1

Notes on uniform convergence

Chapter 1 The Real Numbers

300-Level Math Courses

6c Lecture 14: May 14, 2014

Chapter 2: Differentiation

Multivariate calculus

10. Smooth Varieties. 82 Andreas Gathmann

Limit. Chapter Introduction

1 Adeles over Q. 1.1 Absolute values

Tues Feb Vector spaces and subspaces. Announcements: Warm-up Exercise:

! 1.1 Definitions and Terminology

Chapter 2: Differentiation

CHAPTER 4: HIGHER ORDER DERIVATIVES. Likewise, we may define the higher order derivatives. f(x, y, z) = xy 2 + e zx. y = 2xy.

(x x 0 ) 2 + (y y 0 ) 2 = ε 2, (2.11)

Section 3.1. Best Affine Approximations. Difference Equations to Differential Equations

Contents Part A Number Theory Highlights in the History of Number Theory: 1700 BC 2008

MATH CALCULUS I 4.1: Area and Distance

The Notion of Infinite Measuring Number and Its Relevance in the Intuition of Infinity

What is model theory?

NOTES ON FINITE FIELDS

Sometimes the domains X and Z will be the same, so this might be written:

On convergent power series

arxiv: v1 [math.lo] 7 Nov 2018

Math Review ECON 300: Spring 2014 Benjamin A. Jones MATH/CALCULUS REVIEW

LOOKING AT GRAPHS THROUGH INFINITESIMAL MICROSCOPES WINDOWS AND TELESCOPES

Chapter 3 Differentiation Rules

Making the grade. by Chris Sangwin. Making the grade

arxiv: v1 [math.ca] 6 May 2016

An Introduction to Non-Standard Analysis and its Applications

An Invitation to Smooth Infinitesimal Analysis

Notes on generating functions in automata theory

Metric Spaces Math 413 Honors Project

Section 7.2: One-to-One, Onto and Inverse Functions

Tvestlanka Karagyozova University of Connecticut

Solutions to odd-numbered exercises Peter J. Cameron, Introduction to Algebra, Chapter 2

Math 456: Mathematical Modeling. Tuesday, March 6th, 2018

Econ Slides from Lecture 10

Non-classical Study on the Simultaneous Rational Approximation ABSTRACT

Economics 204 Fall 2011 Problem Set 1 Suggested Solutions

We begin by considering the following three sequences:

Chapter 3a Topics in differentiation. Problems in differentiation. Problems in differentiation. LC Abueg: mathematical economics

z = f (x; y) = x 3 3x 2 y x 2 3

1 Differentiable manifolds and smooth maps

Questionnaire for CSET Mathematics subset 1

B553 Lecture 1: Calculus Review

MATH1013 Calculus I. Revision 1

The Implicit Function Theorem 1

Ca Foscari University of Venice - Department of Management - A.A Luciano Battaia. December 14, 2017

A MODEL-THEORETIC PROOF OF HILBERT S NULLSTELLENSATZ

Math 131, Lecture 20: The Chain Rule, continued

('')''* = 1- $302. It is common to include parentheses around negative numbers when they appear after an operation symbol.

Major Matrix Mathematics Education 7-12 Licensure - NEW

MATH The Derivative as a Function - Section 3.2. The derivative of f is the function. f x h f x. f x lim

Ms. York s AP Calculus AB Class Room #: Phone #: Conferences: 11:30 1:35 (A day) 8:00 9:45 (B day)

1 Introduction. 2 Solving Linear Equations. Charlotte Teacher Institute, Modular Arithmetic

Mathematics 102 Fall 1999 The formal rules of calculus The three basic rules The sum rule. The product rule. The composition rule.

TABLE OF CONTENTS POLYNOMIAL EQUATIONS AND INEQUALITIES

4 CONNECTED PROJECTIVE-PLANAR GRAPHS ARE HAMILTONIAN. Robin Thomas* Xingxing Yu**

Convex Functions and Optimization

Orthonormal Bases; Gram-Schmidt Process; QR-Decomposition

NONSTANDARD ANALYSIS AND AN APPLICATION TO THE SYMMETRIC GROUP ON NATURAL NUMBERS

Section 1: Sets and Interval Notation

A Few Questions on the Topologization of the Ring of Fermat Reals.

Preliminaries Lectures. Dr. Abdulla Eid. Department of Mathematics MATHS 101: Calculus I

Definition 5.1. A vector field v on a manifold M is map M T M such that for all x M, v(x) T x M.

Handout #6 INTRODUCTION TO ALGEBRAIC STRUCTURES: Prof. Moseley AN ALGEBRAIC FIELD

Economics 205 Exercises

1 Introduction. 2 Solving Linear Equations

CHAPTER 2: CONVEX SETS AND CONCAVE FUNCTIONS. W. Erwin Diewert January 31, 2008.

General Equilibrium and Welfare

MAT 417, Fall 2017, CRN: 1766 Real Analysis: A First Course

Chapter 11 - Sequences and Series

Perfect Numbers in ACL2

MATH 113: ELEMENTARY CALCULUS

Foundations of Mathematics MATH 220 FALL 2017 Lecture Notes

THEODORE VORONOV DIFFERENTIABLE MANIFOLDS. Fall Last updated: November 26, (Under construction.)

Non-trivial non-archimedean extension of real numbers. Abstract

MATH 2400: PRACTICE PROBLEMS FOR EXAM 1

THE EULER CHARACTERISTIC OF A LIE GROUP

WHY WORD PROBLEMS ARE HARD

The Integers. Peter J. Kahn

CHRISTENSEN ZERO SETS AND MEASURABLE CONVEX FUNCTIONS1 PAL FISCHER AND ZBIGNIEW SLODKOWSKI

MATH 1A, Complete Lecture Notes. Fedor Duzhin

MATH 102 INTRODUCTION TO MATHEMATICAL ANALYSIS. 1. Some Fundamentals

Chapter 2. Real Numbers. 1. Rational Numbers

Affine Connections: Part 2

Academic Content Standard MATHEMATICS. MA 51 Advanced Placement Calculus BC

Transcription:

Implicit Differentiation with Microscopes by Bair Jacques and enry Valérie Affiliations : Bair J. : EC - Management School, University of Liege Belgium) enry V. : EC - Management School, University of Liege Belgium) and Department of Mathematics, FUNDP, University of Namur Belgium) Address for manuscript correspondance : enry V., University of Liege, 7 Boulevard du Rectorat, B3, 4000 Liege, Belgium E-mail addresses : J.Bair@ulg.ac.be and valerie.henry@math.fundp.ac.be Phone number : +3 4 366736

Implicit differentiation with microscopes Key-words : implicit function, derivative, nonstandard analysis AMS Classification : 6A06, 6A4, 6B0, 6E35. Implicit functions are an important tool in the fundamental mathematical analysis ; this theory has a lot of concrete applications in various domains : for example, many economical reasonings work with implicit functions like in the cases of a consumer and his indifference curves or of a firm and her isoquants. The aim of this note is to give a systematic and suggestive approach to compute the successive derivatives of an implicit function which depends on one real variable. This method is intuitive : indeed, we use virtual) microscopes but, as cost price, we work with hyperreal numbers. Although Leibniz and Newton, for instance, already worked with infinitesimals, the hyperreal numbers were rigorously introduced, in 96, by A. Robinson [4], who developed the nonstandard analysis. ere, we work with a didactical and simple presentation of the nonstandard analysis [3] : we shall essentially adopt Keisler s definitions and notations. We recall that the hyperreal numbers extend the real ones with the same algebraic rules ; technically, the set *R of the hyperreal numbers is a non-archimedean ordered field in which the real line R is embedded. Moreover, *R contains at least in fact infinitely many) one infinitesimal i.e. a number ε such that its absolute value is less than every real number) which is unequal to 0 ; its reciproqual ε is infinite i.e. is a number such that its absolute value is greater than every real number) ; clearly, non-zero infinitesimals and infinite numbers are not real. A hyperreal number x which is not infinite is of course said to be finite ; in this case, there exists one and only one real number r which is infinitely close to x, i.e, such that the difference x r is an infinitesimal : r is called the standard part of x and is denoted by r =stx) ; formally, st is a ring homomorphism from the set of finite hyperreal numbers to R and its kernel is the set of infinitesimals. Moreover, every function of one or several real variables has a natural extension for hyperreal numbers, with the same definition and the same properties as these of the original one : indeed, if a real-valued function is defined by a system of formulas, its extension can be obtained by applying the same formulas to the hyperreal system ; in this article, we adopt the same notation for a real function and for its natural extension. The concept of virtual) microscope is well-known see, for example, [], [], [5]). For a point P a, b) in the hyperreal plane *R and a positive infinite hyperreal number, a microscope pointed on P and with as power magnifies the distances from P by a factor ; technically, it is a map, denoted by M P, defined on *R as follows Then, we also have M P :x, y) X, Y ) with X = x a) and Y = y b) x = a + X and y = b + Y For a real function f of two real variables x and y, we first consider, in the classical euclidean plane R,thecurveC defined by f x, y) =0

We suppose that a point P r, s) belongs to C and that f is of class C p,forp sufficiently large, in a neighbourhood of P. For more simplicity, we denote by d, d, d, d,..., the corresponding partial derivatives of f at P, i.e. d = f x r, s), d = f y r, s), d = f xx r, s), d = f xy r, s),....moreover, we assume that d 0. When we look at C through a microscope M P,where is an arbitrary positive infinite hyperreal number, we see a curve characterized by the equation f r + X,s+ Y ) =0 Taylor s Formula for f at P leads to f r, s)+d X + d [ ] Y + o =0 where a term like o [ ], for every integer k, is such that its product with k is infinitesimal. k Because f r, s) = 0, we also have [ ] d X + d Y + o =0 ) As we are only interested by the finite hyperreal numbers X and Y otherwise they could not be really observed), we suppress all the infinitesimal details by taking the standard parts of the two members in ) ; then we get d st X)+d st Y )=0 st Y )= d d st X) ) It is well-known that the coefficient m = d d is the slope of the tangent line T to C at P ; T is thus defined by the equation y s = m x r) This non-vertical line T suggests intuitively that C is, close to P, the graph of a real function g of the variable x ; more precisely, the implicit function theorem [3], p. 708) ensures the existence of a function g such that gr) =s, the domain of g is an open interval I containing r and the graph of g is a subset of C. Although g is unknown, it is possible to compute its derivatives at r. For that, we first look at the graph of g through the microscope M P ; that leads to this equality s + Y = g r + X ) so, by Taylor s Formula for g s + Y = gr)+g r) X [ ] + o 3

and thus, as above, A comparison between formulas ) and 3) leads to st Y )=g r) stx) 3) g r) = d d In order to compute g r), we must distinguish between the curve C and its tangent T. For that, we use a stronger microscope, for example with a power, and direct it to another point which is infinitely close ro P and belongs to T otherwise we see again C and T as equal). We can choose, for example, the point P r +,s+ m On the one hand, the use of the microscope M P and thus, as previously, s + m + Y = g r + + X ) = gr)+g r) ) note that point P r,s m ) could also be convenient). to the graph of g leads to + X ) + g r) + X ) [ ] + o 3 st Y )=g r) stx)+ g r) 4) On the other hand, the application of M P to the curve C gives 0 = f r + + X,s+ m + Y ) = f r, s)+d + X ) m + d + Y ) + ) ) ) ) ] [d + X +d + X m + Y m [ ] + d + Y +0 3 We easily get d st X)+d st Y )+ [ d +md + m ] d =0 5) The comparison between formulas 4) and 5) gives g r) = d d +md + m d ) = f d ) 3 where f denotes the bordered hessian associated with f at P, i.e. the determinant of the matrix 0 d d d d d d d d 4

More generally, by the principle of induction, we can compute all the derivatives of the implicit function g at r. Indeed, let k be an integer greater than and suppose that the numbers g r), g r),..., g k ) r) are well-known. Then we consider the point P k r +,s+ ) k j= g j) r) j! and we j apply the microscope M P k both on the graph of g and on the curve C. So, after some elementary k computations, we respectively obtain these two equalities and st Y )=m st X)+ gk) r) k! Then, we can deduce from these two last formulas d st X)+d st Y )+p k =0 g k) r) = k! p k d where p k can be calculated in terms of the partial derivatives of the given function f at P. For instance, we can so compute g r) = 3 f d ) 4 ) d d d d d 3 d d +3 d ) d d d ) d d ) 3 d ) 3 d ) In conclusion, we think that the use of microscopes gives a refreshing and new way to systematically compute the derivatives of infinite functions. References [] A. Antibi, J. Bair, V. enry, Une modélisation d un zoom au moyen de microscopes virtuels, Teach. Math. Comput. Sc. / 004) 39-335. [] R. Dossena, L. Magnani, Mathematics through Diagrams : Microscopes in Non-Standard and Smooth Analysis, Studies in Computational Intelligence 64 007) 93-3. [3]. J. Keisler, Elementary Calculus, Prindle, Weber & Schmidt, Boston, 976. [4] A. Robinson, Non-Standard Analysis, North olland, Amsterdam, 966. [5] D. Tall, Looking at graphs through infinitesimal microscopes, windows and telescopes, The Math. Gazette 64 980) - 46. 5

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback