% Implicit Differentiation % MATH266A Exercise \documentclass[12pt]{article} \usepackage{times} %%%\pagestyle{empty} \pagestyle{myheadings}%%% \markright{MATH266A \hfill Implicit Differentiation\hfill} \thispagestyle{empty} \addtolength{\textwidth}{1.2in} \addtolength{\textheight}{1.2in} \addtolength{\oddsidemargin}{-.58in} \addtolength{\evensidemargin}{-.58in} \renewcommand{\baselinestretch}{1.0} \parindent = 0cm \parskip = .1cm \begin{document} \begin{center} {\Large Implicit Differentiation \footnote{Copyright \copyright 2002 Winfried Just, Department of Mathematics, Ohio University. All rights reserved.}} \end{center} \bigskip In this exercise, we will graphically explore the idea behind implicit differentiation. If this \textsc{MatLab} exercise is being counted in your grade, then be sure to print the figures for submission. %%%%You may be asked to submit your pictures for this exercise as part of Quiz 4. Let us use the \verb$ ezplot$ command to draw the graph of the equation \begin{equation}\label{circle} x^2 + y^2 = 25 \end{equation} You do this by entering: \smallskip \verb$>> ezplot('x^2 + y^2 = 25', [-6, 6], [-6, 6])$ \smallskip Look at your picture. It doesn't look like a circle, does it? You can improve its look by entering: \smallskip \verb$>> axis square$ \smallskip Clearly, the graph you see is not the graph of a function. However, let us see what happens if we zoom in on a neighborhood of the point $(3,4)$. Enter: \smallskip \verb$>> axis([1 5 2 6])$ \smallskip As you can see, the graph now looks pretty much like the graph of a function. In class we found the equation of the tangent line to the graph of this function. It is: \begin{equation}\label{tangentcircle} y = -{3 \over 4}(x - 3) + 4 \end{equation} Equivalently, this equation can be written as: \begin{equation}\label{tangentcircle1} -{3 \over 4}(x - 3) + 4 - y = 0 \end{equation} Let us plot the tangent line on the same graph. Enter: \smallskip \verb$>> hold on$ \verb$>> ezplot('-(3/4)*(x-3) + 4 - y = 0', [-6, 6], [-6, 6])$ \smallskip You should see a nice tangent line to the graph of a function. Let us zoom out again to see how the tangent line is related to the whole graph of equation~(\ref{circle}). Enter: \smallskip \verb$>> axis([-6 6 -6 6])$ \smallskip Now give a descriptive title to your picture and print it if submission is required. \medskip It is not the case that for \emph{all} points $(x_0,y_0)$ on the graph of equation~(\ref{circle}) the equation defines a function $y(x)$ in a neighborhood of $(x_0, y_0)$. Please mark on your printout all points $(x_0, y_0)$ where equation~(\ref{circle}) \emph{does not} define such a function. \medskip Now let us explore the equation:\nopagebreak \begin{equation}\label{descartes} x^3 + y^3 = 4.5xy \end{equation} To clean your graphics window, enter: \smallskip \verb$>> hold off$ \smallskip Now enter: \smallskip \verb$>> ezplot('x^3 + y^3 - 4.5*x*y = 0', [-2, 4], [-2, 4])$ \smallskip The shape you see in the picture is called the "folium of Descartes." The whole figure clearly is not the graph of a function. To see what happens in a neighborhood of the point $(1,2)$, enter: \smallskip \verb$>> axis([0.5 1.5 1.5 2.5])$ \smallskip Again, you can see the graph of a function. In the handout, we computed the equation of the tangent line to the graph of this function at $(1,2)$. It is: \begin{equation}\label{tangentdescartes} y = {6 \over 7.5}(x-1) + 2 \end{equation} \smallskip Add the graph of this tangent line to the picture by entering: \smallskip \verb$>> hold on$ \verb$>> ezplot('(6/7.5)*(x-1) + 2 - y = 0', [-2, 4], [-2, 4])$ \smallskip Now zoom out again to look at the whole picture. Enter: \smallskip \verb$>> axis([-2 4 -2 4])$ \smallskip Add a suitable title to your picture and print it if submission is required. \end{document}