%% -*- latex -*- %/* \input ../macros/Header \if\Book0 \usepackage{epsfig} \newlabel{hill}{{4}{89}} \newlabel{master}{{4}{21}} \newlabel{implicit}{{11.2}{59}} \begin{document} \setcounter{section}{5} \setcounter{page}{95} \fi %*/ %*{{page>wiki:headers:hheader}} %* Navigate [[..:..:activities:link|back to the activity]]. %/* \Lab{The Valley} \SecMark \label{Gradient} %*/ %*==== THE VALLEY ==== %/* \subsection{Essentials} %*/ %*=== Essentials === %/* \subsubsection{Main ideas} %*/ %*== Main ideas == %/* \Goal{ %*/ %/* \begin{itemize} \itemsep=0pt \item %*/ %*

Reinforces both the Master Formula and differentials. %*
Sets the stage for path-independence. %*

%/* \end{itemize} %*/ %/* } %*/ %/* %\textbf{Don't skip this lab!} %*/ %/* \subsubsection{Prerequisites} %*/ %*== Prerequisites == %/* \Req{ %*/ %/* \begin{itemize} \itemsep=0pt \item %*/ %*

Some familiarity with differentials. %*
Familiarity with the gradient. %*

%/* \end{itemize} %*/ %/* } %*/ %/* \subsubsection{Warmup} %*/ %*== Warmup == A brief derivation of the master formula from the expression for the differential of a function of two variables. %/* \subsubsection{Props} %*/ %*== Props == %/* \begin{itemize} \itemsep=0pt \item %*/ %*

whiteboards and pens %*
valley transparency %/* (master on page \pageref{valleymaster}) %*/ %*(master available %*{{private:bridge:activities:content:guides:valley.pdf|here}}) %*
blank transparencies and pens %/* %*

%/* \end{itemize} %*/ %/* \subsubsection{Wrapup} %*/ %*== Wrapup == %/* \begin{itemize} \itemsep=0pt \item %*/ %*

Call someone from each group to the board to draw both their path and $d\rr$ on the topo map and show how they found $d\rr$. Discuss the different methods used by different groups. The idea here is that %/* \textit{\bfseries on a curve} %*/ %*//**on a curve**// $dy$ is related to $dx$. Students are being asked to find this relationship, and plug it into the general expression for $d\rr$. %/* \hfill\break \null\quad %*/ %*\\\\ %/* \textit{``Use what you know! Any (algebraically correct) method will work.''} %*/ %*//"Use what you know! Any (algebraically correct) method will work."// %*
Emphasize that $\grad h$ is a property of the hill, while $d\rr$ is a property of the curve. The point of the master formula is that it naturally separates the information in $dh$ into these quite different geometric ideas. %*
Have the class discuss why the answer to the second integral is in fact easy to find without integration. %*

%/* \end{itemize} %*/ %/* \newpage %*/ %/* \subsection{Details} %*/ %*=== Details === %/* \subsubsection{In the Classroom} %*/ %*== In the Classroom == %/* \begin{itemize} \item %*/ %*

This lab is on the long side; don't plan to do %/* \textit{anything} %*/ %*//anything// else in a 50-minute period. The wrapup alone easily requires 20 minutes to do properly; you may wish to do part of it in a subsequent class period. %*
Some students may not realize that $(1,1)$ is on the given circle! %*
Ask the students if their level curves are equally spaced. %/* \hfill\break %*/ %*\\\\ (They shouldn't be.) %*
Initially assign each group one of the curves; groups which finish quickly can try other curves. The first curve, the circle, is qualitatively different from the others, and more difficult; see %/* Section~\ref{implicit}. %*/ %*Section 11.2. Furthermore, the instructions do not uniquely determine the curve in this case --- although the final answer is unaffected. You may wish to assign this curve to a strong group, or not let any group try the circle until they have first done one of the other curves. %*
Some students substitute the given point into the height function before computing the gradient! Perhaps asking for a sketch of $\grad h$ at several points rather than just one would discourage this. %*
Ensure that students reduce to one variable before integrating. %*
Emphasize that one can plug in the relationship between $x$ and $y$ either before or after computing the differential of $h$. Which choice is easiest depends on the circumstances; both will work. %*
In the next-to-last question, groups may need to be reminded that they need to plug in information about their curve in order to find $dh$. They should use the expression for the differential of $h$ as a function of either one or two variables, rather than the master formula (which should not be used until the last question). %*
Some students will realize that the integrals must be the same because of the master formula before ever trying to compute the second integral. Such students should be praised --- but still encouraged to compute the second integral without using the master formula. %*
On the circle, some students go from $x^2+y^2=a^2$ directly to %/* ``$d\rr=2x\,dx\,\ii+2y\,dy\,\jj$''! %/* %*"$d\rr=2x\,dx\,\ii+2y\,dy\,\jj$"! One way to push students away from this mistake is to emphasize that one %/* \textit{always} %*/ %*//always// has $d\rr = dx\,\ii+dy\,\jj$ (or a similar expression in other coordinate systems). We literally stomp our feet when insisting that students start problems involving $d\rr$ by writing down one of these expressions! A discussion of this point works well as part of the wrapup. %*
See the discussion of using transparencies for %/* Group Activity~\ref{hill}. %*/ %*[[private:bridge:activities:guides:hill|the hill activity]] %*
Emphasize that $\DS\Lint$ is a definite integral, and that $\DS\Lint 0\,dx=0$ (not 1). %*

%/* \end{itemize} %*/ %/* \subsubsection{Subsidiary ideas} %*/ %*== Subsidiary ideas == %/* \Sub{ %*/ %/* \begin{itemize} \item %*/ %*

The gradient is perpendicular to level curves. %*
Emphasize that $df=\Partial{f}{x}\,dx+\Partial{f}{y}\,dy$ is a coordinate-dependent expression for $df$, whereas writing $df=\grad f\cdot d\rr$ is coordinate independent. %*

%/* \end{itemize} %*/ %/* } %*/ %/* \subsubsection{Homework} %*/ %*== Homework == %/* \HW{ %*/ %/* \begin{enumerate} \item %*/ %*

Consider the valley in this group activity, whose height $h$ in meters is given by $h={~x^2\over10}+{~y^2\over10}$, with $x$ and $y$ (and 10!) in meters. Suppose you are hiking through this valley on a trail given by \begin{eqnarray*} x=3t \qquad y=2t^2 \end{eqnarray*} with $t$ in seconds (and where %/* ``3'' and ``2'' %*/ %*"3" and "2" have appropriate units). %/* \begin{enumerate} \item %*/ %*
1. Starting from the master formula, determine how fast you are climbing (rate of change of $h$) %/* {\it per meter\/} %*/ %*//per meter// along the trail when $t=1$. %/* \hfill\break {/it %*/ %*// You may find it helpful to recall that $ds=|d\rr|$. %*// %/* } %*/ %*
2. Starting from the master formula, determine how fast you are climbing %/* {\it per second\/} %*/ %*//per second// when $t=1$. %*

%/* \end{enumerate}\end{enumerate} %*/ %/* } %*/ %/* \subsubsection{Essay questions} %*/ %*== Essay questions == %/* \Essay{ %*/ %/* \begin{itemize} \item %*/ %*

During this activity, you drew a gradient vector on a topographic map. Can you draw this vector to scale? Explain. %*
What properties of your path are needed to compute the integrals in this activity? To determine the answer? %*

%/* \end{itemize} %*/ %/* } %*/ %/* \subsubsection{Enrichment} %*/ %*== Enrichment == %/* \Rich{ %*/ %/* \begin{itemize} \item %*/ %*

Discuss the relationship between the master formula, the gradient, topographic maps, and path-independence. %*
Discuss the fundamental theorem for gradients, namely that the line integral of a gradient is just an obvious antiderivative. Relate this to the geometry, especially the existence of a topo map. %*
Many students will integrate the two pieces of $dh=2x\,dx+2y\,dy$ separately, without worrying about the path. What path is implicitly being used? %*
We strongly discourage students from inserting artificial signs into expressions such as $d\rr = dx\,\ii + dy\,\jj$. This forces $dy<0$, and in some cases also $dx<0$, so that one must integrate from $1$ to $0$. By all means discuss the alternative convention with students, which requires $dx$ and $dy$ to always be positive, and then forces one to insert (and keep track of) appropriate signs by hand. %*
Following this lab is a good time to introduce or review the proof, using the master formula, that the gradient is perpendicular to level curves and that it points in the direction of maximal increase. %*
A great followup to this activity is a discussion of what questions you can answer using the master formula. %*
It is immediately obvious in polar coordinates that these integrals do not depend on $\phi$, and hence are independent of path. %*

%/* \end{itemize} %*/ %/* } %*/ %/* \newpage \thispagestyle{empty} \begin{figure} \epsfxsize=6.5in \centerline{\epsffile[61 151 523 613]{valley.ps}} \label{valleymaster} \end{figure} %*/ %/* \input ../macros/footer %*/