derivatives, and the gradient

\\storage\academics\math\calclab

when you hit enter, you can then choose MA1024 and then choose the worksheet

Pardiff_grad_start_A16.mw

Remember to immediately save it in your own home directory. Once you've copied and saved the worksheet, read through the background on the internet and the ba ckground of the worksheet before starting the exercises.

The Maple commands for computing partial derivatives are `D`
and `diff`. The **Getting Started** worksheet has examples
of how to use these commands to compute partial derivatives.

to compute the directional derivative. However, the following computation, based on the definition, is often simpler to use.

One way to think about this that can be helpful in understanding directional derivatives is to realize that is a straight line in the plane. The plane perpendicular to the plane that contains this straight line intersects the surface in a curve whose coordinate is . The derivative of at is the rate of change of at the point moving in the direction .

Maple doesn't have a simple command for computing directional
derivatives. There is a command in the `tensor` package that
can be used, but it is a little confusing unless you know something
about tensors. Fortunately, the method described above and the method
using the gradient described below are both easy to implement in
Maple. Examples are given in the `Getting Started` worksheet.

As described in the text, the gradient has several important properties, including the following.

- The gradient can be used to compute the directional derivative
as follows.

- The gradient points in the direction of maximum increase of the value of at .
- The gradient is perpendicular to the level curve of that passes through the point .
- The gradient can be easily generalized to apply to functions of three or more variables.

Maple has a fairly simple command `grad` in the `linalg`
package (which we used for curve computations). Examples of computing
gradients, using the gradient to compute directional derivatives, and
plotting the gradient field are all in the `Getting Started`
worksheet.

Each critical point can be classified as a local maximum, local minimum, or a saddle point using the second-partials test:

If and then is a local minimum.

If and then is a local maximum.

If then is a saddle point.

If then no conclusion can be made. The examples in the Getting Started worksheet are intended to help you learn how to use Maple to simplify these tasks.

- Using the method from the
`Getting Started`worksheet, compute the directional derivative of at the point in each of the directions below. Explain your results in terms of being positive, negative or zero and what that tells about the surface at that point in the given direction. - Now, find the directional derivative at each of the points
and
in the direction in
and
. What do your results suggest about the surface at these points?
- Using the method from the
`Getting Started`worksheet, plot the gradient field and the contours of on the same plot over the intervals and . Use 30 contours, a grid and`fieldstrength=fixed`for the gradient plot. Classify each point in the previous exercise, and , using both the gradient field and the contour plot in your explanation. - Copy and paste the fieldplot from the previous exercise. Change the plotting intervals to
and
. Use a grid and
`fieldstrength=fixed`. Considering that the directional derivative is a dot product, use the method from the`Getting Started`worksheet to plot one of the vectors from exercise 1 on the same graph as the gradient field to show that it is orthogonal to the gradient vectors at the point in question.

2016-09-15