These are excerpts from a collection of graphical demonstrations I developed for first year calculus in the mid 1990s. Those interested in higher math may also want to visit my page of graphics for complex analysis. This page is on the list of the most frequently linked math pages according to MathSearch.

**Viewing instructions.**
The animations on this page use the animated GIF format. There is
also a Java version of this page. The Java
animator allows you to start and stop the animation, advance through
the frames manually, and control the speed. Also the animation is a
bit smoother, and the frames shuttle (first to last and then backward
to first, etc.), which is a bit nicer. Unfortunately, the Java versions
of the animation usually take much more time to load, and the Java
animator has been know to crash browsers, especially on machines without
much memory. An older version of this page
using the MPEG animation format is available, but no longer actively
maintained, and so not recommended.

This animation
expands upon the classic calculus diagram above. The
diagram illustrates the local accuracy of the tangent line approximation
to a smooth curve, or--otherwise stated--the closeness of the differential
of a function to the difference of function values due to a small increment of the independent variable.
(In the diagram the increment of the independent variable
is shown in green, the differential--i.e., the product of the
derivative and the increment--in red, and the difference of function values
as the red segment plus the yellow segment. The point is
that if the green segment is small, the yellow segment is
*very* small.) A problem with the diagram is that when it is
drawn large enough to be visible the increment is too large to make the
point. For example, here the yellow segment is about 30% of the green
segment. This animation overcomes that problem by showing two views of
the diagram, each changing as the increment varies. In the left view
the ``camera'' is held fixed, and so the diagram becomes very small,
while in the right view the ``camera'' zooms in so that the diagram
occupies a constant area on the screen, and the relationship between the
segment lengths can be clearly seen. Note how the yellow segment
becomes very small in the second view (while the green segment appears
to be of constant length due to the zoom). Note also that as we move in
the difference between the purple curve and the blue tangent line
becomes insignificant.

These images concern the computation of a volume by integrating cross-sectional areas. The first image reviews the basic principle. The other images treat a specific volume, that of the wedge of water formed when a cylindrical class of equal height and diameter is tipped until the water line runs through the center of the base. The pictures are frozen frames from AVS, and can only convey a rough idea of the interactive classroom presentation (which typically lasts about 30 minutes).

- The principle
- The wedge of water formed by tipping a glass
- Cross sections perpendicular to the waterline at the base
- Three different ways to slice the same volume

And now for the quiz: Compute the percentage of the glass filled by water using each of the the three slicings depicted in the last slide and verify that they all lead to the same answer.

In the third century B.C., Archimedes calculated the value of to an accuracy of one accuracy of one part in a thousand. His technique was based on inscribing and circumscribing polygons in a circle, and is very much akin to the method of lower and upper sums used to define the Riemann integral. His approach is presented in the following sequence of slides.

- Calculating the area of a circle
- Inscribed hexagon
- Triangulation
- A lower bound for the area
- Circumscribed hexagon: an upper bound for the area
- Refining the bounds with dodecagons
- Table of results

As a way to help students appreciate functions, their applications, and their graphs, I involve them in a small project to describe the functions determined by the height of a bouncing ball. Although I start by dropping a real tennis ball from one meter above ground, a better quantitative idea of the function can be obtained from a computer animation, including a meter stick and clock. The students view the animation (in slow motion, with manual frame advance, etc.) and try to construct the graph of the function. As a homework assignment they are asked to determine the function algebraically. This is a piecewise quadratic and helps the students to realize that piecewise defined functions do exist outside of calculus books.

- Animation of a bouncing ball
- Animation of the ball with a graph of its height
- Animation of the ball with a graph of its height and velocity
- the Mathematica file used to construct the animations
- the student worksheet (PostScript file)

This is a pretty straightforward animation depicting the geometric convergence of secant lines to the tangent line. The slope of the secant (which converges to the derivative) is also displayed. I use various variations on this demo during the early part of a calculus course.

- Animation of secants approaching a tangent
- The same animation with the tangent shown
- Secants passing through a point of non-differentiability
- Secants approaching a vertical tangent--another form of non-differentiability
- The Mathematica file used to construct the animations.

This animation is a version of the common demonstration that a smooth curve becomes indistinguishable from its tangent line when viewed under a sufficiently high power microscope. Students can easily demonstrate this themselves using a graphics calculator equipped with a zoom button. In this animation, we provide some extra distance queueing by showing the grid and striping the tangent line. Here is the Mathematica file used to construct the animations.

An elegant geometric proof which is well within the reach of a beginning calculus student is the proof of the fundamental trigonometric limit

The proof is based on a diagram depicting a circular sector in the unit circle together with an inscribed and a circumscribed triangle. From the fact that the sector has area exceeding that of the inscribed triangle but less than that of the circumscribed one is lead to the inequalities

The proof then follows from the "squeeze theorem."

I usually spend about 15 minutes on this proof, including lots of class participation. The diagram is built up in three steps: first the sector only, then with the inscribed triangle, and finally with both triangles. Here are some instructions for creating it in class. During the presentation I make frequent recourse to plotting software to verify the various inequalities. For example this plot, constructed from this MATLAB file, convincingly verifies the second set of inequalities.

These are some simple graphs which
are useful in a discussion of limits. The first three functions all have
limit -5 as
*x* approaches 1, emphasizing the irrelevance of the value of the
function at the limit point itself. The last function has different
left and right hand limits at 1, and so the limit does not exist. The
graphs were constructed with this MATLAB
file.

A brief graphical exploration of a continuous, nowhere differentiable function fits very well in the first semester of calculus, for example, to provide a strong counterexample to the converse of the theorem that differentiability implies continuity; or to show that it is only differentiable functions which look like straight lines under the microscope. Given good classroom graphics facilities such an exploration is easy, but it is almost hopeless without them. This plot of such a function was produced with a few lines of Matlab code following Weierstrass's classical construction. In class I zoom in on this graph several times to reveal its fractal nature. Consequently I used a very fine point spacing. On a slower machine it is preferable to use fewer points, and decrease the point spacing as you zoom in.

Students are often puzzled by the appearance of the number *e*,
which is given above (to 35 decimal places). A simple explanation of
its origin arises from the fact that *e* is the only number for
which the tangent to the graph of *y*=*e ^{x}*
through the point (0,1) has slope exactly 1. The important result
that the function

Here's a demonstration by my colleague David Sibley illustrating the computation of the volume of the region formed by two intersecting cylinders.

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Last modified July 2, 1997 by