Quadric surfaces are important objects in Multivariable Calculus and Vector Analysis classes. We like them because they are natural 3D-extensions of the so-called conics (ellipses, parabolas, and hyperbolas), and they provide examples of fairly nice surfaces to use as examples.
The basic quadric surfaces are described by the following equations, where A, B, and C are constants.
It can be tough to memorize what the graph of each equation is. A better approach is to use cross sections to figure out what surface a given equation represents.
About this Gallery -- read before you go on.
Sometimes a computer can graph a surface in more than one way. Look at the two pictures below; they both show graphs of the function . The picture on the left is probably more familiar, and it's what most of us would (attempt to) draw by hand. The picture on the right can be useful, though, because the gridlines on the surface show you the cross sections x=c and y=c of the surface.
In technical terms, the two pictures show graphs of the same function but with different domains. On the left the domain is a disk, described by
On the right, the domain is a square,
In this gallery I've drawn a lot of surfaces with square domains to emphasize the vertical cross sections. I've also included buttons below certain pictures that let you change the domain to a disk. You might be surprised how different some of the pictures look when you change the domain.
In fact, that leads to a good way to gauge how well you understand the quadric surfaces. On each page you'll be able to adjust the coefficients of the equation. Do this with both domains, and see if you can tell that it affects both graphs in the same way.
Go to the next page to open the Gallery of Quadric Surfaces