The basic **elliptic paraboloid** is given by the equation
$$z=Ax^2+By^2$$
where \(A\) and \(B\)have the same sign.
This is probably the simplest of all the quadric surfaces, and
it’s often the first one shown in class. It has a
distinctive “nose-cone” appearance.

This surface is called an elliptic paraboloid because the vertical cross sections are all parabolas, while the horizontal cross sections are ellipses. Occasionally we get sloppy and just refer to it simply as a paraboloid; that wouldn’t be a problem, except that it leads to confusion with the hyperbolic paraboloid.

The cross sections shown below are for the simplest possible elliptic paraboloid: $$ z = x^2 + y^2 $$ One important feature of the vertical cross sections is that the parabolas all open in the same direction. That isn’t true for hyperbolic paraboloids!

Note that in the example shown above, the horizontal cross sections are
actually *circles*, but this isn’t always the case. In fact,
whenever \(A\) and \(B\) are not equal, the paraboloid
will be wider in one direction than the other.

You can use the second picture to investigate how these coefficients affect the shape of the surface. It shows the paraboloid \(z=Ax^2+By^2\) over the square domain $$ \begin{align} -1 \leq x \leq 1 \\ -1 \leq y \leq 1 \end{align} $$ If you change the domain to a disk, you will see the portion of the paraboloid for which \(0 \leq z \leq 6\). When you change \(A\) and \(B\), the domain will change accordingly.

Here are a few things to think about:

- Each slice \(x = c\) is a parabola. If we view all of these slices as living in the same \(yz\)-plane, how do these parabolas differ? Use the first picture to figure this out, and then confirm your answer algebraically from the equation.
- In the second picture, what happens if either \(A\) or \(B\) is 0? What if they both are? Should any of these objects be called “elliptic” paraboloids?
- What would happen if the sliders included negative values for \(A\) and \(B\) and we made both \(A\) and \(B\) negative?