Often the volume integral is represented in terms of a differential volume element
.
It can also mean a triple integral within a region
of a function
and is usually written as:
A volume integral in cylindrical coordinates is
and a volume integral in spherical coordinates (using the ISO convention for angles with
as the azimuth and
measured from the polar axis (see more on conventions)) has the form
The triple integral can be transformed from Cartesian coordinates to any arbitrary coordinate system using the Jacobian matrix and determinant. Suppose we have a transformation of coordinates from
. We can represent the integral as the following.
Where we define the Jacobian determinant to be.

Integrating the equation
over a unit cube yields the following result:

So the volume of the unit cube is 1 as expected. This is rather trivial however, and a volume integral is far more powerful. For instance if we have a scalar density function on the unit cube then the volume integral will give the total mass of the cube. For example for density function:
the total mass of the cube is:
