1.5: Polar, Cylindrical, and Spherical Coordinates

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Page ID: 191899

Kenn Huber
Irvine Valley College

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Learning Objectives

Convert between rectangular and polar coordinates in \(\mathbb{R}^2\).
Convert between cylindrical and rectangular coordinates in \(\mathbb{R}^3\).
Convert between spherical and rectangular coordinates in \(\mathbb{R}^3\).
Convert between cylindrical and spherical coordinates in \(\mathbb{R}^3\).

The Cartesian coordinate system provides a straightforward way to describe the location of points in space. Some surfaces, however, can be difficult to model with equations based on the Cartesian system. This is a familiar problem; recall that in two dimensions, polar coordinates often provide a useful alternative system for describing the location of a point in the plane, particularly in cases involving circles. In this section, we refresh on polar coordinates in two dimensions and then look at two different ways of describing the location of points in three dimensional space based on extensions of polar coordinates.

As the name suggests, cylindrical coordinates are useful for dealing with problems involving cylinders, such as calculating the volume of a round water tank or the amount of oil flowing through a pipe. Similarly, spherical coordinates are useful for dealing with problems involving spheres, such as finding the volume of domed structures.

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