Which version of spherical coordinates is correct?

In summary, there are two versions of spherical coordinates, one using (rho, θ, ∅) and the other using (r, ∅, θ). The difference lies in the symbols used for the angles, which can lead to confusion and should be checked when using spherical coordinates. The international standard is to use θ for colatitude and φ for longitude.
  • #1
hivesaeed4
217
0
∅θ,θI've come across two distinct 'versions' of the spherical coordinates. Could someone tell me which is correct or if both are fine.

Version 1:

A spherical coordinate is (rho,θ,∅)

x=rhocos(θ)sin(∅) ; y=rhosin(θ)sin(∅) ; z=rhocos(θ)

Version 2:

A spherical coordinate is (r,∅,θ)

x=rhocos(∅)sin(θ) ; y=rhosin(θ)sin(∅) ; z=rhocos(θ)
(r could be rho as well)

Now what's the difference between both or which is the false one?
 
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  • #2
Isn't it just a matter of symbols used for coordinates? Symbols don't matter, it is the idea that matters - and the idea is identical in both cases.
 
  • #3
This wiki page mentions the different conventions:
http://en.wikipedia.org/wiki/Spherical_coordinate_system

The symbols θ, φ represent the angles for colatitude (angle from the positive z-axis) and longitude.
But depending on the source the symbols are swapped around.

In particular there appears to be a difference between US math books and US physics books.
The "rest of the world" mostly appears to follow the same convention as used in US physics books.

There is an international standard ISO 31-11, that says to use θ for colatitude and φ for longitude (US physics convention).
The coordinates are listed as (r,θ,φ), making it a right-handed coordinate system.In practice it means that whenever you're dealing with spherical coordinates you have to check how the symbols are defined.
 
Last edited:
  • #4
Thanks Guys.
 
  • #5
hivesaeed4 said:
∅θ,θI've come across two distinct 'versions' of the spherical coordinates. Could someone tell me which is correct or if both are fine.

Version 1:

A spherical coordinate is (rho,θ,∅)

x=rhocos(θ)sin(∅) ; y=rhosin(θ)sin(∅) ; z=rhocos(θ)

Version 2:

A spherical coordinate is (r,∅,θ)

x=rhocos(∅)sin(θ) ; y=rhosin(θ)sin(∅) ; z=rhocos(θ)
(r could be rho as well)

Now what's the difference between both or which is the false one?

The first one looks wrong. z=rcos(θ) means x and y both must have sin(θ) as part of their definition. x=rsin(θ)cos(z) y=rsin(θ)sin(z).
 
  • #6
x=rcos(a)sin(b)
y=rsin(a)sin(b)
z=rcos(b)

You have to make sure that the first variable in x and y are the same, and that the second in x and y is also used in z. It also depends on which side the angle is on that you are using. My physics teacher said to remember that "cos" is the side that is "cozy" with the angle.
 

1. What are spherical coordinates?

Spherical coordinates are a coordinate system used to locate points in three-dimensional space. They use three values - radius, inclination angle, and azimuth angle - to describe the position of a point in relation to a fixed origin.

2. How are spherical coordinates different from Cartesian coordinates?

Spherical coordinates use a different set of parameters to describe a point's position compared to Cartesian coordinates. While Cartesian coordinates use three values - x, y, and z - to describe a point's position in relation to a fixed origin, spherical coordinates use radius, inclination angle, and azimuth angle.

3. What is the range of values for spherical coordinates?

The radius value in spherical coordinates can range from 0 to infinity, the inclination angle ranges from 0 to 180 degrees, and the azimuth angle ranges from 0 to 360 degrees.

4. How are spherical coordinates used in real-world applications?

Spherical coordinates are commonly used in physics, astronomy, and engineering to describe the position of objects in three-dimensional space. They are also useful for navigation and mapping systems.

5. Can spherical coordinates be converted to other coordinate systems?

Yes, spherical coordinates can be converted to other coordinate systems such as Cartesian coordinates or cylindrical coordinates using a set of equations. This allows for easier use of spherical coordinates in different applications.

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