For a particle moving about in a Cartesian coordinate system (neglecting the z-axis), how can the angle of travel be computed given the x and y components of the velocity?

Before anyone says this isn't programming related, I am programming this right now, however, I don't know vector math.

For example, suppose the x and y values of the velocity are respectively 5.0 and -1.5, how would I compute the angle?

closed as off topic by Josh, Xeo, Mehrdad, Alan, farm ostrich May 18 '11 at 3:31

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  • This is definitely on-topic. Just because you don't use vectors at your job doesn't mean basic vector-math isn't highly relevant to programming. That being said, this question is a duplicate of several others. – BlueRaja - Danny Pflughoeft May 18 '11 at 16:09

In Javascript, I'd use Math.atan2(1.5, 5.0). To convert to degrees, use Math.atan2(1.5, 5.0)/(Math.PI/180). On Wikipedia: http://en.wikipedia.org/wiki/Atan2

  • I downvoted because you don't give any explanation of why atan2 should be used to calculate the angle given the x and y components of the velocity. What's the relationship between atan2 and the velocity? I will remove my downvote if you add these details to the answer. Moreover, the question does not mention Javascript. – nbro Apr 7 '18 at 19:12

You need atan2:

For any real arguments x and y not both equal to zero, atan2(y, x) is the angle in radians between the positive x-axis of a plane and the point given by the coordinates (x, y) on it.


The angle in radians from the x-axis is given by:

arctan(vy / vx);  // vx > 0

You also need to handle the case vx < 0.

If you want the bearing versus true north, then you might want:

double bearing = 90 - arctan(vy / vx) * 360 / 2 / M_PI;

The angle is the arctangent of y / x. Many languages have a 4-quadrant arctangent function in the math library that takes x and y arguments.


You have to be careful about what the angles are between. Arctangent, atan(y / x), will give you the angle relative to the positive x-axis, but make sure that's what you need.


The arc-tangent of the slope will give you what you want.

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