First of all, his code is a projection onto a 3D space, but the question is about a rotation on the Z axis which is the same as a 2D rotation and the Z value is kept the same.
When you have any given point (x,y) you form a right triangle. Take a look at this picture:
a is 15 degrees
That circle is called a unit-circle and it's radius is
- The length of the green line along the Y axis is the
sine of the angle.
- The length of the green line along the X axis is the
cosine of the angle.
Note that it doesn't really matter the size of the triangle formed by the point's coordinates. As long as it keeps the same angle, the value of the sine and cosine will remain the same as only the section of the triangle within the unit circle matters here.
sine is how much a point should move in the Y axis, and the
cosine is how much to move in the X axis in order for a point to move in space and keep the same angle as a minimum step (their values range from 0 to 1 which is the circle's radius)
But how do you go about moving a point in space in order to change it's angle to the origin?
Well, firstly, for any point intersecting the unit circle, meaning the hypotenuse of it's triangle is 1, it's position is
(cosine, sine), for a point outside the unit circle, for example
(2,5), it's position is
(hypotenuse * cosine, hypotenuse * sine)
Imagine we have a point
a degrees from the origin and we want to rotate it by
b degrees, this means we want a new position
(x',y') where the angle is changed to
a+b degrees but the distance from the origin (the hypotenuse) is kept the same.
x = hypotenuse * cosine(a)
y = hypotenuse * sine(a)
x' = hypotenuse * cosine(a + b)
y' = hypotenuse * sine(a + b)
By using the trigonometric angle adition formulas we have that
cosine(a + b) = cosine(a) * cosine(b) - sine(a) * sine(b)
sine(a + b) = sine(a) * cosine(b) + cosine(a) * sine(b)
If we apply that to our
(x',y') we get:
x' = hypotenuse * cosine(a) * cosine(b) - hypotenuse * sine(a) * sine(b)
y' = hypotenuse * sine(a) * cosine(b) + hypotenuse * cosine(a) * sine(b)
If you remember our definition for
(x,y) you notice that this is the exact same as:
x' = x * cosine(b) - y * sine(b)
y' = y * cosine(b) + x * sine(b)
And there is your mysterious formula right there on our
y', only the order of the addition is reversed.