So you've got a measure of distance from where the object started along its internal sideways axis and a measure of the angle between that axis and the horizontal?

If so then the formula you want is simple trigonometry. Assuming the object started at (x, y) and has travelled 'distance' units along an axis at an angle of 'angle' with the horizontal then the current position (x', y') is:

```
x' = x + distance * cos(angle)
y' = y + distance * sin(angle)
```

If you have the origin in the lower left of the screen and axes arranged graph paper style with x increasing to the right and y increasing as you go upward, that assumes that the angle is measured anticlockwise and that the object is heading along positive x when angle is zero.

If you'll permit a hand waving explanation, the formula works because one definition of sine and cosine is that they're the (x, y) coordinates of the point on the outside of a unit circle at the angle specified. It also matches with the very first thing most people learn about trigonometry, that sine is 'opposite over hypotenuse', and cosine is 'adjacent over hypotenuse'. In this case your hypotenuse has length 'distance' and and you want to get the 'opposite' and 'adjacent' lengths of a right angled triangle that coincides with the axes.

Assuming Android follows J2SE in this area, the one thing to watch out for is that `Math.sin`

and `Math.cos`

take an angle in radians, whereas OpenGL's `rotatef`

takes an argument in degrees. `Math.toDegrees`

and `Math.toRadians`

can do the conversion for you.