**The Problem**

How would one interpolate between two given angles, given a certain time delta, so that the simulated motion from rotation A or rotation B would take a similar amount of time when the algorithm is ran at different frequencies (without a fixed time step dependency).

**Potential Solution**

I have been using the following C# code to do this kind of interpolation between two points. It solves the differential for the situation:

```
Vector3 SmoothLerpVector3(Vector3 x0, Vector3 y0, Vector3 yt, double t, float k)
{
// x0 = current position
// y0 = last target position
// yt = current target position
// t = time delta between last and current target positions
// k = damping
Vector3 value = x0;
if (t > 0)
{
Vector3 f = x0 - y0 + (yt - y0) / (k * (float)t);
value = yt - (yt - y0) / (k * (float)t) + f * (float)Math.Exp(-k * t);
}
return value;
}
```

This code is usable for 2D coordinates by having the `Z`

coordinate of the `Vector3`

set as 0.

The "last" and "current" positions are because the target can move during the interpolation. Not taking this in to account causes motion jitter at moderately high speeds.

I did not write this code and it appears to work. I had trouble altering this for angles because, for example, an interpolation between the angles 350° and 10° would take the 'long' way round instead of going in the direction of the 20° difference in angle.

I've looked into quaternion slerp but haven't been able to find an implementation that takes a time delta into account. Something that I have thought of, but not been able to implement either, is to interpolate between both angles twice, but the second time with a phase difference of 180° on each angle and to output the smaller of the two multiplied by -1.

Would appreciate any help or direction!