## The problem

The cause of what your seeing is illustrated by the drawing in Levans answer. However, to understand what's going on consider what's happening when you execute the code:

If the first point `vert1`

has coordinates `(p, 0)`

the coordinates of `vert2`

will be `(p cos(α), p sin(α))`

where `α`

is the angle between the two bones (this is always possible given an appropriate coordinate transform). Adding these together using the appropriate weights `w`

and `1-w`

we get the following coordinates:

```
x = w p + (1-w) p cos(α)
y = (1-w) p sin(α)
```

The length of this vector is:

```
length^2 = x^2 + y^2
= (w p + (1-w) p cos(α))^2 + (1-w)^2 p^2 sin(α)^2
= p^2 [w^2 + 2 w (1-w) cos(α) + (1-w)^2 cos(α)^2 + (1-w)^2 sin(α)^2]
= p^2 [w^2 + (1-w)^2 + 2 w (1-w) cos(α)]
```

As an example, when `w = 1/2`

this simplifies to:

```
length^2 = p^2 (1/2 + 1/2 cos(α)) = p^2 cos(α/2)^2
```

And `length = p |cos(α/2)|`

whereas the length of the original vectors is `p`

(see graph). The length of the new vector becomes smaller, this is the shrinking effect that you perceived. The reason for this is that we are actually interpolating the two vertices along a straight line. If we want the keep the same length `p`

we actually need to interpolate along a circle around the center of the rotation. One possible approach is to renormalize the resulting vector, preserving the width at the joint.

This means we need to divide the resulting vertex coordinates by `|cos(α/2)|`

(or the more general result for arbitrary weights). This has as a side effect of course, a divide by zero whenever the angle is exactly 180° (for the same reason the width at the joint is zero with your technique).

I'm no skeletal animation expert, but it seems to me the original solution as you described it, is an approximation to work with small bone angles (where the shrinking effect is minimal).

## Alternative approaches

A different approach is to interpolate your rotations instead of your vertices. See for example the slerp wiki page and this paper.

**SLERP**

The slerp technique is similar to the technique I described above in the sense that it also preserves the width at the joint, however it interpolates directly along a circular path around the joint. The general formula is:

```
gl_Position = [sin((1-w)α)*vert1 + sin(wα)*vert2]/sin(α)
```

Given the points from above `vert1 = (p, 0)`

and `vert2 = (p cos(α), p sin(α))`

applying the SLERP formula yields `result = (x, y)`

with:

```
x = p [sin((1-w)α) + sin(wα) cos(α)]/sin(α)
y = p sin(wα) sin(α)/sin(α) = p sin(wα)
```

Calculating the cosine `cos θ`

of the angle between `vert1`

and `result`

yields:

```
cos(θ) = vert1*result/(|vert1| |result|) = vert1*result/p^2
= p^2 [sin(wα) + sin((1-w)α) cos(α)]/sin(α)/p^2
= [sin(α) cos((1-w)α) - cos(α) sin((1-w)α) + sin((1-w)α) cos(α)]/sin(α)
= cos((1-w)α)
```

The angle between `vert2`

and `result`

is:

```
cos(φ) = vert2*result/p^2
= [sin(wα) cos(α) + sin((1-w)α) cos(α)^2 + sin((1-w)α) sin(α)^2]/sin(α)
= [sin(wα) cos(α) + sin((1-w)α) cos(α)]/sin(α)
= [sin(wα) cos(α) + sin(α) cos(wα) - cos(α) sin(wα)]/sin(α)
= cos(wα)
```

This means that `θ/φ = (1-w)/w`

which expresses the fact that SLERP interpolates with constant radial velocity. When working with 3D rotation matrices we can express the rotation transforming `vert1`

into `vert2`

as `M = inverse(A)*B = transpose(A)*B`

so that we can express the rotation angle `α`

as:

```
cos(α) = (tr(M) - 1)/2 = (tr(transpose(A)*B) - 1)/2
= (A[0][0]*B[0][0] + A[0][1]*B[1][0] + A[0][2]*B[2][0] +
A[1][0]*B[0][1] + A[1][1]*B[1][1] + A[1][2]*B[2][1] +
A[2][0]*B[0][2] + A[2][1]*B[1][2] + A[2][2]*B[2][2] - 1)/2
```

**Quaternion LERP**

When working with quaternions a good approximation to the SLERP is to linearly interpolate the quaternions directly after which you renormalize the result. This gives an interpolation curve identical to the one in SLERP, however interpolation does not occur at constant radial velocity.

If you really want to avoid these problems altogether you can always split your meshes at the joint and rotate these separately.