In the general case, it's not possible to do what you're asking. You're asking to go from 7 degrees of freedom down to 4 but keep the same result. The representative power of the lower DOF system can't match that of the higher. The only time it would be possible is if the more complex curve still happened to lie in the simpler space. For example, if your two Bezier curves came from sub-dividing a single parent curve with points `R0, R1, R2, R3`

. Using the de Casteljau algorithm, we can generate two new curves, `P`

and `Q`

, that lie on the same original curve and share a point that is `t`

distance along the original curve (where `t`

is in `[0,1]`

).

```
P0 = R0
P1 = R0*(1-t) + R1*t
X = R1*(1-t) + R2*t
P2 = P1*(1-t) + X*t
Q3 = R3
Q2 = R2*(1-t) + R3*t
Q1 = X*(1-t) + Q2*t
Q0 = P3 = P2*(1-t) + Q1*t
```

If that relationship doesn't hold for your original points, then you'll have to craft an approximation. But you might get away with pretending that the relationship holds and just invert the equations:

```
R1 = (P1 - P0*(1-t))/t
R2 = (Q2 - Q3*t)/(1-t)
```

Where

```
t = (Q0 - P2)/(Q1 - P2)
```

This last equation is the problem because, unless `P2, Q0, Q1`

are co-linear it won't work exactly. `t`

is a scalar, but `Q1-P2`

is normally an n-dimensional point. So you can solve it separately for each dimension and find the average, or be a bit more sophisticated and minimize the squared error.