You could take a non-linear optimisation approach, by defining a "cost" function that incorporates the distance error from each of your observation points.

Setting the unknown point at `(x,y,z)`

, and considering a set of `N`

observation points `(xi,yi,zi,di)`

the following function could be used to characterise the total distance error:

```
C(x,y,z) = sum( ((x-xi)^2 + (y-yi)^2 + (z-zi)^2 - di^2)^2 )
^^^
^^^ for all observation points i = 1 to N
```

This is the sum of the squared distance errors for all points in the set. (It's actually based on the error in the squared distance, so that there are no square roots!)

When this function is at a minimum the target point `(x,y,z)`

would be at an optimal position. If the solution gives `C(x,y,z) = 0`

all observations would be exactly satisfied.

One apporach to minimise this type of equation would be Newton's method. You'd have to provide an initial starting point for the iteration - possibly a mean value of the observation points (if they en-circle `(x,y,z)`

) or possibly an initial triangulated value from any three observations.

Edit: Newton's method is an iterative algorithm that can be used for optimisation. A simple version would work along these lines:

```
H(X(k)) * dX = G(X(k)); // solve a system of linear equations for the
// increment dX in the solution vector X
X(k+1) = X(k) - dX; // update the solution vector by dX
```

The `G(X(k))`

denotes the gradient vector evaluated at `X(k)`

, in this case:

```
G(X(k)) = [dC/dx
dC/dy
dC/dz]
```

The `H(X(k))`

denotes the Hessian matrix evaluated at `X(k)`

, in this case the symmetric 3x3 matrix:

```
H(X(k)) = [d^2C/dx^2 d^2C/dxdy d^2C/dxdz
d^2C/dydx d^2C/dy^2 d^2C/dydz
d^2C/dzdx d^2C/dzdy d^2C/dz^2]
```

You should be able to differentiate the cost function analytically, and therefore end up with analytical expressions for `G,H`

.

Another approach - if you don't like derivatives - is to approximate `G,H`

numerically using finite differences.

Hope this helps.