After some rearranging you can get the "nice" forms

```
(1) 1/2 z^2 = (alpha) / ( y^2 - x^2) + 1
(2) 1/2 y^2 = (beta) / ( z^2 - x^2) + 1
(3) 1/2 x^2 = (gamma) / ( y^2 - z^2) + 1
```

where `alpha = sx^2-sy^2`

, `beta = sx^2 - sz^2`

and `gamma = sz^2 - sy^2`

. Verify this yourself.

Now I neither have the motivation nor the time but from this point on its pretty straightforward to solve:

Substitute (1) into (2). Rearrange (2) until you get a polynomial (root) equation of the form

```
(4) a(x) * y^4 + b(x) * y^2 + c(x) = 0
```

this can be solved using the quadratic formula for `y^2`

. Note that `a(x),b(x),c(x)`

are some functions of `x`

. The quadratic formula yields 2 roots for (4) which you will have to keep in mind.

Using (1),(2),(4) figure out an expression for `z^2`

in terms of only `x^2`

.

Using (3) write out a polynomial root equation of the form:

```
(5) a * x^4 + b * x^2 + c = 0
```

where `a,b,c`

are not functions but constants. Solve this using the quadratic formula. In total you will have 2*2=4 possible solutions for `x^2,y^2,z^2`

pair meaning you will
have 4*2=8 total solutions for possible `x,y,z`

pairs satisfying these equations. Check conditions on each `x,y,z`

pair and (hopefully) eliminate all but one (otherwise an inverse mapping does not exist.)

Good luck.

PS. It very well may be that the inverse mapping does not exist, think about the geometry: the sphere has surface area `4*pi*r^2`

while the cube has surface area `6*d^2=6*(2r)^2=24r^2`

so intuitively you have many more points on the cube that get mapped to the sphere. This means a many to one mapping, and any such mapping is not injective and hence is not bijective (i.e. the mapping has no inverse.) Sorry but I think you are out of luck.

----- edit --------------

if you follow the advice from MO, setting `z=1`

means you are looking at the solid square in the plane `z=1`

.

Use your first two equations to solve for x,y, wolfram alpha gives the result:

```
x = (sqrt(6) s^2 sqrt(1/2 (sqrt((2 s^2-2 t^2-3)^2-24 t^2)+2 s^2-2 t^2-3)+3)-sqrt(6) t^2 sqrt(1/2 (sqrt((2 s^2-2 t^2-3)^2-24 t^2)+2 s^2-2 t^2-3)+3)-sqrt(3/2) sqrt((2 s^2-2 t^2-3)^2-24 t^2) sqrt(1/2 (sqrt((2 s^2-2 t^2-3)^2-24 t^2)+2 s^2-2 t^2-3)+3)+3 sqrt(3/2) sqrt(1/2 (sqrt((2 s^2-2 t^2-3)^2-24 t^2)+2 s^2-2 t^2-3)+3))/(6 s)
```

and

```
y = sqrt(-sqrt((2 s^2-2 t^2-3)^2-24 t^2)-2 s^2+2 t^2+3)/sqrt(2)
```

where above I use `s=sx`

and `t=sy`

, and I will use `u=sz`

. Then you can use the third equation you have for `u=sz`

. That is lets say that you want to map the top part of the sphere to the cube. Then for any `0 <= s,t <= 1`

(where `s,t`

are in the sphere's coordinate frame ) then the tuple `(s,t,u)`

maps to `(x,y,1)`

(here `x,y`

are in the cubes coordinate frame.) The only thing left is for you to figure out what `u`

is. You can figure this out by using `s,t`

to solve for `x,y`

then using `x,y`

to solve for `u`

.

Note that this will only map the top part of the cube to **only** the top plane of the cube `z=1`

. You will have to do this for all 6 sides (`x=1`

, `y=1`

, `z=0`

... etc ). I suggest using wolfram alpha to solve the resulting equations you get for each sub-case, because they will be as ugly or uglier as those above.