I have six parametric equations using 18 (not actually 26) different variables, 6 of which are unknown.

I could sit down with a couple of pads of paper and work out what the equations for each of the unknowns are, but is there a simple programatic solution (I'm thinking in Matlab) that will spit out the six equations I'm looking for?

**EDIT:**
Shame this has been closed, but I guess I can see why. In case anyone is still interested, the equations are (I believe) non-linear:

```
r11^2 = (l_x1*s_x + m_x)^2 + (l_y1*s_y + m_y)^2
r12^2 = (l_x2*s_x + m_x)^2 + (l_y2*s_y + m_y)^2
r13^2 = (l_x3*s_x + m_x)^2 + (l_y3*s_y + m_y)^2
r21^2 = (l_x1*s_x + m_x - t_x)^2 + (l_y1*s_y + m_y - t_y)^2
r22^2 = (l_x2*s_x + m_x - t_x)^2 + (l_y2*s_y + m_y - t_y)^2
r23^2 = (l_x3*s_x + m_x - t_x)^2 + (l_y3*s_y + m_y - t_y)^2
```

(Squared the `r`

s, good spot @gnovice!)

Where I need to find `t_x`

`t_y`

`m_x`

`m_y`

`s_x`

and `s_y`

Why am I calculating these? There are two points p1 (at `0,0`

) and p2 at(`t_x,t_y`

), for each of three coordinates (`l_x,l_y`

{1,2,3}) I know the distances (`r1`

& `r2`

) to that point from p1 and p2, but in a different coordinate system. The variables `s_x`

and `s_y`

define how much I'd need to scale the one set of coordinates to get to the other, and `m_x`

, `m_y`

how much I'd need to translate (with `t_x`

and `t_y`

being a way to account for rotation differences in the two systems)

Oh! And I forgot to mention, I also know that the point (`l_x,l_y`

) is below the highest of p1 and p2, ie `l_y`

< max(`0`

,`t_y`

) as well as `l_y`

> 0 and `l_y`

< `t_y`

.

It does seem specific enough that I might have to just get my pad out and work it through mathematically!