I have a linear subspace `S = [v1 v2 v3 v4] = [1 1 1 2]t`

where t is some scalar real number.

I want to do a transformation on S based on the following: `[v1 v2 v3 v4] = [A 2A*B 3*C 10]`

What is the quickest way for me to define a new subspace `T = [A B C]`

that is a transformation of S with the aforementioned rules?

In this example, the value of `T`

is `T = [A B C] = [1 0 1/3]t + [0 1/2 0]`

. I get this by finding A, B, and C in terms of v1, v2, v3, and v4 in the transformation rules above. `A = v1`

and `B = v2/(2A) = v2/(2*v1)`

and `C = v3/3`

. Then, I substitute in for the values I find for v1, v2, and v3 in S above. In this case, `A = 1t`

, and `B = (1/2)*(v2/v1) = 1/2`

and `C = (1/3)t`

.

I would like to determine this programmatically in Python. I can't really pursue the change-of-basis transformation (http://en.wikipedia.org/wiki/Change_of_basis) because the transformation is not strictly linear.

However, I can guarantee that the transformation only will include scalars and the variables A, B, and C taken to the first power.

Edit: I would prefer that the solution *not* involve a symbolic math toolkit.

Edit2: Along with the simplest way to pursue this, I would also like a solution that can be practically extended to large arrays (1000s of components).

`eq`

, it seems as if`v1`

to`v5`

are scalars. But based on the rest of the question, it seems as if they are 5-element vectors? – phant0m Aug 28 '12 at 21:26`T`

were 4-dimensional (`[A B C D]`

) and you had`v1 = A*B`

,`v2 = C*D`

,`v3 = 1`

, and`v4 = 6`

? That would raise a couple of complications: there's no way to separate A from B or C from D, and`v3 = 1`

implies`t = 1`

, but`v4 = 6`

implies`t = 3`

. Are there restrictions that keep those from happening? – David Sep 1 '12 at 0:32