# How to reduce the number of independent variables in mathematica

I am not srue whether this is really a mathematical question, or actually a mathematica question. :D

suppose I have a matrix

{{4/13 + (9 w11)/13 + (6 w12)/13,
6/13 + (9 w21)/13 + (6 w22)/13}, {-(6/13) + (6 w11)/13 + (4 w12)/
13, -(9/13) + (6 w21)/13 + (4 w22)/13}}


with w11, w12, w21, w22 as free parameters.

And I know by visual inspection that 3*w11+2*w12 can be represented as one variable, and 3*w21+2*w22 can be represented as another. So essentially this matrix only has two independent variables. Given any matrix of this form, is there any method to automatically reduce the number of independent variables? I guess I am stuck at formulating this in a precise mathematical way.

Edit:

My question is really the following. Given matrix like this

{{4/13 + (9 w11)/13 + (6 w12)/13,
6/13 + (9 w21)/13 + (6 w22)/13}, {-(6/13) + (6 w11)/13 + (4 w12)/
13, -(9/13) + (6 w21)/13 + (4 w22)/13}}


or involving some other symbolical constants

{{a+4/13 + (9 w11)/13 + (6 w12)/13,
6/13*c + (9 w21)/13 + (6 w22)/13}, {-(6/13)/d + (6 w11)/13 + (4 w12)/
13, -(9/13) + (6 w21)/13 + (4 w22)/13}}


I want to use mathematica to automatically identify the number n of independent variables (in this case is 2), and then name these independent varirables y1, y2, ..., yn, and then re-write the matrix in terms of y1, y2, ..., yn instead of w11, w12, w21, w22.

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Without trying to be purist, you need equations to solve for variables. You only have some sums there. – Dr. belisarius Feb 15 '11 at 20:56

Starting with

mat = {{4/13 + (9 w11)/13 + (6 w12)/13,6/13 + (9 w21)/13 + (6 w22)/13},
{-(6/13) + (6 w11)/13 + (4 w12)/13, -(9/13) + (6 w21)/13 + (4 w22)/13}};


Form a second matrix, of indeterminates, same dimensions.

mat2 = Array[y, Dimensions[mat]];


Now consider the polynomial (actually linear) system formed by setting mat-mat2==0. We can eliminate the original variables and look for dependencies amongst the new ones. Could use Eliminate; I'll show with GroebnerBasis.

GroebnerBasis[Flatten[mat - mat2], Variables[mat2], Variables[mat]]


Out[59]= {-3 + 2 y[1, 2] - 3 y[2, 2], -2 + 2 y[1, 1] - 3 y[2, 1]}

So we get a pair of explicit relations between the original matrix elements.

---edit---

You can get expressions for the new variables that clearly indicates the dependency of two of them on the other two. To do this, form the Groebner basis and use it in polynomial reduction.

gb = GroebnerBasis[Flatten[mat - mat2], Variables[mat2], Variables[mat]];
vars = Flatten[mat2];

PolynomialReduce[vars, gb, vars][[All, 2]]


Out[278]= {1 + 3/2 y[2, 1], 3/2 + 3/2 y[2, 2], y[2, 1], y[2, 2]}

---end edit---

Daniel Lichtblau Wolfram Research

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+1, definitely the simplest solution. Incidentally, unlike in his previous question, CoefficientArrays does not work here as it treats each row of the matrix separately, and not as a vector of variables dotted with a vector of matrices which I've had trouble with in the past. Also, I have to look at GroebnerBasis again, as I never know when, or how, it is applicable. – rcollyer Feb 15 '11 at 21:11
@Daniel, thanks a lot. After getting this {-3 + 2 y[1, 2] - 3 y[2, 2], -2 + 2 y[1, 1] - 3 y[2, 1]}, how to use it? Does this tell me the redundant degree of freedom is 2? If so, for example, I am given two (because 4-2=2!) new variables y1, y2 and I want to re-write the original matrix {{4/13 + (9 w11)/13 + (6 w12)/13, 6/13 + (9 w21)/13 + (6 w22)/13}, {-(6/13) + (6 w11)/13 + (4 w12)/ 13, -(9/13) + (6 w21)/13 + (4 w22)/13}} in terms of y1 and y2 rather than w11, w12, w21, w22, how can this be done? – Qiang Li Feb 15 '11 at 21:22
@rcollyer: i am not sure what you meant by the "unlike in his previous question, CoefficientArrays does not work here as it treats each row of the matrix separately" comment. How CoefficientArrays can be related here? – Qiang Li Feb 15 '11 at 21:27
@Daniel, also this does not seem to work if I have another constant, for example, a, involved in the matrix, for example {-3*a + 2 y[1, 2] - 3 y[2, 2], -2 + 2 y[1, 1] - 3 y[2, 1]}, as now, Variables[mat] changes to {a,w11, w12, w21, w22}. Thanks. – Qiang Li Feb 15 '11 at 21:34
@Qiang Li You will need to edit your question so I can see specifically how you bring the new variable into the matrix. What you show has it in the Groebner basis, but I do not know the input you used. – Daniel Lichtblau Feb 15 '11 at 21:49