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This is what I need to do-

I have this equation-

Ax = y

Where A is a rational m*n matrix (m<=n), and x and y are vectors of the right size. I know A and y, I don't know what x is equal to. I also know that there is no x where Ax equals exactly y. I want to find the vector x' such that Ax' is as close as possible to y. Meaning that (Ax' - y) is as close as possible to (0,0,0,...0).

I know that I need to use either the lstsq function:

or the svd function:

I don't understand the documentation at all. Can someone please show me how to use these functions to solve my problem.

Thanks a lot!!!

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3 Answers 3

up vote 0 down vote accepted

SVD is for the case of m < n, because you don't really have enough degrees of freedom.

The docs for lstsq don't look very helpful. I believe that's least square fitting, for the case where m > n.

If m < n, you'll want SVD.

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For a discussion of the SVD from a computing perspective, take a look at section 2.6 of the numerical recipes book ( – TwentyMiles May 16 '09 at 18:13

The updated documentation may be a bit more helpful... looks like you want

numpy.linalg.lstsq(A, y)
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Yeah, it looks like x = numpy.linalg.lstsq(A, y) will solve your problem (and based on the return values it appears to solve the least-squares problem by using the SVD). Beware that for m <= n, you are likely to suffer from overfitting, that is, you have enough degrees of freedom to fit y exactly, but only because your model is too flexible and is fitting the noise in addition to the underlying signal. – las3rjock May 16 '09 at 14:15

The SVD of matrix A gives you orthogonal matrices U and V and diagonal matrix Σ such that

A = U Σ V T

where U UT = I ; V VT = I

Hence, if

x A = y


x U Σ V T = y

x U Σ V T V = y V

x U Σ = y V

U T x Σ = y V

x Σ = U y V

x = Σ -1 U T y V

x = V T Σ -1 U T y

So given SVD of A you can get x.

Although for general matrices A B != B A, it is true for vector x that x U == U T x.

For example, consider x = ( x, y ), U = ( a, b ; c, d ):

x U = ( x, y ) ( a, b ; c, d )

= ( xa+yc, xb+yd )

= ( ax+cy, bx+dy )

= ( a, c; b, d ) ( x; y )

= U T x

It's fairly obvious when you look at the values in x U being the dot products of x and the columns of U, and the values in UTx being the dot products of the x and the rows of UT, and the relation of rows and columns in transposition

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In general matrix multiplication is not commutative, so in general xA != Ax. – las3rjock May 16 '09 at 13:58

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