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I follow the formula on wiki:


to compute pseudoinverse but i can not receive the right result. for example: I want to find theta of the equation: Y=R*theta, i write on matlab:

R = -[1/sqrt(2) 1 1/sqrt(2) 0;0 1/sqrt(2) 1 1/sqrt(2);-1/sqrt(2) 0 1/sqrt(2) 1];
% R is 3x4 matrix

Y = [0; -1/sqrt(2);-1]; %Y is 3x1 matrix

B1 = pinv(R);
theta1 = B1*Y;
result1 = R*theta1 - Y

B2 = R'*inv(R*R');
theta2 = B2*Y;
result2 = R*theta2 - Y

and this is the result:

   result1 =
   1.0e-15 *
Warning: Matrix is close to singular or badly scaled.
Results may be inaccurate. RCOND =  1.904842e-17. 
> In pseudoinverse at 14 
result2 =

Cleary, theta2 is the wrong answer, but i don't know how and why. I read many book and they give me the same formula as wiki. Can anybody help me to do pseudo inverse by hand ? thanks !

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I think you mean "theta1 is the wrong answer" as you have it written. –  horchler May 24 '13 at 19:08
It's theta2. theta1 right because result1~0, and theta2 wrong because result2 <>0 –  kerry_13 May 24 '13 at 19:22
It's not theta2. You have no variable called theta2. What you call theta2 is named theta1 in your script. I'm just trying to carify your question for others. I can't edit your question to change just one character -you need to do that. –  horchler May 24 '13 at 19:34
yeah, I see it, thanks ^^ –  kerry_13 May 26 '13 at 14:02

3 Answers 3

The algebra tells you that a pseudo-inverse can be used to solve such equations, but the algebra isn't accounting for finite precision computation.

In fact computation of a pseudo-inverse using the matrix multiplication method is not suitable because it is numerically unstable. Use the \ operator for matrix division, as in

theta = R \ Y;

Algebraically, matrix division is the same as multiplication by pseudo-inverse. But MATLAB's implementation is far more stable.

For more information, including stable methods, see

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thanks for answer, but in my problem, pinv() show the right answer, and formula B1 = R'*inv(R*R'); is wrong. I want to know how the pinv implement. And I try theta = R \ B; matlab give a error ??? Error using ==> mldivide Matrix dimensions must agree. –  kerry_13 May 24 '13 at 19:08
@kerry_13: See the link I provided. It's unclear why you hasn't already seen that, since it is linked several times from the page you linked in your answer. –  Ben Voigt May 24 '13 at 19:10
Sorry about the typo. You're using B for the pseudo-inverse, I'm accustomed to systems of equations described by Ax = b and then the solution is x = A \ b; –  Ben Voigt May 24 '13 at 19:11
type edit pinv in the Matlab command window. You'll see that the function is based on the svd function (singular value decomposition) -just as is indicated in the Wikipedia link from @BenVoigt. –  horchler May 24 '13 at 19:12

As Ben has already said, matrix inversion is numerically unstable. The function inv is not recommended unless you want to have the actual inversion of a matrix, see for example this link. The misuse of inv is the mistake a new student of numerical linear algebra most often makes.

In most linear algebra computations, you can circumvent inv by using a numerically-stable algorithm. For example, we have LU factorization for linear solvers, and QR or SVD method for ordinary least squares.

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You're not calculating B1 correctly. In your case

B1 = inv(R'*R)*R';

Because R is leading (traditionally it is the other way around). However, that doesn't solve your singularity problem.

pinv used SVD to calculate the pseudo-inverse, which you can read about here.

So basically it does in a more elegant fashion:

[U,S,V] = svd(R);
S(abs(S)<(sum(sum(S))*1e-8)) = 0; % removes near-singular values.
Stemp = 1./S;
Stemp(isinf(Stemp)) = 0; % This take the inverse of non-zero terms... I'm sure there is faster way
B1 = V * Stemp' * U';

And then you can continue on your way...

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