I would like to take the inverse of a nxn matrix to use in my GraphSlam.
The issues that I encountered:
.inverse()Eigen-library (3.1.2) doesn't allow zero values, returns
- The LAPACK (3.4.2) library doesn't allow to use a zero determinant, but allows zero values (used example code from Computing the inverse of a matrix using lapack in C)
- Seldon library (5.1.2) wouldn't compile for some reason
Did anyone successfully implemented an n x n matrix inversion code that allows negative, zero-values and a determinant of zero? Any good library (C++) recommendations?
I try to calculate the omega in the following for GraphSlam: http://www.acastano.com/others/udacity/cs_373_autonomous_car.html
[ 1 -1 0 0 ] [ -1 2 -1 0 ] [ 0 -1 1 0 ] [ 0 0 0 0 ]
Real example would be 170x170 and contain 0's, negative values, bigger positive values. Given simple example is used to debug the code.
I can calculate this in matlab (Moore-Penrose pseudoinverse) but for some reason I'm not able to program this in C++.
A = [1 -1 0 0; -1 2 -1 0; 0 -1 1 0; 0 0 0 0] B = pinv(A) B= [0.56 -0.12 -0.44 0] [-0.12 0.22 -0.11 0] [-0.44 -0.11 0.56 0] [0 0 0 0]
For my application I can (temporarily) remove the dimension with zero's.
So I am going to remove the 4th column and the 4th row.
I can also do that for my 170x170 matrix, the 4x4 was just an example.
[ 1 -1 0 ] [ -1 2 -1 ] [ 0 -1 1 ]
So removing the 4th column and the 4th row wouldn’t bring a zero determinant.
But I can still have a zero determinant if my matrix is as above.
This when the sum of each row or each column is zero. (Which I will have all the time in GraphSlam)
The LAPACK-solution (Moore-Penrose Inverse based) worked if the determinant was not zero (used example code from Computing the inverse of a matrix using lapack in C).
But failed as a "pseudoinverse" with a determinant of zero.
SOLUTION: (all credits to Frank Reininghaus), using SVD(singular value decomposition)
- Zero values (even full 0 rows and full 0 columns)
- Negative values
- Determinant of zero
[0.56 -0.12 -0.44] [-0.12 0.22 -0.11] [-0.44 -0.11 0.56]