MRDIVIDE or the
/ operator actually solves the
xb = a linear system, as opposed to MLDIVIDE or the
\ operator which will solve the system
bx = a.
To solve a system
xb = a with a non-symmetric, non-invertible matrix
b, you can either rely on
mridivide(), which is done via factorization of
b with Gauss elimination, or
pinv(), which is done via Singular Value Decomposition, and zero-ing of the singular values below a (default) tolerance level.
Here is the difference (for the case of
mldivide): What is the difference between PINV and MLDIVIDE when I solve A*x=b?
When the system is overdetermined, both algorithms provide the
same answer. When the system is underdetermined, PINV will return the
solution x, that has the minimum norm (min NORM(x)). MLDIVIDE will
pick the solution with least number of non-zero elements.
In your example:
% solve xb = a
a = [1,2,3,4,5,6,7,8,9,1,2,3,4,5,6,7,8,9];
b = ones(25, 18);
the system is underdetermined, and the two different solutions will be:
x1 = a/b; % MRDIVIDE: sparsest solution (min L0 norm)
x2 = a*pinv(b); % PINV: minimum norm solution (min L2)
>> x1 = a/b
Warning: Rank deficient, rank = 1, tol = 2.3551e-014.
5.0000 0 0 ... 0
>> x2 = a*pinv(b)
0.2 0.2 0.2 ... 0.2
In both cases the approximation error of
xb-a is non-negligible (non-exact solution) and the same, i.e.
norm(x2*b-a) will return the same result.
What is MATLAB doing?
A great break-down of the algorithms (and checks on properties) invoked by the '\' operator, depending upon the structure of matrix
b is given in this post in scicomp.stackexchange.com. I am assuming similar options apply for the
For your example, MATLAB is most probably doing a Gaussian elimination, giving the sparsest solution amongst a infinitude (that's where the 5 comes from).
What is Python doing?
linalg.lstsq uses pseudo-inverse/SVD, as demonstrated above (that's why you get a vector of 0.2's). In effect, the following will both give you the same result as MATLAB's
from numpy import *
a = array([1,2,3,4,5,6,7,8,9,1,2,3,4,5,6,7,8,9])
b = ones((25, 18))
# xb = a: solve b.T x.T = a.T instead
x2 = linalg.lstsq(b.T, a.T)
x2 = dot(a, linalg.pinv(b))