MATLAB and LAPACK implementation of the SVD algorithm - not the same output?

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Danijel Domazet on 22 Feb 2022

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Edited: David Goodmanson on 23 Feb 2022

I am using the LAPACK C library's singular value decomposition function

LAPACKE_cgesvd()

and trying to get the same result as MATLAB's svd() function (in case of complex input).

But the outputs are not the same.

Here is one example:

in = [1+2i 2+4i 3+6i 4+8i; 
      2+3i 4+6i 6+9i 8+12i; 
      3+4i 6+8i 9+12i 12+16i;
      4+5i 8+10i 12+15i 16+20i];
[U,S,V] = svd(in);

This gives

U =
 -0.109108945117997 - 0.218217890235993i  0.909365643461770 + 0.318130360459734i  0.036386779676407 - 0.084386315028456i  0.052751601014692 + 0.033100021335301i
 -0.218217890235992 - 0.327326835353989i -0.037388878899514 - 0.059582067281587i -0.116960851562535 + 0.558535127042627i -0.249442499023482 + 0.672627129227888i
 -0.327326835353989 - 0.436435780471985i -0.117020313474447 + 0.048160693713279i -0.345516960640487 + 0.358878427669969i  0.391668855331377 - 0.533654905367364i
 -0.436435780471985 - 0.545544725589981i -0.219753961051779 - 0.050933678992021i  0.293035065226691 - 0.576080183457497i -0.205991407911317 + 0.029126130759720i
  
 S =
  50.199601592044544                   0                   0                   0
                   0   0.000000000000004                   0                   0
                   0                   0   0.000000000000000                   0
                   0                   0                   0   0.000000000000000
                   
V =
 -0.182574185835055 + 0.000000000000000i -0.749839996855303 + 0.000000000000000i  0.635929749093960 + 0.000000000000000i  0.000000000000000 + 0.000000000000000i
 -0.365148371670110 + 0.000000000000000i -0.099644835021179 - 0.055294049648946i -0.222326993896782 - 0.065198538162360i -0.274861567584794 - 0.851146943050864i
 -0.547722557505166 + 0.000000000000000i  0.582096115689033 + 0.184313498829819i  0.529113396624621 + 0.217328460541199i -0.000000000000000 + 0.000000000000001i
 -0.730296743340221 + 0.000000000000000i -0.199289670042359 - 0.110588099297891i -0.444653987793565 - 0.130397076324720i  0.137430783792397 + 0.425573471525431i  

When I run the LAPACK C code, I get:

U 
[0][0] = -0.109108955 -0.218217865i  [0][1] = +0.719114125 -0.452113479i  [0][2] = +0.022277016 +0.064515218i  [0][3] = -0.409647375 +0.215580061i  
[1][0] = -0.218217909 -0.327326864i  [1][1] = +0.084657431 -0.228100479i  [1][2] = +0.500972092 -0.310676992i  [1][3] = +0.300640881 -0.590053499i  
[2][0] = -0.327326834 -0.436435789i  [2][1] = +0.109215073 +0.273434073i  [2][2] = -0.344847411 -0.481100261i  [2][3] = +0.325270653 +0.399385184i  
[3][0] = -0.436435819 -0.545544684i  [3][1] = -0.340743810 +0.128338531i  [3][2] = +0.002677787 +0.545402348i  [3][3] = -0.279374570 -0.061697662i  
S
[0] = 50.1995964 [1] = 1.69897112e-06 [2] = 1.54533879e-07 [3] = 3.96336745e-14
Vtransposed 
[0][0] = -0.182574213 -0.000000000i  [0][1] = -0.365148425 -0.000000000i  [0][2] = -0.547722638 +0.000000028i  [0][3] = -0.730296850 -0.000000000i  
[1][0] = -0.219238073 -0.000000000i  [1][1] = +0.210008949 +0.144917369i  [1][2] = -0.626949847 -0.483057886i  [1][3] = +0.420017421 +0.289834768i  
[2][0] = -0.958436847 -0.000000000i  [2][1] = +0.021519713 -0.033149216i  [2][2] = +0.247748464 +0.110497266i  [2][3] = +0.043038044 -0.066298351i  
[3][0] = -0.000000639 -0.000000000i  [3][1] = -0.892759502 +0.054592617i  [3][2] = +0.000000003 -0.000000026i  [3][3] = +0.446379900 -0.027296286i  

U: Seems like the first U column is good! But the rest is totally different.

S: All good, if we approximate small C outputs to be zero.

Vt: Only the first element seems to be the same, the rest doesn't match to Matlab's output.

What is the reason for this?

Am I doing something wrong?

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Danijel Domazet on 22 Feb 2022

Edited: Danijel Domazet on 22 Feb 2022

Thanks for your comments.

I'm absolutely not trying to investigate extreme cases. I just generated a 4x4 matrix example having no idea the input matters so much: in_real = i*j; in_imag = i*j+j.

In fact, my real input is calculated from a sound recorded from 4 microphones, and then transfered into frequency domain using DFT transform. What goes into the SVD algo is the covariance matrix computed for the 4 frequencies from the mics, so: 4 mics audio -> DFT -> covariance -> SVD.

Covariance is computed for each frequency bit:

for bin = 1:257
    covar = DFT_output(:,bin) * DFT_output(:,bin)'
end

The input to covar is 4x1 dimension (4 mics x 1 bin), and covar output gives 4x4. That goes into SVD.

However, even with this "real world" inputs, the SVD gives different results, furthermore, the results are similar to the above: it's always that the 1st column of the U output is OK, and the rest is different.

I can provide a "real world" example if needed?

Danijel Domazet on 22 Feb 2022

Edited: Danijel Domazet on 22 Feb 2022

Let's put it this way: is there an input for which LAPACK and MATLAB would give the same result?

Or, what's the best try?

Danijel Domazet on 22 Feb 2022

Edited: Danijel Domazet on 22 Feb 2022

OK, I used rand(4,4) + i*rand(4,4), and the result is much better:

in = ...
    [0.814723686393179 + 0.421761282626275i 0.63235924622541 + 0.655740699156587i ...
    0.957506835434298 + 0.678735154857773i 0.957166948242946 + 0.655477890177557i ...
    ;
    0.905791937075619 + 0.915735525189067i 0.0975404049994095 + 0.0357116785741896i ...
    0.964888535199277 + 0.757740130578333i 0.485375648722841 + 0.171186687811562i ...
    ;
    0.126986816293506 + 0.792207329559554i 0.278498218867048 + 0.849129305868777i ...
    0.157613081677548 + 0.743132468124916i 0.8002804688888 + 0.706046088019609i ...
    ;
    0.913375856139019 + 0.959492426392903i 0.546881519204984 + 0.933993247757551i ...
    0.970592781760616 + 0.392227019534168i 0.141886338627215 + 0.0318328463774207i ...
    ];

Result is:

U = ...
  [-0.42312740984401409 -0.35959265421087588i 
    0.13117268904541174 +0.44787859162628668i ...
    0.11250427785751983 -0.24706940551578091i 
   -0.38438224614546779 -0.50239884161662351i ...
   
   -0.33759289967935291 -0.32429926333442366i 
   -0.06936700508106322 -0.47809332716460873i ...
    0.62193638822998987 -0.24622726102506251i 
    0.02217454979080485 +0.31551793178629584i ...
   
   -0.12989079970942036 -0.439785223293499i 
    0.30358385553377837 +0.4177223468250193i ...
   -0.25124960829083876 -0.062014277681078311i 
    0.42385988499316413 +0.52576884915022781i ...
   
   -0.38050005142283305 -0.34271619213843124i 
   -0.47813520137109283 -0.23139813043816407i ...
   -0.46987090655301544 +0.43716810967614084i 
   -0.19832860352154408 +0.066167190021447483i ...
   ];

The LAPACK gives:

[0][0] = -0.423127532 -0.359592706i  
[0][1] = +0.131172717 +0.447878778i  
[0][2] = -0.112504244 +0.247069359i  
[0][3] = +0.384382606 +0.502398610i  
[1][0] = -0.337592900 -0.324299276i  
[1][1] = -0.069367193 -0.478093356i  
[1][2] = -0.621936560 +0.246227175i  
[1][3] = -0.022174668 -0.315517843i  
[2][0] = -0.129890800 -0.439785272i  
[2][1] = +0.303584039 +0.417722374i  
[2][2] = +0.251249373 +0.062014218i  
[2][3] = -0.423860222 -0.525768697i
[3][0] = -0.380500108 -0.342716217i  
[3][1] = -0.478135169 -0.231398359i  
[3][2] = +0.469871104 -0.437167943i  
[3][3] = +0.198328614 -0.066167258i  

The results are OK, or very close, it's only the sign of the last two rows that are different. Why would the signs be different? I would hope it will not matter in my further calculations...

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Answer 1

David Goodmanson on 23 Feb 2022

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https://in.mathworks.com/matlabcentral/answers/1655690-matlab-and-lapack-implementation-of-the-svd-algorithm-not-the-same-output#answer_902395

Edited: David Goodmanson on 23 Feb 2022

Hi Danijel,

actually it's the columns that have different signs. That's for the following reason: Suppose the svd of the matrix 'in' is

in = USV'
and let
A = 
[1  0  0  0
 0  1  0  0 
 0  0  1  0
 0  0  0 -1]
Then, since A*A = I (4x4 identity)
in = U(AA)S(AA)V'.
Since S is diagonal, ASA = S and
in = (UA)S(AV')

So if U is a solution, so is UA. But UA just multiplies the 4th column of U by a minus sign. AV' is the accomanying solution and it multiplies the 4th row of V" by a minus sign, which means the 4th column of V gets a minus sign. You can obviously do the same for any column of both U and V, meaning that the signs of the columns are arbitrary. In your case the 3rd and 4th columns of U have the minus sign compared to Lapack, so if you take a look at V, its 3rd and 4th columns should also have a minus sign compared to Lapack. Once the signs are set, you just have to stay consistent for the rest of the calculation.