# Could we get different solutions for eigenVectors from a matrix?

My purpose is to find a eigenvectors of a matrix. In Matlab, there is a [V,D] = eig(M) to get the eigenvectors of matrix by using: [V,D] = eig(M). Alternatively I used the website WolframAlpha to double check my results.

We have a 10X10 matrix called M:

0.736538062307847   -0.638137874226607  -0.409041107160722  -0.221115060391256  -0.947102932298308  0.0307937582853794  1.23891356582639    1.23213871779652    0.763885436104244   -0.805948245321096
-1.00495215920171   -0.563583317483057  -0.250162608745252  0.0837145788064272  -0.201241986127792  -0.0351472158148094 -1.36303599752928   0.00983020375259212 -0.627205458137858  0.415060573134481
0.372470672825535   -0.356014310976260  -0.331871925811400  0.151334279460039   0.0983275066581362  -0.0189726910991071 0.0261595600177302  -0.752014960080128  -0.00643718050231003    0.802097123260581
1.26898635468390    -0.444779390923673  0.524988731629985   0.908008064819586   -1.66569084499144   -0.197045800083481  1.04250295411159    -0.826891197039745  2.22636770820512    0.226979917020922
-0.307384714237346  0.00930402052877782 0.213893752473805   -1.05326116146192   -0.487883985126739  0.0237598951768898  -0.224080566774865  0.153775526014521   -1.93899137944122   -0.300158630162419
7.04441299430365    -1.34338456640793   -0.461083493351887  5.30708311554706    -3.82919170270243   -2.18976040860706   6.38272280044908    2.33331906669527    9.21369926457948    -2.11599193328696
1   0   0   0   0   0   0   0   0   0
0   1   0   0   0   0   0   0   0   0
0   0   0   1   0   0   0   0   0   0
0   0   0   0   0   0   1   0   0   0

D:

2.84950796497613 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    1.08333535157800 + 0.971374792725758i   0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    1.08333535157800 - 0.971374792725758i   0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    -2.05253164206377 + 0.00000000000000i   0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    -0.931513274011512 + 0.883950434279189i 0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    -0.931513274011512 - 0.883950434279189i 0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    -1.41036956613286 + 0.354930202789307i  0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    -1.41036956613286 - 0.354930202789307i  0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    -0.374014257422547 + 0.00000000000000i  0.00000000000000 + 0.00000000000000i
0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.00000000000000 + 0.00000000000000i    0.165579401742139 + 0.00000000000000i

V:

-0.118788118233448 + 0.00000000000000i  0.458452024790792 + 0.00000000000000i   0.458452024790792 + -0.00000000000000i  -0.00893883603500744 + 0.00000000000000i    -0.343151745490688 - 0.0619235203325516i    -0.343151745490688 + 0.0619235203325516i    -0.415371644459693 + 0.00000000000000i  -0.415371644459693 + -0.00000000000000i -0.0432672840354827 + 0.00000000000000i 0.0205670999343567 + 0.00000000000000i
0.0644460666316380 + 0.00000000000000i  -0.257319460426423 + 0.297135138351391i -0.257319460426423 - 0.297135138351391i 0.000668740843331284 + 0.00000000000000i    -0.240349418297316 + 0.162117384568559i -0.240349418297316 - 0.162117384568559i -0.101240986260631 + 0.370051721507625i -0.101240986260631 - 0.370051721507625i 0.182133003667802 + 0.00000000000000i   0.0870047828436781 + 0.00000000000000i
-0.0349638967773464 + 0.00000000000000i -0.0481533171088709 - 0.333551383088345i    -0.0481533171088709 + 0.333551383088345i    -5.00304864960391e-05 + 0.00000000000000i   -0.0491721720673945 + 0.235973015480054i    -0.0491721720673945 - 0.235973015480054i    0.305000451960374 + 0.180389787086258i  0.305000451960374 - 0.180389787086258i  -0.766686233364027 + 0.00000000000000i  0.368055402163444 + 0.00000000000000i
-0.328483258287378 + 0.00000000000000i  -0.321235466934363 - 0.0865401147007471i    -0.321235466934363 + 0.0865401147007471i    -0.0942807049530764 + 0.00000000000000i -0.0354015249204485 + 0.395526630779543i    -0.0354015249204485 - 0.395526630779543i    -0.0584777280581259 - 0.342389123727367i    -0.0584777280581259 + 0.342389123727367i    0.0341847135233905 + 0.00000000000000i  -0.00637190625187862 + 0.00000000000000i
0.178211880664383 + 0.00000000000000i   0.236391683569043 - 0.159628238798322i  0.236391683569043 + 0.159628238798322i  0.00705341924756006 + 0.00000000000000i 0.208292766328178 + 0.256171148954103i  0.208292766328178 - 0.256171148954103i  -0.319285221542254 - 0.0313551221105837i    -0.319285221542254 + 0.0313551221105837i    -0.143900055026164 + 0.00000000000000i  -0.0269550068563120 + 0.00000000000000i
-0.908350536903352 + 0.00000000000000i  0.208752559894992 + 0.121276611951418i  0.208752559894992 - 0.121276611951418i  -0.994408141243082 + 0.00000000000000i  0.452243212306010 + 0.00000000000000i   0.452243212306010 + -0.00000000000000i  0.273997199582534 - 0.0964058973906923i 0.273997199582534 + 0.0964058973906923i -0.0270087356931836 + 0.00000000000000i 0.00197408431000798 + 0.00000000000000i
-0.0416872385315279 + 0.00000000000000i 0.234583850413183 - 0.210340074973091i  0.234583850413183 + 0.210340074973091i  0.00435502958971167 + 0.00000000000000i 0.160642433241717 + 0.218916331789935i  0.160642433241717 - 0.218916331789935i  0.276971588308683 + 0.0697020017773242i 0.276971588308683 - 0.0697020017773242i 0.115683515205146 + 0.00000000000000i   0.124212913671392 + 0.00000000000000i
0.0226165595687948 + 0.00000000000000i  0.00466011130798999 + 0.270099580217056i    0.00466011130798999 - 0.270099580217056i    -0.000325812684017280 + 0.00000000000000i   0.222664282388928 + 0.0372585184944646i 0.222664282388928 - 0.0372585184944646i 0.129604953142137 - 0.229763189016417i  0.129604953142137 + 0.229763189016417i  -0.486968076893485 + 0.00000000000000i  0.525456559984271 + 0.00000000000000i
-0.115277185508808 + 0.00000000000000i  -0.204076984892299 + 0.103102999488027i -0.204076984892299 - 0.103102999488027i 0.0459338618810664 + 0.00000000000000i  0.232009172507840 - 0.204443701767505i  0.232009172507840 + 0.204443701767505i  -0.0184618718969471 + 0.238119465887194i    -0.0184618718969471 - 0.238119465887194i    -0.0913994930540061 + 0.00000000000000i -0.0384824814248494 + 0.00000000000000i
-0.0146296269545178 + 0.00000000000000i 0.0235283849818557 - 0.215256480570249i 0.0235283849818557 + 0.215256480570249i -0.00212178438590738 + 0.00000000000000i    0.0266030060993678 - 0.209766836873709i 0.0266030060993678 + 0.209766836873709i -0.172989400304240 - 0.0929551855455724i    -0.172989400304240 + 0.0929551855455724i    -0.309302420721495 + 0.00000000000000i  0.750171291624984 + 0.00000000000000i

I was given the following results:

1. Original Matrix:

1. The results from WolframAlpha:

1. The results from Matlab Eig:

D(eigenvalues)

V(eigenvectors)

Is it possible to get different solutions for eigenVectors or it should be a unique answer. I am interested to get clarified on this concept.

-

Eigenvectors are NOT unique, for a variety of reasons. Change the sign, and an eigenvector is still an eigenvector for the same eigenvalue. In fact, multiply by any constant, and an eigenvector is still that. Different tools can sometimes choose different normalizations.

If an eigenvalue is of multiplicity greater than one, then the eigenvectors are again not unique, as long as they span the same subspace.

-
Does it apply to imaginary part also? [ in eigenVector ] or let's ask in other words: as we use different normalizations, we get different eigenVectors. so far so good... Could we say the results that we get for eigenVectors ( from any of computation approaches) if the imaginary part from one of solutions/answers is ZERO for the rest of approaches we imaginary part would be ZERO for corresponding answer? – farzin parsa Oct 24 '12 at 3:15
I can multiply an eigenvector by any complex number, including i=sqrt(-1), and it is still an eigenvector. So you cannot claim what you want. – user85109 Oct 24 '12 at 9:17
I want to see if I could use it as a rule or not for some work implementation. EX) Imagine one of the elements in eigenVector V[i,j] is equal to a+bi calculated by approach A. With another approach B: it is a'+ b'i in same place V[i,j]. Could we say these two different answers ( a+bi AND a'+ b'i ) are corresponding answers . [ if yes, is it necessary it satisfies the following condition: a^2 + b^2 = a'^2 + b'^2 ] – farzin parsa Oct 24 '12 at 18:49
You cannot say ANYTHING from a single element. – user85109 Oct 24 '12 at 22:39

As woodchips points out (+1), eigenvectors are unique only up to a linear transformation. This fact is readily apparent from the definition, ie an eigenvector/eigenvalue pair solve the characteristic function A*v = k*v, where A is the matrix, v is the eigenvector, and k is the eigenvalue.

Let's consider a much simpler example than your (horrendous looking) question:

M = [1, 2, 3; 4, 5, 6; 7, 8, 9];
[EigVec, EigVal] = eig(M);

Matlab yields:

EigVec =
-0.2320   -0.7858    0.4082
-0.5253   -0.0868   -0.8165
-0.8187    0.6123    0.4082

while Mathematica yields:

EigVec =
0.2833    -1.2833    1
0.6417    -0.1417    -2
1         1          1

From the Matlab documentation:

"For eig(A), the eigenvectors are scaled so that the norm of each is 1.0.".

Mathematica on the other hand is clearly scaling the eigenvectors so that so the final element is unity.

Even just eyeballing the outputs I've given, you can start to see the relationships emerge (in particular, compare the third eigenvector from both outputs).

By the way, I suggest you edit your question to have a more simple input matrix M, such as the one I've used here. This will make it much more readable for anyone who visits this page in the future. It is actually not that bad a question, but the way it is currently formatted will likely cause it to be down-voted.

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Why in some approaches eigenVectors has imaginary values and in some dont? – farzin parsa Oct 24 '12 at 6:46
@farzinparsa The problem of finding eigenvalues can be made equivalent to the problem of finding the roots of a polynomial. The proof of this should be in any good text on linear algebra. Now, it is common knowledge that the roots of polynomials can be imaginary (eg think of the quadratic formula from high-school). Therefore eigenvalues, and thus eigenvectors may be complex. Are there conditions guaranteeing real eigenvalues? Yes, if a matrix is symmetric, its eigenvalues will be real. This stuff is in any standard text on linear algebra. – Colin T Bowers Oct 24 '12 at 7:10

I completely agree with Mr.Colin T Bowers, that MATHEMATICA does the normalization so that last value of EigenVectors become one. Using MATLAB if anybody want to produce EigenVectors result like MATHEMATICA then we can tell MATLAB Normalize the last value of EigenVectors result to 1 using following normalization step.

M = [1, 2, 3; 4, 5, 6; 7, 8, 9];

[EigVec, EigVal] = eig(M);

sf=1./EigVec(end,:); %get the last value of each eigen vector and inverse for scale factor

sf=repmat(sf,size(EigVec,1),1); % Repeat Scale value of each element in the vector

Normalize_EigVec=EigVec.*sf;

Normalize_EigVec =

0.2833   -1.2833    1.0000
0.6417   -0.1417   -2.0000
1.0000    1.0000    1.0000
-
Does it apply to imaginary part also? [ in eigenVector ] or let's ask in other words: as we use different normalizations, we get different eigenVectors. so far so good... Could we say the results that we get for eigenVectors ( from any of computation approaches) if the imaginary part from one of solutions/answers is ZERO for the rest of approaches we imaginary part would be ZERO for corresponding answer? – farzin parsa Oct 24 '12 at 6:36
I just received a notification that you tried to edit my answer and replace it with yours. I'm guessing you thought you were editing your own answer, but accidentally clicked mine instead :-) Anyway, no problems, the moderators picked it up and prevented the edit. By the way, this is a neat little extension to my answer - worth a +1. – Colin T Bowers Oct 24 '12 at 12:53
@Colin T Bowers: I didn't,I asked a question and looking for the answer. I dont have any answer to replace :) I want to see if I could use it as a rule or not for some work implementation. EX) Imagine one of the elements in eigenVector V[i,j] is equal to a+bi calculated by approach A. With another approach B: it is a'+ b'i in same place V[i,j]. Could we say these two different answers ( a+bi AND a'+ b'i ) are corresponding answers . [ if yes, is it necessary it satisfies the following condition: a^2 + b^2 = a'^2 + b'^2 ] – farzin parsa Oct 24 '12 at 18:52
@farzinparsa My comment was intended for veeresh, not you :-) In regards to your question, it would be best to say the two answers are equally valid. I don't think the condition you state is necessary or sufficient. – Colin T Bowers Oct 25 '12 at 3:46