# Implementing a PCA (Eigenvector based) in Python

I try to implement a PCA in Python. My goal is to create a version which behaves similarly to Matlab's PCA implementation. However, I think I miss a crucial point as my tests partly produce a results with the wrong sign(+/-).

Can you find a mistake the algorithm? Why the signs are sometimes different?

An implementation of PCA based on eigen vectors:

``````new_array_rank=4
A_mean = np.mean(A, axis=0)
A = A - A_mean

covariance_matrix = np.cov(A.T)

eigen_values, eigen_vectors = np.linalg.eig(covariance_matrix)
new_index = np.argsort(eigen_values)[::-1]
eigen_vectors = eigen_vectors[:,new_index]
eigen_values = eigen_values[new_index]

eigen_vectors = eigen_vectors[:,:new_array_rank]
return np.dot(eigen_vectors.T, A.T).T
``````

My test values:

``````array([[ 0.13298325,  0.2896928 ,  0.53589224,  0.58164269,  0.66202221,
0.95414116,  0.03040784,  0.26290471,  0.40823539,  0.37783385],
[ 0.90521267,  0.86275498,  0.52696221,  0.15243867,  0.20894357,
0.19900414,  0.50607341,  0.53995902,  0.32014539,  0.98744942],
[ 0.87689087,  0.04307512,  0.45065793,  0.29415066,  0.04908066,
0.98635538,  0.52091338,  0.76291385,  0.97213094,  0.48815925],
[ 0.75136801,  0.85946751,  0.10508436,  0.04656418,  0.08164919,
0.88129981,  0.39666754,  0.86325704,  0.56718669,  0.76346602],
[ 0.93319721,  0.5897521 ,  0.75065047,  0.63916306,  0.78810679,
0.92909485,  0.23751963,  0.87552313,  0.37663086,  0.69010429],
[ 0.53189229,  0.68984247,  0.46164066,  0.29953259,  0.10826334,
0.47944168,  0.93935082,  0.40331874,  0.18541041,  0.35594587],
[ 0.36399075,  0.00698617,  0.61030608,  0.51136309,  0.54185601,
0.81383604,  0.50003674,  0.75414875,  0.54689801,  0.9957493 ],
[ 0.27815017,  0.65417397,  0.57207255,  0.54388744,  0.89128334,
0.3512483 ,  0.94441934,  0.05305929,  0.77389942,  0.93125228],
[ 0.80409485,  0.2749575 ,  0.22270875,  0.91869706,  0.54683128,
0.61501493,  0.7830902 ,  0.72055598,  0.09363186,  0.05103846],
[ 0.12357816,  0.29758902,  0.87807485,  0.94348706,  0.60896429,
0.33899019,  0.36310027,  0.02380186,  0.67207071,  0.28638936]])
``````

My result of the PCA with eigen vectors:

``````array([[  5.09548931e-01,  -3.97079651e-01,  -1.47555867e-01,
-3.55343967e-02,  -4.92125732e-01,  -1.78191399e-01,
-3.29543974e-02,   3.71406504e-03,   1.06404170e-01,
-1.66533454e-16],
[ -5.15879041e-01,   6.40833419e-01,  -7.54601587e-02,
-2.00776798e-01,  -7.07247669e-02,   2.68582368e-01,
-1.66124362e-01,   1.03414828e-01,   7.76738500e-02,
5.55111512e-17],
[ -4.42659342e-01,  -5.13297786e-01,  -1.65477203e-01,
5.33670847e-01,   2.00194213e-01,   2.06176265e-01,
1.31558875e-01,  -2.81699724e-02,   6.19571305e-02,
-8.32667268e-17],
[ -8.50397468e-01,   5.14319846e-02,  -1.46289906e-01,
6.51133920e-02,  -2.83887201e-01,  -1.90516618e-01,
1.45748370e-01,   9.49464768e-02,  -1.05989648e-01,
4.16333634e-17],
[ -1.61040296e-01,  -3.47929944e-01,  -1.19871598e-01,
-6.48965493e-01,   7.53188055e-02,   1.31730340e-01,
1.33229858e-01,  -1.43587499e-01,  -2.20913989e-02,
-3.40005801e-16],
[ -1.70017435e-01,   4.22573148e-01,   4.81511942e-01,
2.42170125e-01,  -1.18575764e-01,  -6.87250591e-02,
-1.20660307e-01,  -2.22865482e-01,  -1.73666882e-02,
-1.52655666e-16],
[  6.90841779e-02,  -2.86233901e-01,  -4.16612350e-01,
9.38935057e-03,   3.02325120e-01,  -1.61783482e-01,
-3.55465509e-01,   1.15323059e-02,  -5.04619674e-02,
4.71844785e-16],
[  5.26189089e-01,   6.81324113e-01,  -2.89960115e-01,
2.01781673e-02,   3.03159463e-01,  -2.11777986e-01,
2.25937548e-01,  -5.49219872e-05,   3.66268329e-02,
-1.11022302e-16],
[  6.68680313e-02,  -2.99715813e-01,   8.53428694e-01,
-1.30066853e-01,   2.31410283e-01,  -1.02860624e-01,
1.95449586e-02,   1.30218425e-01,   1.68059569e-02,
2.22044605e-16],
[  9.68303353e-01,   4.80944309e-02,   2.62865615e-02,
1.44821658e-01,  -1.47094421e-01,   3.07366196e-01,
1.91849667e-02,   5.08517759e-02,  -1.03558238e-01,
1.38777878e-16]])
``````

Test result of the same data using Matlab's PCA function:

``````array([[ -5.09548931e-01,   3.97079651e-01,   1.47555867e-01,
3.55343967e-02,  -4.92125732e-01,  -1.78191399e-01,
-3.29543974e-02,  -3.71406504e-03,  -1.06404170e-01,
-0.00000000e+00],
[  5.15879041e-01,  -6.40833419e-01,   7.54601587e-02,
2.00776798e-01,  -7.07247669e-02,   2.68582368e-01,
-1.66124362e-01,  -1.03414828e-01,  -7.76738500e-02,
-0.00000000e+00],
[  4.42659342e-01,   5.13297786e-01,   1.65477203e-01,
-5.33670847e-01,   2.00194213e-01,   2.06176265e-01,
1.31558875e-01,   2.81699724e-02,  -6.19571305e-02,
-0.00000000e+00],
[  8.50397468e-01,  -5.14319846e-02,   1.46289906e-01,
-6.51133920e-02,  -2.83887201e-01,  -1.90516618e-01,
1.45748370e-01,  -9.49464768e-02,   1.05989648e-01,
-0.00000000e+00],
[  1.61040296e-01,   3.47929944e-01,   1.19871598e-01,
6.48965493e-01,   7.53188055e-02,   1.31730340e-01,
1.33229858e-01,   1.43587499e-01,   2.20913989e-02,
-0.00000000e+00],
[  1.70017435e-01,  -4.22573148e-01,  -4.81511942e-01,
-2.42170125e-01,  -1.18575764e-01,  -6.87250591e-02,
-1.20660307e-01,   2.22865482e-01,   1.73666882e-02,
-0.00000000e+00],
[ -6.90841779e-02,   2.86233901e-01,   4.16612350e-01,
-9.38935057e-03,   3.02325120e-01,  -1.61783482e-01,
-3.55465509e-01,  -1.15323059e-02,   5.04619674e-02,
-0.00000000e+00],
[ -5.26189089e-01,  -6.81324113e-01,   2.89960115e-01,
-2.01781673e-02,   3.03159463e-01,  -2.11777986e-01,
2.25937548e-01,   5.49219872e-05,  -3.66268329e-02,
-0.00000000e+00],
[ -6.68680313e-02,   2.99715813e-01,  -8.53428694e-01,
1.30066853e-01,   2.31410283e-01,  -1.02860624e-01,
1.95449586e-02,  -1.30218425e-01,  -1.68059569e-02,
-0.00000000e+00],
[ -9.68303353e-01,  -4.80944309e-02,  -2.62865615e-02,
-1.44821658e-01,  -1.47094421e-01,   3.07366196e-01,
1.91849667e-02,  -5.08517759e-02,   1.03558238e-01,
-0.00000000e+00]])
``````
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