scipy.linalg.qr_update

scipy.linalg.qr_update(Q, R, u, v, overwrite_qruv=False, check_finite=True)

Rank-k QR update

If A = Q R is the QR factorization of A, return the QR factorization of A + u v**T for real A or A + u v**H for complex A.

Parameters
Q(M, M) or (M, N) array_like

Unitary/orthogonal matrix from the qr decomposition of A.

R(M, N) or (N, N) array_like

Upper triangular matrix from the qr decomposition of A.

u(M,) or (M, k) array_like

Left update vector

v(N,) or (N, k) array_like

Right update vector

overwrite_qruvbool, optional

If True, consume Q, R, u, and v, if possible, while performing the update, otherwise make copies as necessary. Defaults to False.

check_finitebool, optional

Whether to check that the input matrix contains only finite numbers. Disabling may give a performance gain, but may result in problems (crashes, non-termination) if the inputs do contain infinities or NaNs. Default is True.

Returns
Q1ndarray

Updated unitary/orthogonal factor

R1ndarray

Updated upper triangular factor

Notes

This routine does not guarantee that the diagonal entries of R1 are real or positive.

New in version 0.16.0.

References

1

Golub, G. H. & Van Loan, C. F. Matrix Computations, 3rd Ed. (Johns Hopkins University Press, 1996).

2

Daniel, J. W., Gragg, W. B., Kaufman, L. & Stewart, G. W. Reorthogonalization and stable algorithms for updating the Gram-Schmidt QR factorization. Math. Comput. 30, 772-795 (1976).

3

Reichel, L. & Gragg, W. B. Algorithm 686: FORTRAN Subroutines for Updating the QR Decomposition. ACM Trans. Math. Softw. 16, 369-377 (1990).

Examples

>>> from scipy import linalg
>>> a = np.array([[  3.,  -2.,  -2.],
...               [  6.,  -9.,  -3.],
...               [ -3.,  10.,   1.],
...               [  6.,  -7.,   4.],
...               [  7.,   8.,  -6.]])
>>> q, r = linalg.qr(a)

Given this q, r decomposition, perform a rank 1 update.

>>> u = np.array([7., -2., 4., 3., 5.])
>>> v = np.array([1., 3., -5.])
>>> q_up, r_up = linalg.qr_update(q, r, u, v, False)
>>> q_up
array([[ 0.54073807,  0.18645997,  0.81707661, -0.02136616,  0.06902409],  # may vary (signs)
       [ 0.21629523, -0.63257324,  0.06567893,  0.34125904, -0.65749222],
       [ 0.05407381,  0.64757787, -0.12781284, -0.20031219, -0.72198188],
       [ 0.48666426, -0.30466718, -0.27487277, -0.77079214,  0.0256951 ],
       [ 0.64888568,  0.23001   , -0.4859845 ,  0.49883891,  0.20253783]])
>>> r_up
array([[ 18.49324201,  24.11691794, -44.98940746],  # may vary (signs)
       [  0.        ,  31.95894662, -27.40998201],
       [  0.        ,   0.        ,  -9.25451794],
       [  0.        ,   0.        ,   0.        ],
       [  0.        ,   0.        ,   0.        ]])

The update is equivalent, but faster than the following.

>>> a_up = a + np.outer(u, v)
>>> q_direct, r_direct = linalg.qr(a_up)

Check that we have equivalent results:

>>> np.allclose(np.dot(q_up, r_up), a_up)
True

And the updated Q is still unitary:

>>> np.allclose(np.dot(q_up.T, q_up), np.eye(5))
True

Updating economic (reduced, thin) decompositions is also possible:

>>> qe, re = linalg.qr(a, mode='economic')
>>> qe_up, re_up = linalg.qr_update(qe, re, u, v, False)
>>> qe_up
array([[ 0.54073807,  0.18645997,  0.81707661],  # may vary (signs)
       [ 0.21629523, -0.63257324,  0.06567893],
       [ 0.05407381,  0.64757787, -0.12781284],
       [ 0.48666426, -0.30466718, -0.27487277],
       [ 0.64888568,  0.23001   , -0.4859845 ]])
>>> re_up
array([[ 18.49324201,  24.11691794, -44.98940746],  # may vary (signs)
       [  0.        ,  31.95894662, -27.40998201],
       [  0.        ,   0.        ,  -9.25451794]])
>>> np.allclose(np.dot(qe_up, re_up), a_up)
True
>>> np.allclose(np.dot(qe_up.T, qe_up), np.eye(3))
True

Similarly to the above, perform a rank 2 update.

>>> u2 = np.array([[ 7., -1,],
...                [-2.,  4.],
...                [ 4.,  2.],
...                [ 3., -6.],
...                [ 5.,  3.]])
>>> v2 = np.array([[ 1., 2.],
...                [ 3., 4.],
...                [-5., 2]])
>>> q_up2, r_up2 = linalg.qr_update(q, r, u2, v2, False)
>>> q_up2
array([[-0.33626508, -0.03477253,  0.61956287, -0.64352987, -0.29618884],  # may vary (signs)
       [-0.50439762,  0.58319694, -0.43010077, -0.33395279,  0.33008064],
       [-0.21016568, -0.63123106,  0.0582249 , -0.13675572,  0.73163206],
       [ 0.12609941,  0.49694436,  0.64590024,  0.31191919,  0.47187344],
       [-0.75659643, -0.11517748,  0.10284903,  0.5986227 , -0.21299983]])
>>> r_up2
array([[-23.79075451, -41.1084062 ,  24.71548348],  # may vary (signs)
       [  0.        , -33.83931057,  11.02226551],
       [  0.        ,   0.        ,  48.91476811],
       [  0.        ,   0.        ,   0.        ],
       [  0.        ,   0.        ,   0.        ]])

This update is also a valid qr decomposition of A + U V**T.

>>> a_up2 = a + np.dot(u2, v2.T)
>>> np.allclose(a_up2, np.dot(q_up2, r_up2))
True
>>> np.allclose(np.dot(q_up2.T, q_up2), np.eye(5))
True