Sherman–Morrison formula

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In linear algebra, the Sherman–Morrison formula, named after Jack Sherman and Winifred J. Morrison, computes the inverse of a "rank-1 update" to a matrix whose inverse has previously been computed.[1][2][3] That is, given an invertible matrix and the outer product of vectors and the formula cheaply computes an updated matrix inverse

The Sherman–Morrison formula is a special case of the Woodbury formula. Though named after Sherman and Morrison, it appeared already in earlier publications.[4]

Statement

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Suppose   is an invertible square matrix and   are column vectors. Then   is invertible if and only if  . In this case,

 

Here,   is the outer product of two vectors   and  . The general form shown here is the one published by Bartlett.[5]

Proof

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( ) To prove that the backward direction   is invertible with inverse given as above) is true, we verify the properties of the inverse. A matrix   (in this case the right-hand side of the Sherman–Morrison formula) is the inverse of a matrix   (in this case  ) if and only if  .

We first verify that the right hand side ( ) satisfies  .

 

To end the proof of this direction, we need to show that   in a similar way as above:

 

(In fact, the last step can be avoided since for square matrices   and  ,   is equivalent to  .)

( ) Reciprocally, if  , then via the matrix determinant lemma,  , so   is not invertible.

Application

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If the inverse of   is already known, the formula provides a numerically cheap way to compute the inverse of   corrected by the matrix   (depending on the point of view, the correction may be seen as a perturbation or as a rank-1 update). The computation is relatively cheap because the inverse of   does not have to be computed from scratch (which in general is expensive), but can be computed by correcting (or perturbing)  .

Using unit columns (columns from the identity matrix) for   or  , individual columns or rows of   may be manipulated and a correspondingly updated inverse computed relatively cheaply in this way.[6] In the general case, where   is an  -by-  matrix and   and   are arbitrary vectors of dimension  , the whole matrix is updated[5] and the computation takes   scalar multiplications.[7] If   is a unit column, the computation takes only   scalar multiplications. The same goes if   is a unit column. If both   and   are unit columns, the computation takes only   scalar multiplications.

This formula also has application in theoretical physics. Namely, in quantum field theory, one uses this formula to calculate the propagator of a spin-1 field.[8][circular reference] The inverse propagator (as it appears in the Lagrangian) has the form  . One uses the Sherman–Morrison formula to calculate the inverse (satisfying certain time-ordering boundary conditions) of the inverse propagator—or simply the (Feynman) propagator—which is needed to perform any perturbative calculation[9] involving the spin-1 field.

One of the issues with the formula is that little is known about its numerical stability. There are no published results concerning its error bounds. Anecdotal evidence[10] suggests that the Woodbury matrix identity (a generalization of the Sherman–Morrison formula) may diverge even for seemingly benign examples (when both the original and modified matrices are well-conditioned).

Alternative verification

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Following is an alternate verification of the Sherman–Morrison formula using the easily verifiable identity

 .

Let

 

then

 .

Substituting   gives

 

Given a square invertible   matrix  , an   matrix  , and a   matrix  , let   be an   matrix such that  . Then, assuming   is invertible, we have

 

See also

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References

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  1. ^ Sherman, Jack; Morrison, Winifred J. (1949). "Adjustment of an Inverse Matrix Corresponding to Changes in the Elements of a Given Column or a Given Row of the Original Matrix (abstract)". Annals of Mathematical Statistics. 20: 621. doi:10.1214/aoms/1177729959.
  2. ^ Sherman, Jack; Morrison, Winifred J. (1950). "Adjustment of an Inverse Matrix Corresponding to a Change in One Element of a Given Matrix". Annals of Mathematical Statistics. 21 (1): 124–127. doi:10.1214/aoms/1177729893. MR 0035118. Zbl 0037.00901.
  3. ^ Press, William H.; Teukolsky, Saul A.; Vetterling, William T.; Flannery, Brian P. (2007), "Section 2.7.1 Sherman–Morrison Formula", Numerical Recipes: The Art of Scientific Computing (3rd ed.), New York: Cambridge University Press, ISBN 978-0-521-88068-8, archived from the original on 2012-03-19, retrieved 2011-08-08
  4. ^ Hager, William W. (1989). "Updating the inverse of a matrix". SIAM Review. 31 (2): 221–239. doi:10.1137/1031049. JSTOR 2030425. MR 0997457. S2CID 7967459.
  5. ^ a b Bartlett, Maurice S. (1951). "An Inverse Matrix Adjustment Arising in Discriminant Analysis". Annals of Mathematical Statistics. 22 (1): 107–111. doi:10.1214/aoms/1177729698. MR 0040068. Zbl 0042.38203.
  6. ^ Langville, Amy N.; and Meyer, Carl D.; "Google's PageRank and Beyond: The Science of Search Engine Rankings", Princeton University Press, 2006, p. 156
  7. ^ Update of the inverse matrix by the Sherman–Morrison formula
  8. ^ Propagator#Spin 1
  9. ^ "Perturbative quantum field theory".
  10. ^ "MathOverflow discussion". MathOverflow.
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