In mathematics, a shift matrix is a binary matrix with ones only on the superdiagonal or subdiagonal, and zeroes elsewhere. A shift matrix U with ones on the superdiagonal is an upper shift matrix. The alternative subdiagonal matrix L is unsurprisingly known as a lower shift matrix. The (i, j )th component of U and L are

where is the Kronecker delta symbol.

For example, the 5 × 5 shift matrices are

Clearly, the transpose of a lower shift matrix is an upper shift matrix and vice versa.

As a linear transformation, a lower shift matrix shifts the components of a column vector one position down, with a zero appearing in the first position. An upper shift matrix shifts the components of a column vector one position up, with a zero appearing in the last position.[1]

Premultiplying a matrix A by a lower shift matrix results in the elements of A being shifted downward by one position, with zeroes appearing in the top row. Postmultiplication by a lower shift matrix results in a shift left. Similar operations involving an upper shift matrix result in the opposite shift.

Clearly all finite-dimensional shift matrices are nilpotent; an n × n shift matrix S becomes the zero matrix when raised to the power of its dimension n.

Shift matrices act on shift spaces. The infinite-dimensional shift matrices are particularly important for the study of ergodic systems. Important examples of infinite-dimensional shifts are the Bernoulli shift, which acts as a shift on Cantor space, and the Gauss map, which acts as a shift on the space of continued fractions (that is, on Baire space.)

Properties

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Let L and U be the n × n lower and upper shift matrices, respectively. The following properties hold for both U and L. Let us therefore only list the properties for U:

The following properties show how U and L are related:

  • LT = U; UT = L
  • The null spaces of U and L are
     
     
  • The spectrum of U and L is  . The algebraic multiplicity of 0 is n, and its geometric multiplicity is 1. From the expressions for the null spaces, it follows that (up to a scaling) the only eigenvector for U is  , and the only eigenvector for L is  .
  • For LU and UL we have
     
     
    These matrices are both idempotent, symmetric, and have the same rank as U and L
  • LnaUna + LaUa = UnaLna + UaLa = I (the identity matrix), for any integer a between 0 and n inclusive.

If N is any nilpotent matrix, then N is similar to a block diagonal matrix of the form

 

where each of the blocks S1S2, ..., Sr is a shift matrix (possibly of different sizes).[2][3]

Examples

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Then,

 

Clearly there are many possible permutations. For example,   is equal to the matrix A shifted up and left along the main diagonal.

 

See also

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Notes

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References

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  • Beauregard, Raymond A.; Fraleigh, John B. (1973), A First Course In Linear Algebra: with Optional Introduction to Groups, Rings, and Fields, Boston: Houghton Mifflin, ISBN 0-395-14017-X, OCLC 1019797576
  • Herstein, I. N. (1964), Topics In Algebra, Waltham: Blaisdell Publishing, ISBN 978-1-114-54101-6, OCLC 1419919702
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