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SingularValueDecomposition[m]

gives the singular value decomposition for a numerical matrix m as a list of matrices {u,σ,v}, where σ is a diagonal matrix and m can be written as u.σ.ConjugateTranspose[v].

SingularValueDecomposition[{m,a}]

gives the generalized singular value decomposition of m with respect to a.

SingularValueDecomposition[m,spec]

gives the singular value decomposition associated with the largest singular values specified by spec.

Details and Options
Details and Options Details and Options
Examples  
Basic Examples  
Scope  
Basic Uses  
Subsets of Singular Values  
Generalized Singular Value Decomposition  
Special Matrices  
Options  
TargetStructure  
Tolerance  
Applications  
Geometry of SVD  
Least Squares and Curve Fitting  
Properties & Relations  
Possible Issues  
See Also
Tech Notes
Related Guides
History
Cite this Page

SingularValueDecomposition

SingularValueDecomposition[m]

gives the singular value decomposition for a numerical matrix m as a list of matrices {u,σ,v}, where σ is a diagonal matrix and m can be written as u.σ.ConjugateTranspose[v].

SingularValueDecomposition[{m,a}]

gives the generalized singular value decomposition of m with respect to a.

SingularValueDecomposition[m,spec]

gives the singular value decomposition associated with the largest singular values specified by spec.

Details and Options

  • The matrix m may be rectangular.
  • The diagonal elements of σ are the singular values of m.
  • SingularValueDecomposition sets to zero any singular values that would be dropped by SingularValueList.
  • The option Tolerance can be used as in SingularValueList to determine which singular values will be considered to be zero. »
  • u and v are column orthonormal matrices, whose transposes can be considered as lists of orthonormal vectors.
  • SingularValueDecomposition[{m,a}] gives a list of matrices {{u,ua},{w,wa},v} such that m can be written as u.w.ConjugateTranspose[v] and a can be written as ua.wa.ConjugateTranspose[v]. »
  • The second argument spec can take the following settings:
  • kreturn the decomposition that goes with the k largest singular values
    UpTo[k]return a decomposition for as many of the first k largest singular values as are available
    "Thin"return a thin singular value decomposition using the Min[Dimensions[m]] largest singular values
  • With the setting TargetStructure->"Structured", SingularValueDecomposition[m] returns the matrices {u,σ,v} as structured matrices.

Examples

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Basic Examples  (3)

Compute a singular value decomposition:

Reconstruct the input matrix:

Compute a singular value decomposition for an invertible matrix:

The matrix of singular values is also invertible:

Reconstruct the input matrix:

Compute a singular value decomposition for an invertible matrix:

Format the results:

Reconstruct the input matrix:

Scope  (18)

Basic Uses  (7)

Find the singular value decomposition of a machine-precision matrix:

Format the result:

Singular value decomposition of a complex matrix:

Singular value decomposition for an exact matrix:

Singular value decomposition for an arbitrary-precision matrix:

Singular value decomposition of a symbolic matrix:

The singular value decomposition of a large numerical matrix is computed efficiently:

Singular value decomposition of a non-square matrix:

Subsets of Singular Values  (5)

Find the singular value decomposition associated with the three largest singular values of a matrix:

Unlike the full decomposition, these matrices do not recreate any part of the matrix exactly:

Find singular value decomposition associated with the three smallest singular values:

Find the "compact" decomposition associated with the nonzero singular values:

This decomposition still has sufficient information to reconstruct the matrix:

The full singular value decomposition contains a row of zeros:

Find the thin decomposition of a rectangular matrix:

The matrix is square:

The number of singular values used equals the smaller of the dimensions of the input matrix:

This decomposition still has sufficient information to reconstruct the matrix:

The full singular value decomposition contains rows or columns of zeros in a rectangular :

Find the decomposition associated with the three largest singular values, or as many as there are if fewer:

Compute a truncated singular value decomposition for a matrix with repeated singular values:

Repeated singular values are counted separately when doing a partial decomposition:

Generalized Singular Value Decomposition  (2)

Find the generalized singular value decomposition of a machine-precision real matrix:

Verify the result:

Find the generalized singular value decomposition of a machine-precision complex matrix:

Verify the result:

Special Matrices  (4)

Singular value decomposition of sparse matrices:

Find the decomposition associated to the three largest singular values:

Visualize the three right-singular vectors:

Singular value decomposition of structured matrices:

Use a different structure:

The units go with the singular values:

Singular value decomposition of an identity matrix:

Verify the decomposition:

and could have been chosen to be identity matricesthe decomposition is not unique:

Singular value decomposition of HilbertMatrix:

Options  (3)

TargetStructure  (2)

A real rectangular matrix:

With TargetStructure->"Dense", the result of SingularValueDecomposition is a list of three dense matrices:

With TargetStructure->"Structured", the result of SingularValueDecomposition is a list containing two OrthogonalMatrix objects and a DiagonalMatrix:

A complex rectangular matrix:

With TargetStructure->"Dense", the result of SingularValueDecomposition is a list of three dense matrices:

With TargetStructure->"Structured", the result of SingularValueDecomposition is a list containing two UnitaryMatrix objects and a DiagonalMatrix:

Tolerance  (1)

m is a nearly singular matrix:

To machine precision, the matrix is effectively singular:

With a smaller tolerance, the nonzero singular value is detected:

The default tolerance is based on precision, so the small value is detected with precision 20:

Applications  (11)

Geometry of SVD  (5)

Compute the singular value decomposition of the 2×2 matrix :

The action of TemplateBox[{v}, Transpose] is a rotation and possiblyas happens for the axis in this casea reflection:

The action of is a scalingeither a dilation or compressionalong each axis:

The action of is a rotation and possiblythough not in this casea reflection in the target space:

Compute the singular value decomposition of the 3×2 matrix :

After the rotation in the plane by the TemplateBox[{v}, Transpose] matrix, the matrix embeds the unit circle as an ellipse in 3D:

The matrix rotates the ellipse in three dimensions:

Compute the singular value decomposition of the 2×2 matrix :

Let and denote the columns, respectively, of and :

is the direction in which TemplateBox[{{m, ., x}}, Norm] is maximized, and the maximum value is :

Similarly, is the direction in which TemplateBox[{{m, ., x}}, Norm] is minimized, and the minimum value is :

Visualize , and the unit circle along with their image under the multiplication on the left by :

is the direction in which TemplateBox[{{x, ., m}}, Norm] is maximized, and again the maximum value is :

Similarly, is the direction in which TemplateBox[{{x, ., m}}, Norm] is minimized, and again the minimum value is :

Visualize , and the unit circle along with their image under the multiplication on the right by :

Compute the singular value decomposition of the 3×2 matrix :

Let and denote the columns, respectively, of and :

is the direction in which TemplateBox[{{m, ., x}}, Norm] is maximized, and the maximum value is :

Similarly, is the direction in which TemplateBox[{{m, ., x}}, Norm] is minimized, and the minimum value is :

Visualize , and the image of the unit circle in the plane under left-multiplication by :

is the direction in which TemplateBox[{{x, ., m}}, Norm] is maximized, and again the maximum value is :

minimizes TemplateBox[{{x, ., m}}, Norm]the minimum is zero, as the sphere is compressed into an ellipse in the plane:

maximizes TemplateBox[{{x, ., m}}, Norm] subject to the constraint , and the maximum value is :

Visualize , , and the image of the unit sphere in the plane under right-multiplication by :

Compute the singular value decomposition of the 3×3 matrix :

Let and denote the columns, respectively, of and :

is the direction in which TemplateBox[{{m, ., x}}, Norm] is maximized, and the maximum value is :

is the direction in which TemplateBox[{{m, ., x}}, Norm] is maximized if , and the maximum value is :

Similarly, is the direction in which TemplateBox[{{m, ., x}}, Norm] is minimized, and the minimum value is :

Visualize , , and the unit sphere along with their image under the multiplication on the left by :

is the direction in which TemplateBox[{{x, ., m}}, Norm] is maximized, and again the maximum value is :

is the direction in which TemplateBox[{{x, ., m}}, Norm] is maximized if , and again the maximum value is :

Similarly, is the direction in which TemplateBox[{{x, ., m}}, Norm] is minimized, and again the minimum value is :

Visualize , , and the unit sphere along with their image under the multiplication on the right by :

Least Squares and Curve Fitting  (6)

If the linear system has no solution, the best approximate solution is the least-squares solution. That is the solution to , where is the orthogonal projection of onto the column space of , which can be computed using the singular value decomposition. Consider the following and :

The linear system is inconsistent:

Find the matrix of the compact singular value decomposition of . Its columns are orthonormal and span :

Compute the orthogonal projection of onto the space spanned by the columns of :

Visualize , its projections onto the columns of and :

Solve :

Confirm the result using LeastSquares:

Solve the least-squares problem for the following and using only the singular value decomposition:

Compute the compact singular value decomposition where only the nonzero singular values are kept:

Let x=v.TemplateBox[{sigma}, Inverse].TemplateBox[{u}, ConjugateTranspose].b:

By definition, , so m.x=u.sigma.TemplateBox[{sigma}, Inverse].TemplateBox[{u}, ConjugateTranspose].b=u.TemplateBox[{u}, ConjugateTranspose].b, the orthogonal projection of onto :

Thus, is the solution to the least-squares problem, as confirmed by LeastSquares:

Solve the least-squares problem for the following and two different ways: by projecting onto the column space of using just the matrix of the singular value decomposition, and the direct solution using the full decomposition. Compare and explain the results:

Compute the compact singular value decomposition of:

Compute the orthogonal projection of onto :

Solve :

The direct solution can be found using x=v.TemplateBox[{sigma}, Inverse].TemplateBox[{u}, ConjugateTranspose].b=v.TemplateBox[{sigma}, Inverse].TemplateBox[{u}, Transpose].b, as both and are real-valued:

While x and xPerp are different, both solve the least-squares problem because m.x==m.xPerp:

The two solutions differ by an element of NullSpace[m]:

Note that LeastSquares[m,b] gives the result using the direct method:

For the matrices and that follow, find a matrix that minimizes TemplateBox[{{{m, ., x}, -, b}}, Norm]_F:

One solution, in this case unique, is given by x=v.TemplateBox[{sigma}, Inverse].TemplateBox[{u}, Transpose].b:

This result could also have been obtained using LeastSquares[m,b]:

Confirm the answer using Minimize:

SingularValueDecomposition can be used to find a best-fit curve to data. Consider the following data:

Extract the and coordinates from the data:

Construct a design matrix, whose columns are and , for fitting to a line :

Get the coefficients and for a linear leastsquares fit using a thin singular value decomposition:

Verify the coefficients using Fit:

Plot the best-fit curve along with the data:

Find the best-fit parabola to the following data:

Extract the and coordinates from the data:

Construct a design matrix, whose columns are , and , for fitting to a line :

Get the coefficients , and for a leastsquares fit:

Verify the coefficients using Fit:

Plot the best-fit curve along with the data:

Properties & Relations  (13)

The singular value decomposition {u,σ,v} of m decomposes m as u.σ.ConjugateTranspose[v]:

If a is an n×m matrix with decomposition {u,σ,v}, then u is an n×n matrix:

v is an m×m matrix:

And σ is an n×m matrix:

SingularValueDecomposition[m] is built from the eigenvalue decompositions of m.TemplateBox[{m}, ConjugateTranspose] and TemplateBox[{m}, ConjugateTranspose].m:

Compute EigenvalueDecomposition[m.ConjugateTranspose[m]]:

Then is up to phase in each column:

Compute the eigenvalue decomposition of TemplateBox[{m}, ConjugateTranspose].m:

Then is up to phase in each column:

Since has fewer rows than columns, the is (as opposed to ):

The first right singular vector can be found by maximizing TemplateBox[{{m, ., x}}, Norm] over all unit vectors:

Each subsequent vector is a maximizer with the constraint that it is perpendicular to all previous vectors:

Compare the with the found by SingularValueDecomposition; they are the same up to sign:

The analogous statement holds for the left singular vectors with TemplateBox[{{x, ., m}}, Norm]:

The diagonal entries of are the respective maximum values:

If is the smaller of the dimensions of , the first columns of and are related by :

The first columns of and are also related by :

If m is a square matrix, the product of the diagonal elements of equals Abs[Det[m]]:

If is a normal matrix, both and are composed of the same vectors:

The vectors will appear in a different order unless is positive semidefinite and Hermitian:

The diagonal entries of equal Abs[Eigenvalues[m]]:

For positive definite and Hermitian , SingularValueDecomposition and EigenvalueDecomposition coincide:

and are equal:

Their columns are unit eigenvectors of , so they are the same as up to phase:

The nonzero elements of are the eigenvalues of , so :

MatrixRank[m] equals the number of nonzero singular values:

The compact decomposition that only keeps nonzero singular values can compute PseudoInverse[m]:

If decomposes as u.sigma.TemplateBox[{v}, ConjugateTranspose], then m^((-1))=v.TemplateBox[{sigma}, Inverse].TemplateBox[{u}, ConjugateTranspose]:

A matrix m that is an outer product of two vectors has MatrixRank[m]==1:

The nonzero singular value of m is the product of the norms of the vectors:

The corresponding left and right singular vectors are the input vectors, normalized:

SingularValueDecomposition[{m,a}] decomposes m as u.w.ConjugateTranspose[v]:

It decomposes a as ua.wa.ConjugateTranspose[v]:

SingularValueDecomposition[{m,a}] can be related to Eigensystem[{m.m,a.a}]:

The diagonal elements of w are /:

The diagonal elements of wa are 1/:

The columns of v are scaled multiples of the columns of Conjugate[Inverse[vλ]]:

The magnitude of the scaling is the ratio of the corresponding diagonal elements of w and vλ.m.m.vλ:

Equivalently, it is the ratio of the corresponding diagonal elements of wa and vλ.ma.ma.vλ:

Possible Issues  (1)

m is a 2×1000 random matrix:

The full singular value decomposition is very large because u is a 1000×1000 matrix:

The condensed singular value decomposition is much smaller:

It still contains sufficient information to reconstruct m:

Wolfram Research (2003), SingularValueDecomposition, Wolfram Language function, https://reference.wolfram.com/language/ref/SingularValueDecomposition.html (updated 2025).

Text

Wolfram Research (2003), SingularValueDecomposition, Wolfram Language function, https://reference.wolfram.com/language/ref/SingularValueDecomposition.html (updated 2025).

CMS

Wolfram Language. 2003. "SingularValueDecomposition." Wolfram Language & System Documentation Center. Wolfram Research. Last Modified 2025. https://reference.wolfram.com/language/ref/SingularValueDecomposition.html.

APA

Wolfram Language. (2003). SingularValueDecomposition. Wolfram Language & System Documentation Center. Retrieved from https://reference.wolfram.com/language/ref/SingularValueDecomposition.html

BibTeX

@misc{reference.wolfram_2025_singularvaluedecomposition, author="Wolfram Research", title="{SingularValueDecomposition}", year="2025", howpublished="\url{https://reference.wolfram.com/language/ref/SingularValueDecomposition.html}", note=[Accessed: 01-December-2025]}

BibLaTeX

@online{reference.wolfram_2025_singularvaluedecomposition, organization={Wolfram Research}, title={SingularValueDecomposition}, year={2025}, url={https://reference.wolfram.com/language/ref/SingularValueDecomposition.html}, note=[Accessed: 01-December-2025]}