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Angles between flats

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The concept of angles between lines (in the plane or in space), between two planes (dihedral angle) or between a line and a plane can be generalized to arbitrary dimensions. This generalization was first discussed by Camille Jordan.[1] For any pair of flats in a Euclidean space of arbitrary dimension one can define a set of mutual angles which are invariant under isometric transformation of the Euclidean space. If the flats do not intersect, their shortest distance is one more invariant.[1] These angles are called canonical[2] or principal.[3] The concept of angles can be generalized to pairs of flats in a finite-dimensional inner product space over the complex numbers.

Jordan's definition

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Let and be flats of dimensions and in the -dimensional Euclidean space . By definition, a translation of or does not alter their mutual angles. If and do not intersect, they will do so upon any translation of which maps some point in to some point in . It can therefore be assumed without loss of generality that and intersect.

Jordan shows that Cartesian coordinates in can then be defined such that and are described, respectively, by the sets of equations

and

with . Jordan calls these coordinates canonical. By definition, the angles are the angles between and .

The non-negative integers are constrained by

For these equations to determine the five non-negative integers completely, besides the dimensions and and the number of angles , the non-negative integer must be given. This is the number of coordinates , whose corresponding axes are those lying entirely within both and . The integer is thus the dimension of . The set of angles may be supplemented with angles to indicate that has that dimension.

Jordan's proof applies essentially unaltered when is replaced with the -dimensional inner product space over the complex numbers. (For angles between subspaces, the generalization to is discussed by Galántai and Hegedũs in terms of the below variational characterization.[4])[1]

Angles between subspaces

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Now let and be subspaces of the -dimensional inner product space over the real or complex numbers. Geometrically, and are flats, so Jordan's definition of mutual angles applies. When for any canonical coordinate the symbol denotes the unit vector of the axis, the vectors form an orthonormal basis for and the vectors form an orthonormal basis for , where

Being related to canonical coordinates, these basic vectors may be called canonical.

When denote the canonical basic vectors for and the canonical basic vectors for then the inner product vanishes for any pair of and except the following ones.

With the above ordering of the basic vectors, the matrix of the inner products is thus diagonal. In other words, if and are arbitrary orthonormal bases in and then the real, orthogonal or unitary transformations from the basis to the basis and from the basis to the basis realize a singular value decomposition of the matrix of inner products . The diagonal matrix elements are the singular values of the latter matrix. By the uniqueness of the singular value decomposition, the vectors are then unique up to a real, orthogonal or unitary transformation among them, and the vectors and (and hence ) are unique up to equal real, orthogonal or unitary transformations applied simultaneously to the sets of the vectors associated with a common value of and to the corresponding sets of vectors (and hence to the corresponding sets of ).

A singular value can be interpreted as corresponding to the angles introduced above and associated with and a singular value can be interpreted as corresponding to right angles between the orthogonal spaces and , where superscript denotes the orthogonal complement.

Variational characterization

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The variational characterization of singular values and vectors implies as a special case a variational characterization of the angles between subspaces and their associated canonical vectors. This characterization includes the angles and introduced above and orders the angles by increasing value. It can be given the form of the below alternative definition. In this context, it is customary to talk of principal angles and vectors.[3]

Definition

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Let be an inner product space. Given two subspaces with , there exists then a sequence of angles called the principal angles, the first one defined as

where is the inner product and the induced norm. The vectors and are the corresponding principal vectors.

The other principal angles and vectors are then defined recursively via

This means that the principal angles form a set of minimized angles between the two subspaces, and the principal vectors in each subspace are orthogonal to each other.

Examples

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Geometric example

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Geometrically, subspaces are flats (points, lines, planes etc.) that include the origin, thus any two subspaces intersect at least in the origin. Two two-dimensional subspaces and generate a set of two angles. In a three-dimensional Euclidean space, the subspaces and are either identical, or their intersection forms a line. In the former case, both . In the latter case, only , where vectors and are on the line of the intersection and have the same direction. The angle will be the angle between the subspaces and in the orthogonal complement to . Imagining the angle between two planes in 3D, one intuitively thinks of the largest angle, .

Algebraic example

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In 4-dimensional real coordinate space R4, let the two-dimensional subspace be spanned by and , and let the two-dimensional subspace be spanned by and with some real and such that . Then and are, in fact, the pair of principal vectors corresponding to the angle with , and and are the principal vectors corresponding to the angle with

To construct a pair of subspaces with any given set of angles in a (or larger) dimensional Euclidean space, take a subspace with an orthonormal basis and complete it to an orthonormal basis of the Euclidean space, where . Then, an orthonormal basis of the other subspace is, e.g.,

Basic properties

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  • If the largest angle is zero, one subspace is a subset of the other.
  • If the largest angle is , there is at least one vector in one subspace perpendicular to the other subspace.
  • If the smallest angle is zero, the subspaces intersect at least in a line.
  • If the smallest angle is , the subspaces are orthogonal.
  • The number of angles equal to zero is the dimension of the space where the two subspaces intersect.

Advanced properties

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  • Non-trivial (different from and [5]) angles between two subspaces are the same as the non-trivial angles between their orthogonal complements.[6][7]
  • Non-trivial angles between the subspaces and and the corresponding non-trivial angles between the subspaces and sum up to .[6][7]
  • The angles between subspaces satisfy the triangle inequality in terms of majorization and thus can be used to define a distance on the set of all subspaces turning the set into a metric space.[8]
  • The sine of the angles between subspaces satisfy the triangle inequality in terms of majorization and thus can be used to define a distance on the set of all subspaces turning the set into a metric space.[6] For example, the sine of the largest angle is known as a gap between subspaces.[9]

Extensions

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The notion of the angles and some of the variational properties can be naturally extended to arbitrary inner products[10] and subspaces with infinite dimensions.[7]

Computation

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Historically, the principal angles and vectors first appear in the context of canonical correlation and were originally computed using SVD of corresponding covariance matrices. However, as first noticed in,[3] the canonical correlation is related to the cosine of the principal angles, which is ill-conditioned for small angles, leading to very inaccurate computation of highly correlated principal vectors in finite precision computer arithmetic. The sine-based algorithm[3] fixes this issue, but creates a new problem of very inaccurate computation of highly uncorrelated principal vectors, since the sine function is ill-conditioned for angles close to π/2. To produce accurate principal vectors in computer arithmetic for the full range of the principal angles, the combined technique[10] first compute all principal angles and vectors using the classical cosine-based approach, and then recomputes the principal angles smaller than π/4 and the corresponding principal vectors using the sine-based approach.[3] The combined technique[10] is implemented in open-source libraries Octave[11] and SciPy[12] and contributed [13] and [14] to MATLAB.

See also

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References

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  1. ^ a b c Jordan, Camille (1875). "Essai sur la géométrie à dimensions". Bulletin de la Société Mathématique de France. 3: 103–174. doi:10.24033/bsmf.90.
  2. ^ Afriat, S. N. (1957). "Orthogonal and oblique projectors and the characterization of pairs of vector spaces". Mathematical Proceedings of the Cambridge Philosophical Society. 53 (4): 800–816. doi:10.1017/S0305004100032916. S2CID 122049149.
  3. ^ a b c d e Björck, Å.; Golub, G. H. (1973). "Numerical Methods for Computing Angles Between Linear Subspaces". Mathematics of Computation. 27 (123): 579–594. doi:10.2307/2005662. JSTOR 2005662.
  4. ^ Galántai, A.; Hegedũs, Cs. J. (2006). "Jordan's principal angles in complex vector spaces". Numerical Linear Algebra with Applications. 13 (7): 589–598. CiteSeerX 10.1.1.329.7525. doi:10.1002/nla.491. S2CID 13107400.
  5. ^ Halmos, P.R. (1969), "Two subspaces", Transactions of the American Mathematical Society, 144: 381–389, doi:10.1090/S0002-9947-1969-0251519-5
  6. ^ a b c Knyazev, A.V.; Argentati, M.E. (2006), "Majorization for Changes in Angles Between Subspaces, Ritz Values, and Graph Laplacian Spectra", SIAM Journal on Matrix Analysis and Applications, 29 (1): 15–32, CiteSeerX 10.1.1.331.9770, doi:10.1137/060649070, S2CID 16987402
  7. ^ a b c Knyazev, A.V.; Jujunashvili, A.; Argentati, M.E. (2010), "Angles between infinite dimensional subspaces with applications to the Rayleigh–Ritz and alternating projectors methods", Journal of Functional Analysis, 259 (6): 1323–1345, arXiv:0705.1023, doi:10.1016/j.jfa.2010.05.018, S2CID 5570062
  8. ^ Qiu, L.; Zhang, Y.; Li, C.-K. (2005), "Unitarily invariant metrics on the Grassmann space" (PDF), SIAM Journal on Matrix Analysis and Applications, 27 (2): 507–531, doi:10.1137/040607605
  9. ^ Kato, D.T. (1996), Perturbation Theory for Linear Operators, Springer, New York
  10. ^ a b c Knyazev, A.V.; Argentati, M.E. (2002), "Principal Angles between Subspaces in an A-Based Scalar Product: Algorithms and Perturbation Estimates", SIAM Journal on Scientific Computing, 23 (6): 2009–2041, Bibcode:2002SJSC...23.2008K, CiteSeerX 10.1.1.73.2914, doi:10.1137/S1064827500377332
  11. ^ Octave function subspace
  12. ^ SciPy linear-algebra function subspace_angles
  13. ^ MATLAB FileExchange function subspace
  14. ^ MATLAB FileExchange function subspacea