Biorthogonal decomposition: Difference between revisions

Revision as of 11:49, 30 April 2010

The Biorthogonal Decomposition (BOD, also known as Proper Orthogonal Decomposition, POD^[1]) applies to the analysis of multipoint measurements

Y(i,j)\,

where i=1,...,N is a temporal index and j=1,...,M a spatial index (typically). The time traces Y(i,j) for fixed j are usually sampled at a fixed rate; however the measurement locations x(j) need not be ordered in any specific way.

The BOD decomposes the data matrix as follows:

Y(i,j)=\sum _{k}\lambda _{k}\psi _{k}(i)\phi _{k}(j),\,

where ψ_k is a 'chrono' (a temporal function) and φ_k a 'topo' (a spatial or detector-dependent function), such that the chronos and topos satisfy the following orthogonality relation

\sum _{i}{\psi _{k}(i)\psi _{l}(i)}=\sum _{j}{\phi _{k}(j)\phi _{l}(j)}=\delta _{kl}.\,

The combination chrono/topo at a given k, ψ_k(i) φ_k(j), is called a spatio-temporal 'mode' of the fluctuating system, and is constructed from the data matrix without any prejudice regarding the mode shape. The λ_k are the eigenvalues (sorted in decreasing order), where k=1,...,min(N,M), and directly represent the square root of the fluctuation energy contained in the corresponding mode. This decomposition is achieved using a standard Singular value decomposition of the data matrix Y(i,j). Thus, the oscillations of the spatiotemporal fluctuating field are represented by means of a very small number of spatio-temporal modes that are constructed from the data themselves, without prejudice regarding the mode shape. ^[2]

A limitation of the technique is that it assumes space-time separability. This is not always the most appropriate assumption: e.g., travelling waves have a structure such as cos(kx-ωt); however, most propagating waves can still be recognised clearly by their distinct footprint in the biorthogonal modes (provided there are not too many): a travelling wave will produce a pair of modes with similar amplitude and a 90° phase difference.

Relation with signal correlation

The correlation between signals j₁ and j₂ is defined as:

C(j_{1},j_{2})=\sum _{i}{Y(i,j_{1})Y(i,j_{2})},\!

Using the above expansion of Y and the orthogonality relations, it is easy to show that the topos φ_k are the eigenvectors of the correlation matrix C, and λ_k² the corresponding eigenvalues.

References

↑ P. Holmes, J.L. Lumley, and G. Berkooz, Turbulence, Coherent Structures, Dynamical Systems and Symmetry, Cambridge University Press (1996) ISBN 0521634199
↑ T. Dudok de Wit et al., The biorthogonal decomposition as a tool for investigating fluctuations in plasmas, Phys. Plasmas 1 (1994) 3288

[1] P. Holmes, J.L. Lumley, and G. Berkooz, Turbulence, Coherent Structures, Dynamical Systems and Symmetry, Cambridge University Press (1996) ISBN 0521634199

[2] T. Dudok de Wit et al., The biorthogonal decomposition as a tool for investigating fluctuations in plasmas, Phys. Plasmas 1 (1994) 3288

[1]

[2]

Revision as of 20:58, 19 March 2010 (view source) Admin (talk \| contribs) (→‎See also) ← Older edit		Revision as of 11:49, 30 April 2010 (view source) Admin (talk \| contribs) No edit summary Newer edit →
Line 1:		Line 1:
	The Biorthogonal Decomposition (BOD, also known as Proper Orthogonal Decomposition, POD) applies to the analysis of multipoint measurements		The Biorthogonal Decomposition (BOD, also known as Proper Orthogonal Decomposition, POD<ref>P. Holmes, J.L. Lumley, and G. Berkooz, ''Turbulence, Coherent Structures, Dynamical Systems and Symmetry'', Cambridge University Press (1996) ISBN 0521634199</ref>) applies to the analysis of multipoint measurements

	:<math>Y(i,j)\,</math>		:<math>Y(i,j)\,</math>

Biorthogonal decomposition: Difference between revisions

Revision as of 11:49, 30 April 2010

Relation with signal correlation

See also

References

Navigation menu

Search