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Empirical Orthogonal Functions

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All vectors are arranged in columns unless transposed. If computing var/cov 'by hand', you ... Interpretation* Propagating features. NAO example. Exercise: ENSO ... – PowerPoint PPT presentation

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Title: Empirical Orthogonal Functions


1
Empirical Orthogonal Functions
Andy Jacobson and Brad Holcombe July 2006
2
Variance and Covariance
  • Notes
  • E() is expectation (mean)
  • M is the number of obs
  • N is the number of stations (locations with
    data)
  • All vectors are arranged in columns unless
    transposed.
  • If computing var/cov by hand, you must remove
    the mean of the data at each station.
  • Degrees of freedom M are reduced by one because
    of the computation of the mean.
  • D is the data matrix
  • The spatial dimensions of your input data must
    be unwrapped 2-D grids must be laid out as a
    1-D row in D
  • C is the covariance matrix.

3
Eigenvalue Decomposition
  • Two covariate time series, x and y.
  • Generated from two uncorrelated random number
    sequences by multiplying by a specified
    covariance matrix.

4
Eigenvalue Decomposition
  • Notes
  • C is the covariance matrix
  • E is the matrix of eigenvectors
  • ? is the diagonal matrix of eigenvalues

5
Eigenvalue Decomposition
  • Notes
  • C is the covariance matrix
  • E is the matrix of eigenvectors
  • ? is the diagonal matrix of eigenvalues

6
Eigenvalue Decomposition
  • Notes
  • C is the covariance matrix
  • E is the matrix of eigenvectors
  • ? is the diagonal matrix of eigenvalues

7
Eigenvalue Decomposition
  • Notes
  • C is the covariance matrix
  • E is the matrix of eigenvectors
  • ? is the diagonal matrix of eigenvalues

8
Eigenvalue Decomposition
9
Eigenvalue Decomposition
  • Notes
  • C is the covariance matrix
  • E is the matrix of eigenvectors
  • ? is the diagonal matrix of eigenvalues

10
Eigenvalue Decomposition
  • Notes
  • C is the covariance matrix
  • E is the matrix of eigenvectors
  • ? is the diagonal matrix of eigenvalues

11
Eigenvalue Decomposition
  • Notes
  • C is the covariance matrix
  • E is the matrix of eigenvectors
  • ? is the diagonal matrix of eigenvalues

12
EOFs
  • Notes
  • EOF terminology is not well defined. Conflicting
    definitions are common in the literature.
  • The projection of each eigenvector onto the data
    gives a time series of scores.
  • A is the matrix of score time series and has
    dimensions M x N
  • Principal components often refers to the
    scores.
  • PCA, however, is sometimes taken to mean an
    eigen decomposition of the correlation matrix.
  • The observations from any given time can be
    recovered with a weighted sum of the eigenvector
    scores from that time (row)

13
EOF Examples
  1. Retrieving the magnitude and time series of two
    static patterns
  2. Effects of noise, missing data, and few data
  3. Interpretation
  4. Propagating features
  5. NAO example
  6. Exercise ENSO
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