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Independent Component Analysis

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Title: Independent Component Analysis


1
Independent Component Analysis Blind Source
Separation
  • Ata Kaban
  • The University of Birmingham

2
Overview
  • Today we learn about
  • The cocktail party problem -- called also blind
    source separation (BSS)
  • Independent Component Analysis (ICA) for solving
    BSS
  • Other applications of ICA / BSS
  • At an intuitive introductory practical level

3
A bit like
in the sense of having to find quantities that
are not observable directly
4
Signals, joint density
Joint density
Signals
Amplitude S1(t)
Amplitude S2(t)
time
marginal densities
5
Original signals (hidden sources) s1(t), s2(t),
s3(t), s4(t), t1T
6
The ICA model
xi(t) ai1s1(t) ai2s2(t)
ai3s3(t) ai4s4(t) Here,
i14. In vector-matrix notation, and dropping
index t, this is x A s
7
This is recorded by the microphones a linear
mixture of the sources xi(t) ai1s1(t)
ai2s2(t) ai3s3(t) ai4s4(t)
8
  • The coctail party problem
  • Called also Blind Source Separation (BSS) problem
  • Ill posed problem, unless assumptions are made!
  • The most common assumption is that source signals
    are statistically independent. This means that
    knowing the value of one of them does not give
    any information about the other.
  • The methods based on this assumption are called
    Independent Component Analysis methods. These are
    statistical techniques of decomposing a complex
    data set into independent parts.
  • It can be shown that under some reasonable
    conditions, if the ICA assumption holds, then the
    source signals can be recovered up to permutation
    and scaling.

Determine the source signals, given only the
mixtures
9
Recovered signals
10
Some further considerations
  • If we knew the mixing parameters aij then we
    would just need to solve a linear system of
    equations.
  • We know neither aij nor si.
  • ICA was initially developed to deal with problems
    closely related to the coctail party problem
  • Later it became evident that ICA has many other
    applications too. E.g. from electrical recordings
    of brain activity from different locations of the
    scalp (EEG signals) recover underlying components
    of brain activity

11
Illustration of ICA with 2 signals
a1
s2
x2
a2
a1
s1
x1
Original s
Mixed signals
12
Illustration of ICA with 2 signals
a1
x2
a2
a1
x1
Mixed signals
Step2 Rotatation
Step1 Sphering
13
Illustration of ICA with 2 signals
a1
s2
x2
a2
a1
s1
x1
Original s
Mixed signals
Step2 Rotatation
Step1 Sphering
14
Excluded case
There is one case when rotation doesnt matter.
This case cannot be solved by basic ICA.
Example of non-Gaussian density (-) vs.Gaussian
(-.) Seek non-Gaussian sources for two
reasons identifiability interestingness
Gaussians are not interesting since the
superposition of independent sources tends to be
Gaussian
when both densities are Gaussian
15
Computing the pre-processing steps for ICA
  • 0) Centring make the signals centred in zero
  • xi ? xi - Exi for each i
  • 1) Sphering make the signals uncorrelated. I.e.
    apply a transform V to x such that Cov(Vx)I //
    where Cov(y)EyyT denotes covariance matrix
  • VExxT-1/2 // can be done using sqrtm
    function in MatLab
  • x?Vx // for all t (indexes t dropped
    here)
  • // bold lowercase refers to column
    vector bold upper to matrix
  • Scope to make the remaining computations
    simpler. It is known that independent variables
    must be uncorrelated so this can be fulfilled
    before proceeding to the full ICA

16
Computing the rotation step
Aapo Hyvarinen (97)
  • Fixed Point Algorithm
  • Input X
  • Random init of W
  • Iterate until convergence
  • Output W, S

This is based on an the maximisation of an
objective function G(.) which contains an
approximate non-Gaussianity measure.
where g(.) is derivative of G(.),
W is the rotation transform sought
? is Lagrange multiplier to enforce that
W is an orthogonal transform i.e. a
rotation Solve by fixed point iterations The
effect of ? is an orthogonal de-correlation
  • The overall transform then to take X back to S is
    (WTV)
  • There are several g(.) options, each will work
    best in special cases. See FastICA sw / tut for
    details.

17
Application domains of ICA
  • Blind source separation (BellSejnowski, Te won
    Lee, Girolami, Hyvarinen, etc.)
  • Image denoising (Hyvarinen)
  • Medical signal processing fMRI, ECG, EEG
    (Mackeig)
  • Modelling of the hippocampus and visual cortex
    (Lorincz, Hyvarinen)
  • Feature extraction, face recognition (Marni
    Bartlett)
  • Compression, redundancy reduction
  • Watermarking (D Lowe)
  • Clustering (Girolami, Kolenda)
  • Time series analysis (Back, Valpola)
  • Topic extraction (Kolenda, Bingham, Kaban)
  • Scientific Data Mining (Kaban, etc)

18
Image denoising
Noisy image
Original image
Wiener filtering
ICA filtering
19
Clustering
In multi-variate data search for the direction
along of which the projection of the data is
maximally non-Gaussian has the most structure
20
Blind Separation of Information from Galaxy
Spectra
21
Decomposition using Physical Models
Decomposition using ICA
22
Summing Up
  • Assumption that the data consists of unknown
    components
  • Individual signals in a mix
  • topics in a text corpus
  • basis-galaxies
  • Trying to solve the inverse problem
  • Observing the superposition only
  • Recover components
  • Components often give simpler, clearer view of
    the data

23
Related resources
  • http//www.cis.hut.fi/projects/ica/cocktail/cockta
    il_en.cgiDemo and links to further info on ICA.
  • http//www.cis.hut.fi/projects/ica/fastica/code/dl
    code.shtmlICA software in MatLab.
  • http//www.cs.helsinki.fi/u/ahyvarin/papers/NN00ne
    w.pdf Comprehensive tutorial paper, slightly more
    technical.
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