Title: Deconvolution,%20Deblurring%20and%20Restoration
1Deconvolution, Deblurring andRestoration
- T-61.182, Biomedical Image Analysis
- Seminar Presentation 14.4.2005
- Seppo Mattila Mika Pollari
2Overview (1/2)
- Linear space-invariant (LSI) restoration filters
- - Inverse filtering
- - Power spectrum equalization
- - Wiener filter
- - Constrained least-squares restoration
- - Metz filter
- Blind Deblurring
3Overview (2/2)
- Homomorphic Deconvolution
- Space-variant restoration
- Sectioned image restoration
- Adaptive-neighbourhood deblurring
- The Kalman filter
- Applications
- - Medical
- - Astronomical
4Introduction
- Find the best possible estimate of the original
unknown image from the degraded image. - One typical degradation process has a form
5Image Restoration General
- One has to have some a priori knowledge about the
degragation process. - Usually one needs 1) model for degragation, some
information from 2) original image and 3) noise. - Note! Eventhough one doesnt know the original
image some information such as power spectral
density (PSD) and autocorreletion function (ACF)
are easy to model.
6Linear-Space Invariant (LSI) Restoration Filters
- Assume linear and shift-invariant degrading
process - Random noise statistically indep.
of image-generating process - Possible to design LSI filters to
restore the image
7Inverse Filtering
- Consider degrading process in matrix form
- Given g and h, estimate f by minimising the
squared error between observed image (g) and
- where and are approximations of f and
g - Set derivative of ?2 to zero
(if noise present)
8Inverse Filtering Examples
- Works fine if no noise but...
- H(u,v) usually low-pass function.
- N(u,v) uniform over whole spectrum.
- High-freq. Noise amplified!!
0.4x
0.2x
9Power Spectrum Equalization (PSE)
- Want to find linear transform L such that
- Power spectral density (PSD) FT(Autocorrelation
function)
i.e.
. . .
10The Wiener Filter (1/2)
- Degradation model
- Assumtions Image and noise are
second-order-stationary random processes and they
are statistically independent - Optimal mean-square error (MSE) criterion Find
Wiener filter (L) which minimize MSE
11The Wiener Filter (2/2)
- Minimizing the criterion we end up to optimal
Wiener filter. - The Wiener filter depends on the autocorrelation
function (ACF) of the image and noise (This is no
problem). - In general ACFs are easy to estimate.
12Comparison of Inverse Filter, PSE, and Wiener
Filter
13Constrained Least-squares Restoration
- Minimise with constraint
where L is a linear filter
operator - Similar to Wiener filter but does not require the
PSDs of the image and noise to be known - The mean and variance of the noise needed to set
optimally. If 0 inverse filter
. . .
14The Metz Filter
- Modification to inverse filter.
- Supress the high frequency noise instead of
amplyfying it. - Select factor so that mean-square error (MSE)
between ideal and filtered image is minimized.
15Motion Deblurring Simple Model
- Assume simple in plane movement during the
exposure - Either PSF or MTF is needed for restoration
16Blind Deblurring
- Definition of deblurring.
- Blind deblurring models of PSF and noise are not
known cannot be estimated separately. - Degragated image (in spectral domain) consist
some information of PSF and noise but in combined
form.
17Method 1 Extension to PSE
- Broke image to M x M size segment where M is
larger than dimensions of PSF then - Average of PSD of these segments tend toward the
true signal and noise PSD - This is combined information of blur function
and noise which is needed in PSE - Finaly, only PSD of image is needed
18Extension to PSE Cont...
19Method 2 Iterative Blind Deblurring
- Assumptation MTF of PSF has zero phase.
- Idea blur function affects in PSD but phase
information preserves original information from
edges.
20Iterative Blind Deblurring Cont...
- Fourier transform of restored image is
- Note that smoothing operator S has small effect
to smooth functions (PSF). This leads to
iterative update rule
21Examples of Iterative Blind Deblurring
22Homomorphic deconvolution
- Start from
- Convert convolution operation to addition
- Complex cepstrum
- Complex cepstra related
- Practical application, however, not simple...
23Steps involved in deconvolution using complex
cepstrum
24Space-variant Image Restoration
- So far we have assumed that images are spatially
(and temporaly) stationary - This is (generally) not true at the best images
are locally stationary - Techniques to overcome this problem
- Sectioned image restoration
- Adaptive neighbourhood deblurring
- The Kalman filter (the most elegant approach)
25Sectioned Image Restoration
- Divide image into small P x P rectangular,
presumably stationary segments. - Centre each segment in a region, and pad the
surrounding with the mean value. - For each segment apply separately image
restoration (e.g. PSE or wiener).
26Adaptive-neighborhood deblurring (AND)
- Grow adaptive neighborhood regions
- Apply 2D Hamming window to each region
- Estimate the noise spectrum
Pixel locations within the region
Centered on (m,n)
A is a freq. domain scale factor that depends on
the spectral characterisics of the region grown
etc.
27AND segmentation
28Adaptive-neighborhood deblurring (AND) Cont
- Frequency-domain estimate of the uncorrupted
adaptive-neighborhood region - Obtain estimate for deblurred adaptive
neigborhood region m,n(p,q) by FT-1 - Run for every pixel in the input image g(x,y)
Deblurred image
29Comparison of Sectioned and AND-technique
30Kalman Filter
- Kalman filter is a set of mathematical equations.
- Filter provides recursive way to estimate the
state of the process (in non-stationary
environment), so that mean of squared errors is
minimized (MMSE). - Kalman filter enables prediction, filtering, and
smoothing.
31Kalman Filter State-Space
- Process Eq.
- Observation Eq.
- Innovation process
32Kalman Filter in a Nutshell (1/2)
- Data observations are available
- System parameters are known
- a(n1,n), h(n), and the ACF of driving and
observation noise - Initial conditions
- Recursion
33Kalman Filter in a Nutshell (2/2)
- Compute the Kalman gain K(n)
- Obtain the innovation process
- Update
- Compute the ACF of filtered state error
- Compute the ACF of predicted state error
34Wiener Filter Restoration of Digital Radiography
35Astronomical applications
- Images blurred by atmospheric turbulence
- Observing above the atmosphere very expensive
(HST) - Improve the ground-based resolution by
- Suitable sites for the observatory (_at_ 4 km
height) - Real time Adaptive optics correction
- Deconvolution
36Point Spread Function (PSF) in Astronomy
Iobserved Ireal ?PSF
- Easy to measure and model from several stars
usually present in astro-images - Determines the spatial resolution of an image
- Commonly used for image matching and
deconvolution
Ideal PSF if no atmosphere FWHM 1.22x?/D
Atmospheric turbulence broadens the PSF
Gaussian PSF with FWHM 1"
lt 0.1" (8m telescope)
37Richardson-Lucy deconvolution
- Used in both fields astronomy medical imaging
- Start from Bayes's theorem, end up with
- Takes into account statistical fluctuations in
the signal, therefore can reconstruct noisy
images! - In astronomy the PSF is known accurately
- From an initial guess f0(x) iterate until converge
38Astro-examples
Observed PSF
Inverse filter Richardson-Lucy