# The blurring kernel of a low-quality camera

I am doing some image enhancement experiments so I take photos from my cheap camera. The camera has mosaic artifacts and all images look like grid. I think pillbox (out-of-focus) kernel and Gaussian kernel would not be the best candidates. Any suggestions?

EDIT:
Sample

I suspect this cannot be done via a constant kernel, because the effects on pixels are not the same (so there are "grids").

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Maybe a better idea is to do some anti-aliasing jobs and then apply blurring kernels mentioned above. –  ziyuang May 12 '11 at 12:50
Is it possible that those are just plain old JPEG artifacts? The blocks seem to be 8x8. –  Joachim Sauer May 12 '11 at 13:01
And yeah, that does look like plain jpeg artefact. –  James May 12 '11 at 13:04

## 1 Answer

The effects are non linear. (And probably non-stationary), so you cannot simply invert the convolution and enhance the image -- if you could, the camera chip would do it on-board.

The best way to work out what the convolution is (or at least an approximation to it) might be to take photos of known patterns, compute, and working in 2D frequency/laplace domain divide the resulting spectra to get a linear approximation to the filter.

I suspect that the convolution you discover by doing this will be very context dependant -- so the best way to enhance an image might be to divide it into tiles, classify each region of the image as belonging to a different set (for each of which you could work out a different linear approximation to the convolution, based on test data), and then deconvolve each separately.

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Cool, @Autopulated. But I am not quite sure how to "divide the resulting spectra to get a linear approximation to the filter", can you offer more clues? –  ziyuang May 12 '11 at 15:55
If you take 2D Fourier transforms of your data, convolution in the spatial domain is equivalent to multiplication in the frequency domain, so you can do: `deconvolved real data = IFFT(FFT(real data) x FFT(test patch)/FFT(test patch photo))` where FFT stands for 2D Fourier transform, IFFT for the 2D inverse Fourier transform. –  James May 12 '11 at 17:10
In my experience, dividing in the frequency domain is very prone to errors due to additive noise. I've found a "best-fit" approach works much better in real-world problems like the one described. See my question and answer for more details. –  Stav Dec 31 '13 at 10:26