Off-the-Grid Recovery of Piecewise Constant Images from Few Fourier Samples
October 01, 2015 Β· Declared Dead Β· π SIAM Journal of Imaging Sciences
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Authors
Greg Ongie, Mathews Jacob
arXiv ID
1510.00384
Category
cs.CV: Computer Vision
Citations
124
Venue
SIAM Journal of Imaging Sciences
Last Checked
4 months ago
Abstract
We introduce a method to recover a continuous domain representation of a piecewise constant two-dimensional image from few low-pass Fourier samples. Assuming the edge set of the image is localized to the zero set of a trigonometric polynomial, we show the Fourier coefficients of the partial derivatives of the image satisfy a linear annihilation relation. We present necessary and sufficient conditions for unique recovery of the image from finite low-pass Fourier samples using the annihilation relation. We also propose a practical two-stage recovery algorithm which is robust to model-mismatch and noise. In the first stage we estimate a continuous domain representation of the edge set of the image. In the second stage we perform an extrapolation in Fourier domain by a least squares two-dimensional linear prediction, which recovers the exact Fourier coefficients of the underlying image. We demonstrate our algorithm on the super-resolution recovery of MRI phantoms and real MRI data from low-pass Fourier samples, which shows benefits over standard approaches for single-image super-resolution MRI.
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