1 / 17

Sparse Signal Reconstruction Using FOCUSS

Sparse Signal Reconstruction Using FOCUSS. Yan Chen. References. Irina F. Gorodnitsky and Bhaskar D. Rao, “Sparse Signal Reconstruction from Limited Data Using FOCUSS: A Re-weighted Minimum Norm Algorithm”, IEEE Trans. On Signal Processing, 1997.

idona-cobb
Download Presentation

Sparse Signal Reconstruction Using FOCUSS

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Sparse Signal Reconstruction Using FOCUSS Yan Chen

  2. References • Irina F. Gorodnitsky and Bhaskar D. Rao, “Sparse Signal Reconstruction from Limited Data Using FOCUSS: A Re-weighted Minimum Norm Algorithm”, IEEE Trans. On Signal Processing, 1997. • Hong Jung and Jong Chul Ye, “Improved k-t BLAST and k-t SENSE using FOCUSS”, Phys. Med. Biol., 2007. • Michael Lustig, David L. Donoho, Juan M. Santos, and John M. Pauly, “Compressed Sensing MRI”, IEEE Signal Processing Magazine, 2008.

  3. Outline • Problem Formulation • Uniqueness Conditions for Sparse Solutions • FOCUSS • FOCUSS vs. CS: similarities and differences • Conclusions

  4. Problem Formulation • The sparse signal reconstruction problem can be formulated as finding the sparse signal such that where is a mxn (m<n) matrix, is the observed data. • There are infinitely many solutions. And the infinite set of solutions can be expressed as: where is the minimum norm solution, and is any vector in the null space of

  5. Unique Representation Property (URP) • A system is said to have the URP if any m columns of the transform matrix are linearly independent.

  6. Uniqueness Conditions for Sparse Solutions • Theorem 1: Given a linear system satisfying the URP, which has a k<m/2-dimensional solution, there can be no other solution with dimension less than r=m-k+1.

  7. Uniqueness Conditions for Sparse Solutions • Corollary 1: A linear system satisfying the URP can have at most one solution of dimension less than m/2. This solution is the maximally sparse solution.

  8. Uniqueness Conditions for Sparse Solutions • Corollary 2: For the system satisfying the URP, the real signal can always be found as the unique maximally sparse solution when the number of the data samples m exceeds the signal dimension by a factor of 2. In this case, if a solution with dimension less than m/2 is found, it is guaranteed to represent the real signal.

  9. Minimum norm solution • The minimum norm solution is unique and found by assuming the minimum L2-norm on the solution. It can be computed by: where is the pseudo-inverse of . But it does not provide sparse solutions.

  10. L1-norm Minimization • To produce sparse reconstruction, L1-norm minimization is used: • If is in the gradient domain, the object function is the Total Variation (TV) norm. Even if is not in the gradient domain, it is often useful to include a TV penalty as well, which seek sparsity both in the transform domain and the gradient domain. • However, cartoon-like artifacts would be introduced!!

  11. FOCUSS: FOcal Underdetermined System Solver (1) • Instead of directly minimizing L2-norm of , let us consider the following optimization problem: where is the solution of the following constrained minimization problem: • The unique solution is given by: The novelty of FOCUSS is that the weighting matrix is updated using the previous solution.

  12. FOCUSS: FOcal Underdetermined System Solver (2) • More specifically, if the (n-1)-th iteration of the estimate is given by: • Then, the n-th iteration of FOCUSS can be calculated:

  13. FOCUSS: FOcal Underdetermined System Solver (3) • FOCUSS starts by finding a non-sparse low resolution estimate to initialize the weighting matrix. • Then, the solution is pruned to a sparse signal by scaling the entries of the current solution by those of the solution of previous iterations. • Once some entries of the previous solution become zero, these entries are fixed to zero. Therefore, a sparser solution can be found with more iterations.

  14. FOCUSS vs. CS • Consider the n-th FOCUSS estimate: • Set p=0.5, then: The FOCUSS solution is asymptotically equivalent to the L1-minimization solution when p=0.5.

  15. FOCUSS vs. CS • L1-norm minimization • Sparseness constraint is explicitly involved in the cost function. • No initial estimate. • Annoying visual artifacts may be introduced due to the hard sparseness constraint, especially when TV regularization is used. • L2-norm minimization • Sparseness constraint is implicitly involved in the cost function. • Initial estimate is needed. • Visual quality is good since non-zero values are gradually suppressed. More: complexity, training data (prior information), the number of samples.

  16. Conclusions • We introduced a sparse signal reconstruction method-FOCUSS. • We compared FOCUSS with CS, and showed the similarities and differences between them. • FOCUSS is a nice fit to the applications such as dynamic MRI, where a good initial estimate is available.

  17. Thanks! • Questions?

More Related