Weighted ℓ_1 minimization for sparse recovery with prior information
Abstract
In this paper we study the compressed sensing problem of recovering a sparse signal from a system of underdetermined linear equations when we have prior information about the probability of each entry of the unknown signal being nonzero. In particular, we focus on a model where the entries of the unknown vector fall into two sets, each with a different probability of being nonzero. We propose a weighted ℓ_1 minimization recovery algorithm and analyze its performance using a Grassman angle approach. We compute explicitly the relationship between the system parameters (the weights, the number of measurements, the size of the two sets, the probabilities of being non-zero) so that an iid random Gaussian measurement matrix along with weighted ℓ_1 minimization recovers almost all such sparse signals with overwhelming probability as the problem dimension increases. This allows us to compute the optimal weights. We also provide simulations to demonstrate the advantages of the method over conventional ℓ_1 optimization.
Additional Information
© 2009 IEEE.Attached Files
Published - Khajehnejad2009p110872009_Ieee_International_Symposium_On_Information_Theory_Vols_1-_4.pdf
Submitted - 0901.2912.pdf
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Additional details
- Eprint ID
- 19442
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- CaltechAUTHORS:20100816-133504795
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2010-08-16Created from EPrint's datestamp field
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2021-11-08Created from EPrint's last_modified field