561 research outputs found
RSP-Based Analysis for Sparsest and Least -Norm Solutions to Underdetermined Linear Systems
Recently, the worse-case analysis, probabilistic analysis and empirical
justification have been employed to address the fundamental question: When does
-minimization find the sparsest solution to an underdetermined linear
system? In this paper, a deterministic analysis, rooted in the classic linear
programming theory, is carried out to further address this question. We first
identify a necessary and sufficient condition for the uniqueness of least
-norm solutions to linear systems. From this condition, we deduce that
a sparsest solution coincides with the unique least -norm solution to a
linear system if and only if the so-called \emph{range space property} (RSP)
holds at this solution. This yields a broad understanding of the relationship
between - and -minimization problems. Our analysis indicates
that the RSP truly lies at the heart of the relationship between these two
problems. Through RSP-based analysis, several important questions in this field
can be largely addressed. For instance, how to efficiently interpret the gap
between the current theory and the actual numerical performance of
-minimization by a deterministic analysis, and if a linear system has
multiple sparsest solutions, when does -minimization guarantee to find
one of them? Moreover, new matrix properties (such as the \emph{RSP of order
} and the \emph{Weak-RSP of order }) are introduced in this paper, and a
new theory for sparse signal recovery based on the RSP of order is
established
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