Near-linear convergence of the Random Osborne algorithm for Matrix Balancing

We revisit Matrix Balancing, a pre-conditioning task used ubiquitously for computing eigenvalues and matrix exponentials. Since 1960, Osborne’s algorithm has been the practitioners’ algorithm of choice, and is now implemented in most numerical software packages. However, the theoretical properties o...

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Vydáno v:Mathematical programming Ročník 198; číslo 1; s. 363 - 397
Hlavní autoři: Altschuler, Jason M., Parrilo, Pablo A.
Médium: Journal Article
Jazyk:angličtina
Vydáno: Berlin/Heidelberg Springer Berlin Heidelberg 01.03.2023
Springer
Témata:
Algorithms
Analysis
Calculus of Variations and Optimal Control; Optimization
Combinatorics
Full Length Paper
Mathematical and Computational Physics
Mathematical Methods in Physics
Mathematics
Mathematics and Statistics
Mathematics of Computing
Numerical Analysis
Theoretical
65F50
Random Osborne
Convex optimization
Near-linear time
90C25
Osborne’s algorithm
Coordinate descent
65F08
Matrix Balancing
ISSN:0025-5610, 1436-4646
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Popis
Shrnutí:We revisit Matrix Balancing, a pre-conditioning task used ubiquitously for computing eigenvalues and matrix exponentials. Since 1960, Osborne’s algorithm has been the practitioners’ algorithm of choice, and is now implemented in most numerical software packages. However, the theoretical properties of Osborne’s algorithm are not well understood. Here, we show that a simple random variant of Osborne’s algorithm converges in near-linear time in the input sparsity. Specifically, it balances K ∈ R ≥ 0 n × n after O ( m ε - 2 log κ ) arithmetic operations in expectation and with high probability, where m is the number of nonzeros in K , ε is the ℓ 1 accuracy, and κ = ∑ ij K ij / ( min i j : K ij ≠ 0 K ij ) measures the conditioning of K . Previous work had established near-linear runtimes either only for ℓ 2 accuracy (a weaker criterion which is less relevant for applications), or through an entirely different algorithm based on (currently) impractical Laplacian solvers. We further show that if the graph with adjacency matrix K is moderately connected—e.g., if K has at least one positive row/column pair—then Osborne’s algorithm initially converges exponentially fast, yielding an improved runtime O ( m ε - 1 log κ ) . We also address numerical precision issues by showing that these runtime bounds still hold when using O ( log ( n κ / ε ) ) -bit numbers. Our results are established through an intuitive potential argument that leverages a convex optimization perspective of Osborne’s algorithm, and relates the per-iteration progress to the current imbalance as measured in Hellinger distance. Unlike previous analyses, we critically exploit log-convexity of the potential. Notably, our analysis extends to other variants of Osborne’s algorithm: along the way, we also establish significantly improved runtime bounds for cyclic, greedy, and parallelized variants of Osborne’s algorithm.
ISSN:0025-5610
1436-4646
DOI:10.1007/s10107-022-01825-4