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Fixed-point iterative linear inverse solver with extended precision

Zheyuan Zhu, Andrew B. Klein, Guifang Li, Sean Pang

2023Scientific Reports15 citationsDOIOpen Access PDF

Abstract

Solving linear systems, often accomplished by iterative algorithms, is a ubiquitous task in science and engineering. To accommodate the dynamic range and precision requirements, these iterative solvers are carried out on floating-point processing units, which are not efficient in handling large-scale matrix multiplications and inversions. Low-precision, fixed-point digital or analog processors consume only a fraction of the energy per operation than their floating-point counterparts, yet their current usages exclude iterative solvers due to the cumulative computational errors arising from fixed-point arithmetic. In this work, we show that for a simple iterative algorithm, such as Richardson iteration, using a fixed-point processor can provide the same convergence rate and achieve solutions beyond its native precision when combined with residual iteration. These results indicate that power-efficient computing platforms consisting of analog computing devices can be used to solve a broad range of problems without compromising the speed or precision.

Topics & Concepts

Computer scienceSolverIterative methodFixed pointAlgorithmFloating pointRange (aeronautics)Convergence (economics)Fixed-point arithmeticMathematical optimizationComputational scienceMathematicsEconomic growthMathematical analysisMaterials scienceEconomicsProgramming languageComposite materialNeural Networks and Reservoir ComputingNumerical Methods and AlgorithmsSparse and Compressive Sensing Techniques
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