Newton-like Polynomial-Coded Distributed Computing for Numerical Stability

Newton-like Polynomial-Coded Distributed Computing for Numerical Stability

For coded distributed computing (CDC), polynomial code is one prevalent encoding method for CDC (called Poly-CDC). It suffers from poor numerical stability due to the Vandermonde matrix serving as the coefficient matrix which needs to be inverted, and whose condition number increases exponentially w...

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Bibliographic Details
Published in:Symmetry (Basel) Vol. 15; no. 7; p. 1372
Main Authors: Dai, Mingjun, Lai, Xiong, Tong, Yanli, Li, Bingchun
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-07-2023
Subjects:
coded distributed computing (CDC)
Computer networks
Design
Distributed processing
Mathematical analysis
Newton interpolation polynomial (NIP) encoding
Nodes
Numerical stability
Polynomials
Stability
symmetrical combination property
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Summary:For coded distributed computing (CDC), polynomial code is one prevalent encoding method for CDC (called Poly-CDC). It suffers from poor numerical stability due to the Vandermonde matrix serving as the coefficient matrix which needs to be inverted, and whose condition number increases exponentially with the size of the matrix or equivalently with the number of parallel worker nodes. To improve the numerical stability, especially for large networks, we propose a Newton-like polynomial code (NLPC)-based CDC (NLPC-CDC), with a design dedicated for both matrix–vector and matrix–matrix multiplications. The associated proof of the constructed code possesses a (n,k)-symmetrical combination property (CP), where symmetrical means the worker nodes have identical computation volume, CP means the k-symmetrical original computing tasks are encoded into n(n≥k)-symmetrically coded computing tasks, and the arbitrary k resulting from the n-coded computing tasks can recover the intended computing results. Extensive numerical studies verify the significant numerical stability improvement of our proposed NLPC-CDC over Poly-CDC.
ISSN:2073-8994
2073-8994
DOI:10.3390/sym15071372