Estimating the Sizes of Binary Error-Correcting Constrained Codes

In this paper, we study binary constrained codes that are resilient to bit-flip errors and erasures. In our first approach, we compute the sizes of constrained subcodes of linear codes. Since there exist well-known linear codes that achieve vanishing probabilities of error over the binary symmetric...

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Bibliographic Details
Published in:IEEE journal on selected areas in information theory 2023, Vol.4, p.144-158
Main Authors: Rameshwar, V. Arvind, Kashyap, Navin
Format: Article
Language:English
Subjects:
Algorithms
Binary codes
Block codes
Boolean functions
Codes
Combinatorial analysis
Constrained coding
Constraints
Error correction
Error correction codes
Fourier analysis
Fourier transforms
Information theory
Linear codes
Linear programming
linear programming bounds
Upper bound
Upper bounds
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Summary:In this paper, we study binary constrained codes that are resilient to bit-flip errors and erasures. In our first approach, we compute the sizes of constrained subcodes of linear codes. Since there exist well-known linear codes that achieve vanishing probabilities of error over the binary symmetric channel (which causes bit-flip errors) and the binary erasure channel, constrained subcodes of such linear codes are also resilient to random bit-flip errors and erasures. We employ a simple identity from the Fourier analysis of Boolean functions, which transforms the problem of counting constrained codewords of linear codes to a question about the structure of the dual code. We illustrate the utility of our method in providing explicit values or efficient algorithms for our counting problem, by showing that the Fourier transform of the indicator function of the constraint is computable, for different constraints. Our second approach is to obtain good upper bounds, using an extension of Delsarte's linear program (LP), on the largest sizes of constrained codes that can correct a fixed number of combinatorial errors or erasures. We observe that the numerical values of our LP-based upper bounds beat the generalized sphere packing bounds of Fazeli et al. (2015).
ISSN:2641-8770
2641-8770
DOI:10.1109/JSAIT.2023.3279113