AI Coding: Learning to Construct Error Correction Codes
January 17, 2019 Β· Declared Dead Β· π IEEE Transactions on Communications
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Authors
Lingchen Huang, Huazi Zhang, Rong Li, Yiqun Ge, Jun Wang
arXiv ID
1901.05719
Category
cs.IT: Information Theory
Citations
92
Venue
IEEE Transactions on Communications
Last Checked
4 months ago
Abstract
In this paper, we investigate an artificial-intelligence (AI) driven approach to design error correction codes (ECC). Classic error correction code was designed upon coding theory that typically defines code properties (e.g., hamming distance, subchannel reliability, etc.) to reflect code performance. Its code design is to optimize code properties. However, an AI-driven approach doesn't necessarily rely on coding theory any longer. Specifically, we propose a constructor-evaluator framework, in which the code constructor is realized by AI algorithms and the code evaluator provides code performance metric measurements. The code constructor keeps improving the code construction to maximize code performance that is evaluated by the code evaluator. As examples, we construct linear block codes and polar codes with reinforcement learning (RL) and evolutionary algorithms. The results show that comparable code performance can be achieved with respect to the existing codes. It is noteworthy that our method can provide superior performances where existing classic constructions fail to achieve optimum for a specific decoder (e.g., list decoding for polar codes).
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