Polar coding for Ring-LWE-based public key encryption

The ring learning with errors (RLWE) problem can be used to construct efficient post-quantum public key encryption schemes. An error distribution, normally a Gaussian-like distribution, is involved in the RLWE problem. In this work we focus on using polar codes to alleviate a natural trade-off present in RLWE public key encryption schemes; namely, we would like a wider error distribution to increase security, but a wider error distribution comes at the cost of an increased probability of decryption error. The motivation of this work is to improve the bit-security level by using wider error distribution while keeping the target decryption failure rate achievable. The approach we proposed in this work is twofold. Firstly, we formulate RLWE public key encryption as a channel model with some noise terms known by the decoder. This makes our approach distinguished from existing research of this kind in the literature which ignores these known terms. Secondly, we design polar codes for the derived channel model. Theoretically and numerically, we show the proposed modeling and polar coding scheme contributes to a considerable bit-security level improvement compared with NewHope, a submission to National Institute of Standards and Technology (NIST), with almost the same parameters. Moreover, polar encoding and decoding support isochronous implementations in the sense that the timings of associated operations are irrelevant to the sensitive information.