A New Class of Linear Codes

Abstract

Let n be a prime power, r be a prime with r n-1, and ∈ (0,1/2). Using the theory of multiplicative character sums and superelliptic curves, we construct new codes over Fr having length n, relative distance (r-1)/r+O(n-) and rate n-1/2-. When r=2, our binary codes have exponential size when compared to all previously known families of linear and non-linear codes with relative distance asymptotic to 1/2, such as Delsarte--Goethals codes. Moreover, concatenating with a Reed-Solomon code we get a family of codes of length n and rate n-1/(2n+2)-2/(n+1)+O(n-1/(n+1)) and relative distance 1/2+O(n-). This shows that, for a fixed length, the rate of the concatenation suggested by Kschischang and Tasbihi (2024) of a Reed-Solomon and a Reed-Muller code can be made an order of magnitude smaller than a concatenation of a Reed-Solomon with a large dimensional Shadow code, while still keeping the regime of relative distance 1/2. Finally, we show that the square of a Shadow code behaves like a random code and the Shadow code itself has a decoding algorithm, which suggest that such class of codes has the potential to be interesting for cryptographic applications.