Weight distribution of cosets of small codes with good dual properties

Abstract

The bilateral minimum distance of a binary linear code is the maximum d such that all nonzero codewords have weights between d and n-d. Let Q⊂ \0,1\n be a binary linear code whose dual has bilateral minimum distance at least d, where d is odd. Roughly speaking, we show that the average L∞-distance -- and consequently the L1-distance -- between the weight distribution of a random cosets of Q and the binomial distribution decays quickly as the bilateral minimum distance d of the dual of Q increases. For d = (1), it decays like n-(d). On the other d=(n) extreme, it decays like and e-(d). It follows that, almost all cosets of Q have weight distributions very close to the to the binomial distribution. In particular, we establish the following bounds. If the dual of Q has bilateral minimum distance at least d=2t+1, where t≥ 1 is an integer, then the average L∞-distance is at most \(en2t)t(2tn)t2 , 2 e-t10\. For the average L1-distance, we conclude the bound \(2t+1)(en2t)t (2tn)t2-1,2(n+1)e-t10\, which gives nontrivial results for t≥ 3. We given applications to the weight distribution of cosets of extended Hadamard codes and extended dual BCH codes. Our argument is based on Fourier analysis, linear programming, and polynomial approximation techniques.