On deep holes of generalized projective Reed-Solomon codes

Abstract

Determining deep holes is an important topic in decoding Reed-Solomon codes. Let l 1 be an integer and a1,…,al be arbitrarily given l distinct elements of the finite field Fq of q elements with the odd prime number p as its characteristic. Let D= Fq\a1,…,al\ and k be an integer such that 2 k q-l-1. In this paper, we study the deep holes of generalized projective Reed-Solomon code GPRSq(D, k) of length q-l+1 and dimension k over Fq. For any f(x)∈ Fq[x], we let f(D)=(f(y1),…,f(yq-l)) if D=\y1, ..., yq-l\ and ck-1(f(x)) be the coefficient of xk-1 of f(x). By using D\"ur's theorem on the relation between the covering radius and minimum distance of GPRSq(D, k), we show that if u(x)∈ Fq[x] with (u(x))=k, then the received codeword (u(D), ck-1(u(x))) is a deep hole of GPRSq(D, k) if and only if the sum Σy∈ Iy is nonzero for any subset I⊂eq D with \#(I)=k. We show also that if j is an integer with 1≤ j≤ l and uj(x):= λj(x-aj)q-2+j xk-1+f≤ k-2(j)(x) with λj∈ Fq*, j∈ Fq and f≤k-2(j)(x)∈ Fq[x] being a polynomial of degree at most k-2, then (uj(D), ck-1(uj(x))) is a deep hole of GPRSq(D, k) if and only if the sum q-2k-1(-aj)q-1-kΠy∈ I(aj-y)+e is nonzero for any subset I⊂eq D with \#(I)=k, where e is the identity of the group Fq*. This implies that (uj(D), ck-1(uj(x))) is a deep hole of GPRSq(D, k) if p|k.