Total dual dyadicness and dyadic generating sets

Abstract: A vector is dyadic if each of its entries is a dyadic rational number, i.e. of the form a 2 k for some integers a, k with k ≥ 0. A linear system Ax ≤ b with integral data is totally dual dyadic if whenever min{b ⊺ y ∶ A ⊺ y = w, y ≥ 0} for w integral, has an optimal solution, it has a dyadic optimal solution. In this paper, we study total dual dyadicness, and give a co-NP characterization of it in terms of dyadic generating sets for cones and subspaces, the former being the dyadic analogue of Hilbert bases, an… Show more

“…Ax = 0, and for each i ∈ [n], we have q i | xi , so if xi = 0 then xi has a prime factor greater than or equal to p k+1 . Thus the 1-by-n matrix A satisfies the conclusion of Lemma 5.4 (1).…”

“…In Section 4, we focus on the size of the denominators of a solution to a feasible dyadic linear program. In particular, we show that if Ax ≤ b, x dyadic is feasible, where A ∈ Z m×n and b ∈ Z m , then there exists a 1 2 k -integral solution, where k ≤ log 2 n + (2n + 1) log 2 ( A ∞ √ n + 1) . Here A ∞ denotes the largest absolute value of an entry in A.…”

“…Proof. Denote by L 1 the set L as defined by (1) and by L 2 the set L as defined by (2). We need to show L 1 = L 2 .…”

“…A rational number is dyadic if it is an integer multiple of 1 2 k for some nonnegative integer k. Dyadic numbers are important for numerical computations because they have a finite binary representation, and therefore they can be represented exactly on a computer in floating-point arithmetic. When real or rational numbers are approximated by dyadic numbers on a computer, approximation errors may propagate and accumulate throughout the computations.…”

“…Take a mathematical point of view: Given a prime integer p ≥ 2, we say that a rational number is finitely p-adic if it is of the form r p k for some integer r and nonnegative integer k. This concept is closely related to the notion of the p-adic numbers introduced by Hensel, formally defined as the set of "finite-tailed" infinite series +∞ i=N a i p i where N ∈ Z, and a i ∈ Z and 0 ≤ a i < p for each i ≥ N . 1 The study of p-adic numbers gives rise to beautiful and powerful mathematics; see the excellent book by Gouvêa for more [17]. It can be readily checked that the set of finitely p-adic numbers is the set of finite series of the form M i=N a i p i , where M, N ∈ Z, M ≥ N , and 0 ≤ a i < p, a i ∈ Z for all N ≤ i ≤ M , justifying our terminology.…”

Total Dual Dyadicness and Dyadic Generating Sets

“…Ax = 0, and for each i ∈ [n], we have q i | xi , so if xi = 0 then xi has a prime factor greater than or equal to p k+1 . Thus the 1-by-n matrix A satisfies the conclusion of Lemma 5.4 (1).…”

“…In Section 4, we focus on the size of the denominators of a solution to a feasible dyadic linear program. In particular, we show that if Ax ≤ b, x dyadic is feasible, where A ∈ Z m×n and b ∈ Z m , then there exists a 1 2 k -integral solution, where k ≤ log 2 n + (2n + 1) log 2 ( A ∞ √ n + 1) . Here A ∞ denotes the largest absolute value of an entry in A.…”

“…Proof. Denote by L 1 the set L as defined by (1) and by L 2 the set L as defined by (2). We need to show L 1 = L 2 .…”

“…A rational number is dyadic if it is an integer multiple of 1 2 k for some nonnegative integer k. Dyadic numbers are important for numerical computations because they have a finite binary representation, and therefore they can be represented exactly on a computer in floating-point arithmetic. When real or rational numbers are approximated by dyadic numbers on a computer, approximation errors may propagate and accumulate throughout the computations.…”

“…Take a mathematical point of view: Given a prime integer p ≥ 2, we say that a rational number is finitely p-adic if it is of the form r p k for some integer r and nonnegative integer k. This concept is closely related to the notion of the p-adic numbers introduced by Hensel, formally defined as the set of "finite-tailed" infinite series +∞ i=N a i p i where N ∈ Z, and a i ∈ Z and 0 ≤ a i < p for each i ≥ N . 1 The study of p-adic numbers gives rise to beautiful and powerful mathematics; see the excellent book by Gouvêa for more [17]. It can be readily checked that the set of finitely p-adic numbers is the set of finite series of the form M i=N a i p i , where M, N ∈ Z, M ≥ N , and 0 ≤ a i < p, a i ∈ Z for all N ≤ i ≤ M , justifying our terminology.…”

Total Dual Dyadicness and Dyadic Generating Sets