Abstract
It is common in forest tree breeding that selection of populations must consider conservation of genetic diversity, while at the same time attempting to maximize response to selection. To optimize selection in these situations, the constraint on genetic diversity can be mathematically described with the numerator relationship matrix as a quadratic constraint. Pong-Wong and Woolliams formulated the optimal selection problem using semidefinite programming (SDP). Their SDP approach gave an accurate optimal value, but required rather long computation time. In this paper, we propose an second-order cone programming (SOCP) approach to reduce the heavy computation cost. First, we demonstrate that a simple SOCP formulation achieves the same numerical solution as the SDP approach. A simple SOCP formulation is, however, not much more efficient compared to the SDP approach, so we focused on the sparsity structure of the numerator relationship matrix, and we develop a more efficient SOCP formulation using Henderson’s algorithm. Numerical results show that the proposed formulation, which we call a compact SOCP, greatly reduced computation time. In a case study, an optimal selection problem that demanded 39,200 s under the SDP approach was solved in less than 2 s by the compact SOCP formulation. The proposed approach is now available as a part of the software package OPSEL.
Highlights
Breeders of forest trees must often consider conservation of genetic diversity, while at the same time maximizing response to selection
The remainder of this paper is organized as follows: Sect. 2 describes the semidefinite programming (SDP) approach of Pong-Wong and Woolliams and discusses a simple second-order cone programming (SOCP) formulation; in Sect. 3, we propose SOCP formulations and derive an efficient method; Sect. 4 presents numerical results to verify the reduction in computation time for problems of various sizes; and Sect. 5 gives conclusions and discusses future directions
We examined the SOCP formulations for the optimal selection problem arising from tree breeding
Summary
Breeders of forest trees must often consider conservation of genetic diversity, while at the same time maximizing response to selection. To solve the optimal selection problem (1) efficiently, Meuwissen [15] developed an iterative method based on Lagrangian multipliers and his method has been widely used in breeding, for example, [7,10,28]. It is a characteristic of this method that some variables xi may be fixed to their lower or upper bounds (li or ui ) forcibly, and it was further demonstrated by [22] that the output solution of Meuwissen’s method is not always truly optimal. The remainder of this paper is organized as follows: Sect. 2 describes the SDP approach of Pong-Wong and Woolliams and discusses a simple SOCP formulation; in Sect. 3, we propose SOCP formulations and derive an efficient method; Sect. 4 presents numerical results to verify the reduction in computation time for problems of various sizes; and Sect. 5 gives conclusions and discusses future directions
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