关于Choi正交拉丁方的最新结果

Q3 Mathematics Journal of Algebra Combinatorics Discrete Structures and Applications Pub Date : 2018-12-05 DOI:10.13069/jacodesmath.1056511

Jon-Lark Kim, D. Ohk, Doo Young Park, Jae Woo Park

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引用次数: 0

摘要

崔锡正研究拉丁方块的时间比欧拉早了60年，但这一点并不为人所知。他在书中介绍了一对9阶的正交拉丁方阵。有趣的是，他的两个正交的非双对角线拉丁方产生了一个9阶的魔方，其理论原因没有被研究。关于Choi的拉丁9阶方阵已有一些研究。最近的一个是李高伟(Ko-Wei Lih)在两个3 * 3正交拉丁方阵的基础上构造了9阶的Choi拉丁方阵。本文利用包含Lih构造的Kronecker积，将9阶的Choi正交拉丁平方推广到n2阶的正交拉丁平方。我们用二面体群D8找到了9阶Choi正交拉丁方的几何描述。我们还给出了一种由两个正交的非双对角线拉丁方构造幻方的新方法，这解释了为什么Choi的拉丁方产生一个9阶的幻方。

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Recent results on Choi's orthogonal Latin squares

Choi Seok-Jeong studied Latin squares at least 60 years earlier than Euler although this was less known. He introduced a pair of orthogonal Latin squares of order 9 in his book. Interestingly, his two orthogonal non-double-diagonal Latin squares produce a magic square of order 9, whose theoretical reason was not studied. There have been a few studies on Choi’s Latin squares of order 9. The most recent one is Ko-Wei Lih’s construction of Choi’s Latin squares of order 9 based on the two 3ˆ3 orthogonal Latin squares. In this paper, we give a new generalization of Choi’s orthogonal Latin squares of order 9 to orthogonal Latin squares of size n2 using the Kronecker product including Lih’s construction. We find a geometric description of Choi’s orthogonal Latin squares of order 9 using the dihedral group D8. We also give a new way to construct magic squares from two orthogonal non-double-diagonal Latin squares, which explains why Choi’s Latin squares produce a magic square of order 9.

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