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Quantum combinatorial designs and <i>k</i> -uniform states

Yajuan Zang, Paolo Facchi, Zihong Tian

2021Journal of Physics A Mathematical and Theoretical12 citationsDOIOpen Access PDF

Abstract

Abstract Goyeneche et al [2018 Phys. Rev. A 97 062326] introduced several classes of quantum combinatorial designs, namely quantum Latin squares, quantum Latin cubes, and the notion of orthogonality on them. They also showed that mutually orthogonal quantum Latin arrangements can be entangled in the same way in which quantum states are entangled. Moreover, they established a relationship between quantum combinatorial designs and a remarkable class of entangled states called k -uniform states, i.e. multipartite pure states such that every reduction to k parties is maximally mixed. In this article, we put forward the notions of incomplete quantum Latin squares and orthogonality on them and present construction methods for mutually orthogonal quantum Latin squares and mutually orthogonal quantum Latin cubes. Furthermore, we introduce the notions of generalized mutually orthogonal quantum Latin squares and generalized mutually orthogonal quantum Latin cubes, which are equivalent to quantum orthogonal arrays of size d 2 and d 3 , respectively, and thus naturally provide two- and three-uniform states.

Topics & Concepts

OrthogonalityQuantum stateQuantum algorithmMathematicsQuantumQuantum operationQuantum informationQuantum discordQuantum networkQuantum mechanicsQuantum channelQuantum capacityQuantum computerDiscrete mathematicsMultipartitePure mathematicsClass (philosophy)Orthogonal arrayQuantum information scienceQuantum Fourier transformQuantum technologyPhysicsQuantum processQuantum error correctionTopology (electrical circuits)Algebra over a fieldCombinatoricsTheoretical physicsComputer scienceSIC-POVMQuantum systemQuantum teleportationgraph theory and CDMA systemsQuantum Computing Algorithms and ArchitectureQuantum Information and Cryptography
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