Synthesis of Hybrid and d-valued Quantum Logic Circuits

Author

Khan, Faisal Shah ; Perkowski, Marek A.

Author_Institution

Portland State Univ., Portland

fYear

0

fDate

0-0 0

Firstpage

2410

Lastpage

2415

Abstract

Recent research in generalizing quantum computation from 2-valued qudits to d-valued qudits has shown practical advantages for scaling up a quantum computer. A further generalization leads to quantum computing with hybrid qudits where two or more qudits have different finite dimensions. In both cases, a quantum computation is performed when a unitary evolution operator, acting as a quantum logic gate, transforms the state of qudits in a quantum system. Unitary operators can be represented by unitary matrices, and therefore for a quantum system consists of multiple qudits, a gate may be synthesized by matrix decomposition techniques such as QR factorization and the cosine-sine decomposition (CSD). In this article, we present a CSD based synthesis method for n qudit hybrid and d-valued quantum circuits.

Keywords

logic gates; matrix decomposition; multivalued logic circuits; quantum computing; CSD based synthesis method; cosine-sine decomposition; d-valued quantum logic circuit; matrix decomposition technique; quantum computing; quantum logic gate; unitary evolution operator; Circuit synthesis; Hilbert space; Logic circuits; Logic gates; Mathematics; Matrix decomposition; Quantum computing; State-space methods; Tensile stress; Vectors;

fLanguage

English

Publisher

ieee

Conference_Titel

Evolutionary Computation, 2006. CEC 2006. IEEE Congress on

Conference_Location

Vancouver, BC

Print_ISBN

0-7803-9487-9

Type

conf

DOI

10.1109/CEC.2006.1688607

Filename

1688607