research-article

Quantum-Logic Synthesis of Hermitian Gates

Authors:

Mona Arabzadeh,

Mahboobeh Houshmand,

Morteza Saheb ZamaniAuthors Info & Claims

ACM Journal on Emerging Technologies in Computing Systems (JETC), Volume 12, Issue 4

Article No.: 40, Pages 1 - 15

https://doi.org/10.1145/2794263

Published: 28 December 2015 Publication History

Abstract

In this article, the problem of synthesizing a general Hermitian quantum gate into a set of primary quantum gates is addressed. To this end, an extended version of the Jacobi approach for calculating the eigenvalues of Hermitian matrices in linear algebra is considered as the basis of the proposed synthesis method. The quantum circuit synthesis method derived from the Jacobi approach and its optimization challenges are described. It is shown that the proposed method results in multiple-control rotation gates around the y axis, multiple-control phase shift gates, multiple-control NOT gates, and a middle diagonal Hermitian matrix, which can be synthesized to multiple-control Pauli Z gates. Using the proposed approach, it is shown how multiple-control U gates, where U is a single-qubit Hermitian quantum gate, can be implemented using a linear number of elementary gates in terms of circuit lines with the aid of one auxiliary qubit in an arbitrary state.

References

[1]

M. Arabzadeh, M. Saeedi, and M. Saheb Zamani. 2010. Rule-based optimization of reversible circuits. In Asia and South Pacific Design Automation Conference. 849--854.

Digital Library

[2]

A. Barenco, C. H. Bennett, R. Cleve, D. P. DiVincenzo, N. Margolus, P. Shor, T. Sleator, J. Smolin, and H. Weinfurter. 1995. Elementary gates for quantum computation. Physical Review A 52 (1995), 3457--3467.

[3]

V. Bergholm, J. J. Vartiainen, M. Möttönen, and M. M. Salomaa. 2005. Quantum circuits with uniformly controlled one-qubit gates. Physical Review A 71 (2005), 052330.

[4]

A. Broadbent and E. Kashefi. 2009. Parallelizing quantum circuits. Theoretical Computer Science 410, 26 (June 2009), 2489--2510.

Digital Library

[5]

S. S. Bullock and I. L. Markov. 2004. Asymptotically optimal circuits for arbitrary n-qubit diagonal computations. Quantum Information and Computation 4, 1 (2004), 27--47.

Digital Library

[6]

G. Cybenko. 2001. Reducing quantum computations to elementary unitary operations. Computing in Science and Engineering 3, 2 (2001), 27--32.

Digital Library

[7]

V. Danos, E. Kashefi, P. Panangaden, and S. Perdrix. 2009. Extended Measurement Calculus. Semantic Techniques in Quantum Computation.

[8]

R. Feynman. 1982. Simulating physics with computers. International Journal of Theoretical Physics 21 (1982), 467--488.

[9]

G. H. Golub and C. F. Van Loan. 1996. Matrix Computations. Vol. 3. JHUP.

[10]

M. Grassl. 2008. Circuits for quantum error-correction codes. http://iaks-www.ira.uka.de/home/grassl/QECC/circuits/.

[11]

L. K. Grover. 1996. A fast quantum mechanical algorithm for database search. ACM Symposium on Theory of Computing (1996).

Digital Library

[12]

A. W. Harrow, A. Hassidim, and S. Lloyd. 2009. Quantum algorithm for linear systems of equations. Physical Review Letters 103, 15 (2009), 150502.

[13]

M. Houshmand, M. Saheb Zamani, M. Sedighi, and M. Arabzadeh. 2014. Decomposition of diagonal hermitian quantum gates using multiple-controlled pauli z gates. To Appear in ACM Journal of Emerging Technologies and Computer Systemes E-Print, Quant-Ph/1405.6741 (2014).

Digital Library

[14]

Chia-Chun Lin, Amlan Chakrabarti, and Niraj K. Jha. 2014. FTQLS: Fault-tolerant quantum logic synthesis. IEEE Transactions on Very Large Scale Integration (VLSI) Systems 22, 6 (2014), 1350--1363.

[15]

D. Maslov, G. W. Dueck, D. M. Miller, and C. Negrevergne. 2008. Quantum circuit simplification and level compaction. IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems 27, 3 (2008), 436--444.

Digital Library

[16]

M. A. Nielsen and I. L. Chuang. 2000. Quantum Computation and Quantum Information. Cambridge University Press.

Digital Library

[17]

H. Park and V. Hari. 1993. A real algorithm for the Hermitian eigenvalue decomposition. BIT Numerical Mathematics 33, 1 (1993), 158--171.

[18]

A. Pathak. 2013. Non-Hermitian quantum gates are more common than Hermitian quantum gates. E-Print, Quant-Ph/1309.4037v1 (2013).

[19]

M. Saeedi, M. Arabzadeh, M. Saheb Zamani, and M. Sedighi. 2011. Block-based quantum-logic synthesis. Quantum Information and Computation 11, 3--4 (2011), 262--277.

Digital Library

[20]

V. V. Shende, S. S. Bullock, and I. L. Markov. 2006. Synthesis of quantum-logic circuits. IEEE Transactions on CAD 25, 6 (June 2006), 1000--1010.

Digital Library

[21]

V. V. Shende and I. L. Markov. 2009. On the CNOT-cost of Toffoli gates. Quantum Information and Computation 9, 5--6 (May 2009), 461--486.

Digital Library

[22]

V. V. Shende, I. L. Markov, and S. S. Bullock. 2004. Smaller two-qubit circuits for quantum communication and computation. Design, Automation and Test in Europe (2004), 980--985.

Digital Library

[23]

P. W. Shor. 1997. Polynomial-time algorithms for prime factorization and discrete logarithms on a quantum computer. SIAM Journal on Computing 26 (1997), 1484--1509.

Digital Library

[24]

J. J. Vartiainen, M. Möttönen, and M. M. Salomaa. 2004. Efficient decomposition of quantum gates. Physical Review Letters 92 (2004), 177902.

[25]

F. Vatan and C. Williams. 2004a. Optimal quantum circuits for general two-qubit gates. Physical Review A 69 (2004), 032315.

[26]

F. Vatan and C. P. Williams. 2004b. Realization of a general three-qubit quantum gate. E-Print, Quant-Ph/0401178 (2004).

[27]

G. Vidal and C. M. Dawson. 2004. A universal quantum circuit for two-qubit transformations with three CNOT gates. Physical Review A 69 (2004), 010301.

[28]

N. Wiebe, D. Braun, and S. Lloyd. 2012. Quantum algorithm for data fitting. Physical Review Letters 109, 5 (2012), 050505.

[29]

C. Wu, Y. Tsai, and H. Tsai. 2005. Quantum circuits for stabilizer codes. In IEEE International Symposium on Circuits and Systems, (ISCAS’05). 2333--2336.

Cited By

Houshmand MSedighi MZamani MMarjoei K(2017)Quantum Circuit Synthesis Targeting to Improve One-Way Quantum Computation Pattern Cost MetricsACM Journal on Emerging Technologies in Computing Systems10.1145/306483413:4(1-27)Online publication date: 21-May-2017
https://dl.acm.org/doi/10.1145/3064834

Index Terms

Quantum-Logic Synthesis of Hermitian Gates
1. Hardware
  1. Emerging technologies

Recommendations

Decomposition of Diagonal Hermitian Quantum Gates Using Multiple-Controlled Pauli Z Gates
Special Issue on Computational Synthetic Biology and Regular Papers

Quantum logic decomposition refers to decomposing a given quantum gate to a set of physically implementable gates. An approach has been presented to decompose arbitrary diagonal quantum gates to a set of multiplexed-rotation gates around z axis. In this ...
Construction of quantum gates for concatenated Greenberger---Horne---Zeilinger-type logic qubit

Concatenated Greenberger---Horne---Zeilinger (C-GHZ) state is a kind of logic qubit which is robust in noisy environment. In this paper, we encode the C-GHZ state as the logic qubit and design two kinds of quantum gates for such logic qubit. The first ...
Compact quantum gates for hybrid photon---atom systems assisted by Faraday rotation

We present some compact circuits for a deterministic quantum computing on the hybrid photon---atom systems, including the Fredkin gate and SWAP gate. These gates are constructed by exploiting the optical Faraday rotation induced by an atom trapped in a ...

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image ACM Journal on Emerging Technologies in Computing Systems

ACM Journal on Emerging Technologies in Computing Systems Volume 12, Issue 4

Regular Papers

July 2016

394 pages

ISSN:1550-4832

EISSN:1550-4840

DOI:10.1145/2856147

Editor:
Yuan Xie
University of California, Santa Barbara, USA

Issue’s Table of Contents

Copyright © 2015 ACM.

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

Publisher

Association for Computing Machinery

New York, NY, United States

Journal Family

ACM Journals for the Design of Smart and Connected Systems

Publication History

Published: 28 December 2015

Accepted: 01 June 2015

Revised: 01 March 2015

Received: 01 September 2014

Published in JETC Volume 12, Issue 4

Permissions

Request permissions for this article.

Request Permissions

Check for updates

Author Tags

Qualifiers

Research-article
Research
Refereed

Funding Sources

National Science Foundation

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

1
Total Citations
View Citations
242
Total Downloads

Downloads (Last 12 months)9
Downloads (Last 6 weeks)0

Reflects downloads up to 26 Sep 2024

Other Metrics

View Author Metrics

Citations

Cited By

Houshmand MSedighi MZamani MMarjoei K(2017)Quantum Circuit Synthesis Targeting to Improve One-Way Quantum Computation Pattern Cost MetricsACM Journal on Emerging Technologies in Computing Systems10.1145/306483413:4(1-27)Online publication date: 21-May-2017
https://dl.acm.org/doi/10.1145/3064834

View Options

Get Access

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Article

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Media

Figures

Other

Tables

View Issue’s Table of Contents