Implementing Quantum Finite Automata Algorithms on Noisy Devices

Utku Birkan; Özlem Salehi; Viktor Olejar; Cem Nurlu; Abuzer Yakaryilmaz

Implementing Quantum Finite Automata Algorithms on Noisy Devices

Utku Birkan^*
, Özlem Salehi
, Viktor Olejar
, Cem Nurlu
, Abuzer Yakaryilmaz

^*Corresponding author for this work

Department of Computer Science

Middle East Technical University
Ozyegin University
QWorld Association
P. J. Safarik University
Bogazici University

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › Research › peer-review

8 Citations (Scopus)

Abstract

Quantum finite automata (QFAs) literature offers an alternative mathematical model for studying quantum systems with finite memory. As a superiority of quantum computing, QFAs have been shown exponentially more succinct on certain problems such as recognizing the language MODp={aj∣j≡0modp} with bounded error, where p is a prime number. In this paper we present improved circuit based implementations for QFA algorithms recognizing the MOD_p problem using the Qiskit framework. We focus on the case p= 11 and provide a 3 qubit implementation for the MOD₁₁ problem reducing the total number of required gates using alternative approaches. We run the circuits on real IBM quantum devices but due to the limitation of the real quantum devices in the NISQ era, the results are heavily affected by the noise. This limitation reveals once again the need for algorithms using less amount of resources. Consequently, we consider an alternative 3 qubit implementation which works better in practice and obtain promising results even for the problem MOD₃₁.

Original language	English
Title of host publication	Computational Science – ICCS 2021 - 21st International Conference, Proceedings
Pages	3-16
Number of pages	14
Volume	12747 LNCS
Publication status	Published - 2021

Publication series

Name	Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
Volume	12747 LNCS
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Keywords

Quantum algorithms
Quantum circuit
Quantum finite automata
Rotation gate

OECD Field of Science

1.2 Computer and Information Sciences

Cite this

Birkan, U., Salehi, Ö., Olejar, V., Nurlu, C., & Yakaryilmaz, A. (2021). Implementing Quantum Finite Automata Algorithms on Noisy Devices. In Computational Science – ICCS 2021 - 21st International Conference, Proceedings (Vol. 12747 LNCS, pp. 3-16). (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics); Vol. 12747 LNCS).

Birkan, Utku ; Salehi, Özlem ; Olejar, Viktor et al. / Implementing Quantum Finite Automata Algorithms on Noisy Devices. Computational Science – ICCS 2021 - 21st International Conference, Proceedings. Vol. 12747 LNCS 2021. pp. 3-16 (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)).

@inproceedings{7124351f2f8b420f896431cc842636d4,

title = "Implementing Quantum Finite Automata Algorithms on Noisy Devices",

abstract = "Quantum finite automata (QFAs) literature offers an alternative mathematical model for studying quantum systems with finite memory. As a superiority of quantum computing, QFAs have been shown exponentially more succinct on certain problems such as recognizing the language MODp=\{aj∣j≡0modp\} with bounded error, where p is a prime number. In this paper we present improved circuit based implementations for QFA algorithms recognizing the MODp problem using the Qiskit framework. We focus on the case p= 11 and provide a 3 qubit implementation for the MOD11 problem reducing the total number of required gates using alternative approaches. We run the circuits on real IBM quantum devices but due to the limitation of the real quantum devices in the NISQ era, the results are heavily affected by the noise. This limitation reveals once again the need for algorithms using less amount of resources. Consequently, we consider an alternative 3 qubit implementation which works better in practice and obtain promising results even for the problem MOD31.",

keywords = "Quantum algorithms, Quantum circuit, Quantum finite automata, Rotation gate",

author = "Utku Birkan and {\"O}zlem Salehi and Viktor Olejar and Cem Nurlu and Abuzer Yakaryilmaz",

note = "Publisher Copyright: {\textcopyright} 2021, Springer Nature Switzerland AG.",

year = "2021",

language = "English",

isbn = "9783030779795",

volume = "12747 LNCS",

series = "Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)",

pages = "3--16",

booktitle = "Computational Science – ICCS 2021 - 21st International Conference, Proceedings",

}

Birkan, U, Salehi, Ö, Olejar, V, Nurlu, C & Yakaryilmaz, A 2021, Implementing Quantum Finite Automata Algorithms on Noisy Devices. in Computational Science – ICCS 2021 - 21st International Conference, Proceedings. vol. 12747 LNCS, Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics), vol. 12747 LNCS, pp. 3-16.

Implementing Quantum Finite Automata Algorithms on Noisy Devices. / Birkan, Utku; Salehi, Özlem; Olejar, Viktor et al.
Computational Science – ICCS 2021 - 21st International Conference, Proceedings. Vol. 12747 LNCS 2021. p. 3-16 (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics); Vol. 12747 LNCS).

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › Research › peer-review

TY - GEN

T1 - Implementing Quantum Finite Automata Algorithms on Noisy Devices

AU - Birkan, Utku

AU - Salehi, Özlem

AU - Olejar, Viktor

AU - Nurlu, Cem

AU - Yakaryilmaz, Abuzer

PY - 2021

Y1 - 2021

N2 - Quantum finite automata (QFAs) literature offers an alternative mathematical model for studying quantum systems with finite memory. As a superiority of quantum computing, QFAs have been shown exponentially more succinct on certain problems such as recognizing the language MODp={aj∣j≡0modp} with bounded error, where p is a prime number. In this paper we present improved circuit based implementations for QFA algorithms recognizing the MODp problem using the Qiskit framework. We focus on the case p= 11 and provide a 3 qubit implementation for the MOD11 problem reducing the total number of required gates using alternative approaches. We run the circuits on real IBM quantum devices but due to the limitation of the real quantum devices in the NISQ era, the results are heavily affected by the noise. This limitation reveals once again the need for algorithms using less amount of resources. Consequently, we consider an alternative 3 qubit implementation which works better in practice and obtain promising results even for the problem MOD31.

AB - Quantum finite automata (QFAs) literature offers an alternative mathematical model for studying quantum systems with finite memory. As a superiority of quantum computing, QFAs have been shown exponentially more succinct on certain problems such as recognizing the language MODp={aj∣j≡0modp} with bounded error, where p is a prime number. In this paper we present improved circuit based implementations for QFA algorithms recognizing the MODp problem using the Qiskit framework. We focus on the case p= 11 and provide a 3 qubit implementation for the MOD11 problem reducing the total number of required gates using alternative approaches. We run the circuits on real IBM quantum devices but due to the limitation of the real quantum devices in the NISQ era, the results are heavily affected by the noise. This limitation reveals once again the need for algorithms using less amount of resources. Consequently, we consider an alternative 3 qubit implementation which works better in practice and obtain promising results even for the problem MOD31.

KW - Quantum algorithms

KW - Quantum circuit

KW - Quantum finite automata

KW - Rotation gate

UR - https://link.springer.com/chapter/10.1007%252F978-3-030-77980-1_1

UR - https://www.scopus.com/pages/publications/85111211413

M3 - Conference paper

SN - 9783030779795

VL - 12747 LNCS

T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)

SP - 3

EP - 16

BT - Computational Science – ICCS 2021 - 21st International Conference, Proceedings

ER -

Birkan U, Salehi Ö, Olejar V, Nurlu C, Yakaryilmaz A. Implementing Quantum Finite Automata Algorithms on Noisy Devices. In Computational Science – ICCS 2021 - 21st International Conference, Proceedings. Vol. 12747 LNCS. 2021. p. 3-16. (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)).

Implementing Quantum Finite Automata Algorithms on Noisy Devices

Abstract

Publication series

Keywords

OECD Field of Science

Other files and links

Fingerprint

Cite this