Quantum alternation

A. Yakaryılmaz

doi:10.1134/S1995080216060196

Quantum alternation

A. Yakaryılmaz^*

^*Corresponding author for this work

Yenisehir

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

We introduce quantum alternation as a generalization of quantum nondeterminism. We define q-alternating Turing machine (qATM) by augmenting alternating Turing machine with constant-size quantum memory. We show that one-way constant-space qATMs (1AQFAs) are Turing equivalent. Then, we introduce strong version of qATM by requiring to halt in every computation path and we show that strong qATMs can simulate deterministic spacewith exponentially less space. This leads to shifting the deterministic space hierarchy exactly by one level. We also focus on realtime versions of 1AQFAs (rtAQFAs) and obtain many results: rtAQFAs can recognize a PSPACE-complete problem; they cannot be simulated by sublinear deterministic Turing machines; for any level of polynomial hierarchy, say k, there exists a complete language that can be recognized by rtAFAs with only (k +1) alternations; and polynomial hierarchy lies in its log-space q-alternation counterpart.

Original language	English
Pages (from-to)	637-649
Number of pages	13
Journal	Lobachevskii Journal of Mathematics
Volume	37
Issue number	6
DOIs	https://doi.org/10.1134/S1995080216060196
Publication status	Published - 1 Nov 2016
Externally published	Yes

Keywords

Alternation
PSPACE
logspace
polynomial hierarchy
quantum automata
quantum computation
subset-sum problems

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10.1134/S1995080216060196

Cite this

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title = "Quantum alternation",

abstract = "We introduce quantum alternation as a generalization of quantum nondeterminism. We define q-alternating Turing machine (qATM) by augmenting alternating Turing machine with constant-size quantum memory. We show that one-way constant-space qATMs (1AQFAs) are Turing equivalent. Then, we introduce strong version of qATM by requiring to halt in every computation path and we show that strong qATMs can simulate deterministic spacewith exponentially less space. This leads to shifting the deterministic space hierarchy exactly by one level. We also focus on realtime versions of 1AQFAs (rtAQFAs) and obtain many results: rtAQFAs can recognize a PSPACE-complete problem; they cannot be simulated by sublinear deterministic Turing machines; for any level of polynomial hierarchy, say k, there exists a complete language that can be recognized by rtAFAs with only (k +1) alternations; and polynomial hierarchy lies in its log-space q-alternation counterpart.",

keywords = "Alternation, PSPACE, logspace, polynomial hierarchy, quantum automata, quantum computation, subset-sum problems",

author = "A. Yakaryılmaz",

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T1 - Quantum alternation

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N2 - We introduce quantum alternation as a generalization of quantum nondeterminism. We define q-alternating Turing machine (qATM) by augmenting alternating Turing machine with constant-size quantum memory. We show that one-way constant-space qATMs (1AQFAs) are Turing equivalent. Then, we introduce strong version of qATM by requiring to halt in every computation path and we show that strong qATMs can simulate deterministic spacewith exponentially less space. This leads to shifting the deterministic space hierarchy exactly by one level. We also focus on realtime versions of 1AQFAs (rtAQFAs) and obtain many results: rtAQFAs can recognize a PSPACE-complete problem; they cannot be simulated by sublinear deterministic Turing machines; for any level of polynomial hierarchy, say k, there exists a complete language that can be recognized by rtAFAs with only (k +1) alternations; and polynomial hierarchy lies in its log-space q-alternation counterpart.

AB - We introduce quantum alternation as a generalization of quantum nondeterminism. We define q-alternating Turing machine (qATM) by augmenting alternating Turing machine with constant-size quantum memory. We show that one-way constant-space qATMs (1AQFAs) are Turing equivalent. Then, we introduce strong version of qATM by requiring to halt in every computation path and we show that strong qATMs can simulate deterministic spacewith exponentially less space. This leads to shifting the deterministic space hierarchy exactly by one level. We also focus on realtime versions of 1AQFAs (rtAQFAs) and obtain many results: rtAQFAs can recognize a PSPACE-complete problem; they cannot be simulated by sublinear deterministic Turing machines; for any level of polynomial hierarchy, say k, there exists a complete language that can be recognized by rtAFAs with only (k +1) alternations; and polynomial hierarchy lies in its log-space q-alternation counterpart.

KW - Alternation

KW - PSPACE

KW - logspace

KW - polynomial hierarchy

KW - quantum automata

KW - quantum computation

KW - subset-sum problems

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DO - 10.1134/S1995080216060196

M3 - Article

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SP - 637

EP - 649

JO - Lobachevskii Journal of Mathematics

JF - Lobachevskii Journal of Mathematics

IS - 6

ER -

Quantum alternation

Abstract

Keywords

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