A simplified stabilizer ZX-calculus

Miriam Backens; Simon Perdrix; Quanlong Wang

doi:10.4204/EPTCS.236.1

A simplified stabilizer ZX-calculus

Miriam Backens, Simon Perdrix, Quanlong Wang

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

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Abstract

The stabilizer ZX-calculus is a rigorous graphical language for reasoning about quantum mechanics.The language is sound and complete: a stabilizer ZX-diagram can be transformed into another one if and only if these two diagrams represent the same quantum evolution or quantum state. We show that the stabilizer ZX-calculus can be simplified, removing unnecessary equations while keeping only the essential axioms which potentially capture fundamental structures of quantum mechanics. We thus give a significantly smaller set of axioms and prove that meta-rules like 'colour symmetry' and 'upside-down symmetry', which were considered as axioms in previous versions of the language, can in fact be derived. In particular, we show that the additional symbol and one of the rules which had been recently introduced to keep track of scalars (diagrams with no inputs or outputs) are not necessary.

Original language	English
Title of host publication	EPTCS
Subtitle of host publication	Proceedings 13th International Conference on Quantum Physics and Logic
Pages	1-20
Number of pages	21
Volume	236
DOIs	https://doi.org/10.4204/EPTCS.236.1
Publication status	Published - 1 Jan 2017

Publication series

Name	Electronic Proceedings in Theoretical Computer Science
Publisher	Open Publishing Association
ISSN (Print)	2075-2180

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QITG

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10.4204/EPTCS.236.1

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New insights in quantum algorithms and complexity
Montanaro, A. M. R.
31/07/14 → 30/07/19
Project: Research
New insights in quantum algorithms and complexity
Montanaro, A. M. R.
31/07/14 → 30/06/20
Project: Research

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title = "A simplified stabilizer ZX-calculus",

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N2 - The stabilizer ZX-calculus is a rigorous graphical language for reasoning about quantum mechanics.The language is sound and complete: a stabilizer ZX-diagram can be transformed into another one if and only if these two diagrams represent the same quantum evolution or quantum state. We show that the stabilizer ZX-calculus can be simplified, removing unnecessary equations while keeping only the essential axioms which potentially capture fundamental structures of quantum mechanics. We thus give a significantly smaller set of axioms and prove that meta-rules like 'colour symmetry' and 'upside-down symmetry', which were considered as axioms in previous versions of the language, can in fact be derived. In particular, we show that the additional symbol and one of the rules which had been recently introduced to keep track of scalars (diagrams with no inputs or outputs) are not necessary.

AB - The stabilizer ZX-calculus is a rigorous graphical language for reasoning about quantum mechanics.The language is sound and complete: a stabilizer ZX-diagram can be transformed into another one if and only if these two diagrams represent the same quantum evolution or quantum state. We show that the stabilizer ZX-calculus can be simplified, removing unnecessary equations while keeping only the essential axioms which potentially capture fundamental structures of quantum mechanics. We thus give a significantly smaller set of axioms and prove that meta-rules like 'colour symmetry' and 'upside-down symmetry', which were considered as axioms in previous versions of the language, can in fact be derived. In particular, we show that the additional symbol and one of the rules which had been recently introduced to keep track of scalars (diagrams with no inputs or outputs) are not necessary.

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DO - 10.4204/EPTCS.236.1

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A simplified stabilizer ZX-calculus

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New insights in quantum algorithms and complexity

New insights in quantum algorithms and complexity

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