Approximation of Quantum States Using Decision Diagrams

Alwin Walter Zulehner; Stefan Hillmich; Igor L. Markov; Robert Wille

Approximation of Quantum States Using Decision Diagrams

Alwin Walter Zulehner
, Stefan Hillmich
, Igor L. Markov
, Robert Wille

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

Abstract

The computational power of quantum computers poses major challenges to new design tools since representing pure quantum states typically requires exponentially large memory. As shown previously, decision diagrams can reduce these memory requirements by exploiting redundancies. In this work, we demonstrate further reductions by allowing for small inaccuracies in the quantum state representation. Such inaccuracies are legitimate since quantum computers themselves experience gate and measurement errors and since quantum algorithms are somewhat resistant to errors (even without error correction). We develop four dedicated schemes that exploit these observations and effectively approximate quantum states represented by decision diagrams. We empirically show that the proposed schemes reduce the size of decision diagrams by up to several orders of magnitude while controlling the fidelity of approximate quantum state representations.

Original language	English
Title of host publication	Asia and South Pacific Design Automation Conference (ASP-DAC)
Number of pages	6
Publication status	Published - 2020

Fields of science

102 Computer Sciences
202 Electrical Engineering, Electronics, Information Engineering

JKU Focus areas

Digital Transformation

Cite this

@inproceedings{49bb6c0e688646b79c5f57a6131da5f9,

title = "Approximation of Quantum States Using Decision Diagrams",

abstract = "The computational power of quantum computers poses major challenges to new design tools since representing pure quantum states typically requires exponentially large memory. As shown previously, decision diagrams can reduce these memory requirements by exploiting redundancies. In this work, we demonstrate further reductions by allowing for small inaccuracies in the quantum state representation. Such inaccuracies are legitimate since quantum computers themselves experience gate and measurement errors and since quantum algorithms are somewhat resistant to errors (even without error correction). We develop four dedicated schemes that exploit these observations and effectively approximate quantum states represented by decision diagrams. We empirically show that the proposed schemes reduce the size of decision diagrams by up to several orders of magnitude while controlling the fidelity of approximate quantum state representations.",

author = "Zulehner, \{Alwin Walter\} and Stefan Hillmich and Markov, \{Igor L.\} and Robert Wille",

year = "2020",

language = "English",

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T1 - Approximation of Quantum States Using Decision Diagrams

AU - Zulehner, Alwin Walter

AU - Hillmich, Stefan

AU - Markov, Igor L.

AU - Wille, Robert

PY - 2020

Y1 - 2020

N2 - The computational power of quantum computers poses major challenges to new design tools since representing pure quantum states typically requires exponentially large memory. As shown previously, decision diagrams can reduce these memory requirements by exploiting redundancies. In this work, we demonstrate further reductions by allowing for small inaccuracies in the quantum state representation. Such inaccuracies are legitimate since quantum computers themselves experience gate and measurement errors and since quantum algorithms are somewhat resistant to errors (even without error correction). We develop four dedicated schemes that exploit these observations and effectively approximate quantum states represented by decision diagrams. We empirically show that the proposed schemes reduce the size of decision diagrams by up to several orders of magnitude while controlling the fidelity of approximate quantum state representations.

AB - The computational power of quantum computers poses major challenges to new design tools since representing pure quantum states typically requires exponentially large memory. As shown previously, decision diagrams can reduce these memory requirements by exploiting redundancies. In this work, we demonstrate further reductions by allowing for small inaccuracies in the quantum state representation. Such inaccuracies are legitimate since quantum computers themselves experience gate and measurement errors and since quantum algorithms are somewhat resistant to errors (even without error correction). We develop four dedicated schemes that exploit these observations and effectively approximate quantum states represented by decision diagrams. We empirically show that the proposed schemes reduce the size of decision diagrams by up to several orders of magnitude while controlling the fidelity of approximate quantum state representations.

M3 - Conference proceedings

BT - Asia and South Pacific Design Automation Conference (ASP-DAC)

ER -