Factoring larger integers with fewer qubits via quantum annealing with optimized parameters

RSA cryptography is based on the difficulty of factoring large integers, which is an NP-hard (and hence intractable) problem for a classical computer. However, Shor’s algorithm shows that its complexity is polynomial for a quantum computer, although technical difficulties mean that practical quantum...

Full description

Saved in:
Bibliographic Details
Published in:Science China. Physics, mechanics & astronomy mechanics & astronomy, 2019-06, Vol.62 (6), p.60311, Article 60311
Main Authors: Peng, WangChun, Wang, BaoNan, Hu, Feng, Wang, YunJiang, Fang, XianJin, Chen, XingYuan, Wang, Chao
Format: Article
Language:English
Subjects:
Algorithms
Analysis
Astronomy
Circuits
Classical and Continuum Physics
Computers
Cryptography
Integers
Observations and Techniques
Physics
Physics and Astronomy
Polynomials
Quantum computers
Quantum computing
Qubits (quantum computing)
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:RSA cryptography is based on the difficulty of factoring large integers, which is an NP-hard (and hence intractable) problem for a classical computer. However, Shor’s algorithm shows that its complexity is polynomial for a quantum computer, although technical difficulties mean that practical quantum computers that can tackle integer factorizations of meaningful size are still a long way away. Recently, Jiang et al. proposed a transformation that maps the integer factorization problem onto the quadratic unconstrained binary optimization (QUBO) model. They tested their algorithm on a D-Wave 2000Q quantum annealing machine, raising the record for a quantum factorized integer to 376289 with only 94 qubits. In this study, we optimize the problem Hamiltonian to reduce the number of qubits involved in the final Hamiltonian while maintaining the QUBO coefficients in a reasonable range, enabling the improved algorithm to factorize larger integers with fewer qubits. Tests of our improved algorithm using D-Wave’s hybrid quantum/classical simulator qbsolv confirmed that performance was improved, and we were able to factorize 1005973, a new record for quantum factorized integers, with only 89 qubits. In addition, our improved algorithm can tolerate more errors than the original one. Factoring 1005973 using Shor’s algorithm would require about 41 universal qubits, which current universal quantum computers cannot reach with acceptable accuracy. In theory, the latest IBM Q System One TM (Jan. 2019) can only factor up to 10-bit integers, while the D-Wave have a thousand-fold advantage on the factoring scale. This shows that quantum annealing machines, such as those by D-Wave, may be close to cracking practical RSA codes, while universal quantum-circuit-based computers may be many years away from attacking RSA.
ISSN:1674-7348
1869-1927
DOI:10.1007/s11433-018-9307-1