Papers
Topics
Authors
Recent
Search
2000 character limit reached

Guided quantum walk

Published 10 Aug 2023 in quant-ph | (2308.05418v3)

Abstract: We utilize the theory of local amplitude transfers (LAT) to gain insights into quantum walks (QWs) and quantum annealing (QA) beyond the adiabatic theorem. By representing the eigenspace of the problem Hamiltonian as a hypercube graph, we demonstrate that probability amplitude traverses the search space through a series of local Rabi oscillations. We argue that the amplitude movement can be systematically guided towards the ground state using a time-dependent hopping rate based solely on the problem's energy spectrum. Building upon these insights, we extend the concept of multi-stage QW by introducing the guided quantum walk (GQW) as a bridge between QW-like and QA-like procedures. We assess the performance of the GQW on exact cover, traveling salesperson and garden optimization problems with 9 to 30 qubits. Our results provide evidence for the existence of optimal annealing schedules, beyond the requirement of adiabatic time evolutions. These schedules might be capable of solving large-scale combinatorial optimization problems within evolution times that scale linearly in the problem size.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (28)
  1. M. Marzec, Portfolio Optimization: Applications in Quantum Computing, Handbook of High‐Frequency Trading and Modeling in Finance , 73 (2016).
  2. A. M. Childs and J. Goldstone, Spatial search by quantum walk, Phys. Rev. A 70, 022314 (2004).
  3. R. J. Boucherie, A. Braaksma, and H. Tijms, Operations Research (World Scientific, 2021).
  4. J. Preskill, Quantum Computing in the NISQ era and beyond, Quantum 2, 79 (2018).
  5. Y. Aharonov, L. Davidovich, and N. Zagury, Quantum random walks, Phys. Rev. A 48, 1687 (1993).
  6. B. Apolloni, C. Carvalho, and D. de Falco, Quantum stochastic optimization, Stoch. Process. Their Appl. 33, 233 (1989).
  7. T. Kadowaki and H. Nishimori, Quantum annealing in the transverse Ising model, Phys. Rev. E 58, 5355 (1998).
  8. T. Albash and D. A. Lidar, Adiabatic quantum computation, Rev. Mod. Phys. 90, 015002 (2018a).
  9. T. Albash and D. A. Lidar, Demonstration of a Scaling Advantage for a Quantum Annealer over Simulated Annealing, Phys. Rev. X 8, 031016 (2018b).
  10. T. Neuhaus, Monte Carlo Search for Very Hard KSAT Realizations for Use in Quantum Annealing, arXiv:1412.5361 [cond-mat.stat-mech] (2014a).
  11. T. Neuhaus, Quantum Searches in a Hard 2SAT Ensemble, arXiv:1412.5460 [quant-ph] (2014b).
  12. Lishan Zeng, Jun Zhang and Mohan Sarovar, Schedule path optimization for adiabatic quantum computing and optimization, Journal of Physics A: Mathematical and Theoretical 10.1088/1751-8113/49/16/165305 (2016).
  13. Yu-Qin Chen and Yu Chen and Chee-Kong Lee and Shengyu Zhang and Chang-Yu Hsieh, Optimizing Quantum Annealing Schedules with Monte Carlo Tree Search enhanced with neural networks, Nature Machine Intelligence 10.1038/s42256-022-00446-y (2022).
  14. V. Choi, Adiabatic Quantum Algorithms for the NP-Complete Maximum-Weight Independent Set, Exact Cover and 3SAT Problems,  (2010), arXiv:1004.2226 [quant-ph] .
  15. G. Dantzig, R. Fulkerson, and S. Johnson, Solution of a Large-Scale Traveling-Salesman Problem, J. Oper. Res. Soc. Am. 2, 393 (1954).
  16. R. Bellman, Dynamic Programming Treatment of the Travelling Salesman Problem, J. ACM 9, 61 (1962).
  17. M. Held and R. M. Karp, A Dynamic Programming Approach to Sequencing Problems, Journal of the Society for Industrial and Applied Mathematics 10, 196 (1962).
  18. A. Lucas, Ising formulations of many NP problems, Front. Phys. 2, 5 (2014).
  19. C. D. Gonzalez Calaza, D. Willsch, and K. Michielsen, Garden optimization problems for benchmarking quantum annealers, Quantum Inf. Process. 20, 305 (2021).
  20. Jülich Supercomputing Centre, JUWELS Cluster and Booster: Exascale Pathfinder with Modular Supercomputing Architecture at Juelich Supercomputing Centre, J. of Large-Scale Res. Facil. 7, A138 (2021).
  21. E. Farhi, J. Goldstone, and S. Gutmann, A Quantum Approximate Optimization Algorithm, arXiv:1411.4028 [quant-ph] (2014).
  22. S. H. Sack and M. Serbyn, Quantum annealing initialization of the quantum approximate optimization algorithm, Quantum 5, 491 (2021).
  23. J. A. Nelder and R. Mead, A Simplex Method for Function Minimization, Comput. J. 7, 308 (1965).
  24. J. Roland and N. J. Cerf, Quantum search by local adiabatic evolution, Phys. Rev. A 65, 042308 (2002).
  25. M. Suzuki, General Decomposition Theory of Ordered Exponentials, Proc. Japan Acad. B 69, 161 (1993).
  26. A. P. Young, S. Knysh, and V. N. Smelyanskiy, Size Dependence of the Minimum Excitation Gap in the Quantum Adiabatic Algorithm, Phys. Rev. Lett. 101, 170503 (2008).
  27. A. P. Young, S. Knysh, and V. N. Smelyanskiy, First-Order Phase Transition in the Quantum Adiabatic Algorithm, Phys. Rev. Lett. 104, 020502 (2010).
  28. S. Schulz, GPU-accelerated simulation of guided quantum walks, Master’s thesis, RWTH Aachen (2022).
Citations (3)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up

Tweets

Sign up for free to view the 1 tweet with 0 likes about this paper.

Sign Up for Free