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QuERLoc: Towards Next-Generation Localization with Quantum-Enhanced Ranging

Published 25 Apr 2024 in cs.ET | (2404.16895v3)

Abstract: Remarkable advances have been achieved in localization techniques in past decades, rendering it one of the most important technologies indispensable to our daily lives. In this paper, we investigate a novel localization approach for future computing by presenting QuERLoc, the first study on localization using quantum-enhanced ranging. By fine-tuning the evolution of an entangled quantum probe, quantum ranging can output the information integrated in the probe as a specific mapping of distance-related parameters. QuERLoc is inspired by this unique property to measure a special combination of distances between a target sensor and multiple anchors within one single physical measurement. Leveraging this capability, QuERLoc settles two drawbacks of classical localization approaches: (i) the target-anchor distances must be measured individually and sequentially, and (ii) the resulting optimization problems are non-convex and are sensitive to noise. We first present the theoretical formulation of preparing the probing quantum state and controlling its dynamic to induce a convexified localization problem, and then solve it efficiently via optimization. We conduct extensive numerical analysis of QuERLoc under various settings. The results show that QuERLoc consistently outperforms classical approaches in accuracy and closely follows the theoretical lowerbound, while maintaining low time complexity. It achieves a minimum reduction of 73% in RMSE and 97.6% in time consumption compared to baselines. By introducing range-based quantum localization to the mobile computing community and showing its superior performance, QuERLoc sheds light on next-generation localization technologies and opens up new directions for future research.

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References (45)
  1. 2000. Handbook of Semidefinite Programming. Springer US.
  2. 2006. Lectures on Quantum Information. Wiley.
  3. Semidefinite Programming Approaches for Sensor Network Localization With Noisy Distance Measurements. IEEE Transactions on Automation Science and Engineering 3, 4 (2006), 360–371.
  4. Quantum Fingerprinting. Phys. Rev. Lett. 87 (Sep 2001), 167902. Issue 16.
  5. Indoor localization without the pain. In Proceedings of the sixteenth annual international conference on Mobile computing and networking (MobiCom’10). ACM, 293–304.
  6. Efficient Use of Quantum Resources for the Transmission of a Reference Frame. Phys. Rev. Lett. 93 (Oct 2004), 180503. Issue 18.
  7. Robust Quantum Control by a Single-Shot Shaped Pulse. Phys. Rev. Lett. 111 (Jul 2013). Issue 5.
  8. Joachim Dahl. 2012. Semidefinite optimization using MOSEK. ISMP, Berlin (2012).
  9. Steven Diamond and Stephen Boyd. 2016. CVXPY: a python-embedded modeling language for convex optimization. J. Mach. Learn. Res. 17, 1 (jan 2016), 2909–2913.
  10. Domenico D’Alessandro. 2021. Introduction to Quantum Control and Dynamics. Chapman and Hall/CRC.
  11. Quantum-enhanced positioning and clock synchronization. Nature 412, 6845 (July 2001), 417–419.
  12. Quantum-Enhanced Measurements: Beating the Standard Quantum Limit. Science 306, 5700 (Nov. 2004), 1330–1336.
  13. Quantum Metrology. Phys. Rev. Lett. 96 (Jan 2006), 010401. Issue 1.
  14. Advances in quantum metrology. Nature Photonics 5, 4 (March 2011), 222–229.
  15. Effect of control procedures on the evolution of entanglement in open quantum systems. Physical Review A 85, 1 (Jan. 2012).
  16. Lov K. Grover. 1997. Quantum Mechanics Helps in Searching for a Needle in a Haystack. Phys. Rev. Lett. 79 (Jul 1997), 325–328. Issue 2.
  17. Quantum Zeno effect. Phys. Rev. A 41 (Mar 1990), 2295–2300. Issue 5.
  18. A Faster Interior Point Method for Semidefinite Programming. In 2020 IEEE 61st Annual Symposium on Foundations of Computer Science (FOCS). IEEE.
  19. Quantum Transfer Learning for Wi-Fi Sensing. In ICC 2022 - IEEE International Conference on Communications.
  20. SpotFi: Decimeter Level Localization Using WiFi. In Proceedings of the 2015 ACM Conference on Special Interest Group on Data Communication (SIGCOMM ’15). ACM, 269–282.
  21. A new constrained weighted least squares algorithm for TDOA-based localization. Signal Processing 93, 11 (Nov. 2013), 2872–2878.
  22. Energy efficient GPS sensing with cloud offloading. In Proceedings of the 10th ACM Conference on Embedded Network Sensor Systems (SenSys ’12). ACM, 85–98.
  23. Nonlinear Evolution of Quantum States in the Adiabatic Regime. Phys. Rev. Lett. 90 (May 2003), 170404. Issue 17.
  24. Distributed quantum phase estimation with entangled photons. Nature Photonics 15, 2 (Nov. 2020), 137–142.
  25. Wireless sensor network localization techniques. Computer Networks 51, 10 (July 2007), 2529–2553.
  26. Thermometry in the quantum regime: recent theoretical progress. Journal of Physics A: Mathematical and Theoretical 52, 30 (July 2019), 303001.
  27. Perturbation theory with quantum signal processing. Quantum 7 (May 2023), 1000.
  28. Michael A. Nielsen and Isaac L. Chuang. 2012. Quantum Computation and Quantum Information: 10th Anniversary Edition. Cambridge University Press.
  29. Luca Pezzé and Augusto Smerzi. 2014. Quantum theory of phase estimation. arXiv preprint arXiv:1411.5164 (2014).
  30. Zee: zero-effort crowdsourcing for indoor localization. In Proceedings of the 18th annual international conference on Mobile computing and networking (Mobicom’12). ACM, 293–304.
  31. Jorma J Rissanen. 1996. Fisher information and stochastic complexity. IEEE transactions on information theory 42, 1 (1996), 40–47.
  32. Localization from mere connectivity. In Proceedings of the 4th ACM International Symposium on Mobile Ad Hoc Networking & Computing (MobiHoc ’03). ACM, 201–212.
  33. Moshe Shapiro and Paul Brumer. 2006. Quantum control of bound and continuum state dynamics. Physics Reports 425, 4 (March 2006), 195–264.
  34. Ahmed Shokry and Moustafa Youssef. 2022. A Quantum Algorithm for RF-based Fingerprinting Localization Systems. In 2022 IEEE 47th Conference on Local Computer Networks (LCN). IEEE.
  35. Anthony Man-Cho So and Yinyu Ye. 2006. Theory of semidefinite programming for Sensor Network Localization. Mathematical Programming 109, 2–3 (Sept. 2006), 367–384.
  36. Paul Tseng. 2007. Second‐Order Cone Programming Relaxation of Sensor Network Localization. SIAM Journal on Optimization 18, 1 (Jan. 2007), 156–185.
  37. Sabine Van Huffel and Hongyuan Zha. 1993. The total least squares problem. Elsevier, 377–408.
  38. Noise Tolerant Localization for Sensor Networks. IEEE/ACM Transactions on Networking 26, 4 (Aug. 2018), 1701–1714.
  39. Iterative Localization of Wireless Sensor Networks: An Accurate and Robust Approach. IEEE/ACM Transactions on Networking 22, 2 (April 2014), 608–621.
  40. Efficient Convex Relaxation Methods for Robust Target Localization by a Sensor Network Using Time Differences of Arrivals. IEEE Transactions on Signal Processing 57, 7 (2009), 2775–2784.
  41. Beyond trilateration: On the localizability of wireless ad-hoc networks. In IEEE INFOCOM 2009. IEEE.
  42. Ground-based wireless positioning.
  43. Caitao Zhan and Himanshu Gupta. 2023. Quantum Sensor Network Algorithms for Transmitter Localization. In 2023 IEEE International Conference on Quantum Computing and Engineering (QCE). IEEE.
  44. Quantum-Memory-Enhanced Preparation of Nonlocal Graph States. Phys. Rev. Lett. 128 (Feb 2022), 080501. Issue 8.
  45. Junyi Zhou and Jing Shi. 2008. RFID localization algorithms and applications—a review. Journal of Intelligent Manufacturing 20, 6 (Aug. 2008), 695–707.

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