Distributed Quantum Magnetic Sensing for Infrastructure-free Geo-localization
- URL: http://arxiv.org/abs/2512.11300v2
- Date: Mon, 15 Dec 2025 01:37:28 GMT
- Title: Distributed Quantum Magnetic Sensing for Infrastructure-free Geo-localization
- Authors: Thinh Le, Shiqian Guo, Jianqing Liu,
- Abstract summary: We study how quantum magnetic sensing can be used for geo-localization.<n>In high-gradient regions, gradient-space Mahalanobis search achieves sub-kilometer median localization error.<n>In magnetically smoother areas, corner-space search provides better accuracy and a $4-8times$ reduction in runtime.
- Score: 2.9232295049733508
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Modern navigation systems rely heavily on Global Navigation Satellite Systems (GNSS), whose weak spaceborne signals are vulnerable to jamming, spoofing, and line-of-sight blockage. As an alternative, the Earth's magnetic field entails location information and is found critical to many animals' cognitive and navigation behavior. However, the practical use of the Earth's magnetic field for geo-localization hinges on an ultra-sensitive magnetometer. This work investigates how quantum magnetic sensing can be used for this purpose. We theoretically derive the Cramér-Rao lower bound (CRLB) for the estimation error of quantum sensing when using a nitrogen-vacancy (NV) center and prove the quantum advantage over classical magnetometers. Moreover, we employ a practical distributed quantum sensing protocol to saturate CRLB. Based on the estimated magnetic field and the earth's magnetic field map, we formulate geo-localization as a map-matching problem and introduce a coarse-to-fine Mahalanobis distance search in both gradient space (local field derivatives) and corner space (raw field samples). We simulate the proposed quantum sensing-based geo-localization framework over four cities in the United States and Canada. The results report that in high-gradient regions, gradient-space Mahalanobis search achieves sub-kilometer median localization error; while in magnetically smoother areas, corner-space search provides better accuracy and a $4-8\times$ reduction in runtime.
Related papers
- Physics-informed Diffusion Generation for Geomagnetic Map Interpolation [46.1541319960911]
We propose a Physics-informed Diffusion Generation framework to interpolate incomplete geomagnetic maps.<n>First, we design a physics-informed mask strategy to guide the diffusion generation process based on a local receptive field.<n>Second, we impose a physics-informed constraint on the diffusion generation results following the kriging principle of geomagnetic maps.
arXiv Detail & Related papers (2026-01-31T13:10:47Z) - Optimal and efficient inference tools for field tracking with precessing spins [35.18016233072556]
Spin-precession magnetometer (SPM) observes electron, nucleus, color center, or muon spins as they precess in response to their local magnetic field.<n>We show that it is sufficient to accurately track fluctuating and unknown transient signals.<n>Our methods can be easily adapted to other types of sensors undergoing nonlinear dissipative dynamics.
arXiv Detail & Related papers (2025-10-13T19:44:33Z) - Bias-field-free operation of nitrogen-vacancy ensembles in diamond for accurate vector magnetometry [0.0]
Nitrogen-vacancy center spin ensembles offer a promising solution for high-sensitivity vector magnetometry.<n> bias magnetic field typically used to separate signals from each NV orientation introduces inaccuracy from drifts in permanent magnets or coils.<n>We present a novel bias-field-free approach that labels the NV orientations via the direction of the microwave (MW) field in a variable-pulse-duration Ramsey sequence.
arXiv Detail & Related papers (2025-05-30T13:26:10Z) - Long-distance Geomagnetic Navigation in GNSS-denied Environments with Deep Reinforcement Learning [62.186340267690824]
Existing studies on geomagnetic navigation rely on pre-stored map or extensive searches, leading to limited applicability or reduced navigation efficiency in unexplored areas.
This paper develops a deep reinforcement learning (DRL)-based mechanism, especially for long-distance geomagnetic navigation.
The designed mechanism trains an agent to learn and gain the magnetoreception capacity for geomagnetic navigation, rather than using any pre-stored map or extensive and expensive searching approaches.
arXiv Detail & Related papers (2024-10-21T09:57:42Z) - A Bionic Data-driven Approach for Long-distance Underwater Navigation with Anomaly Resistance [59.21686775951903]
Various animals exhibit accurate navigation using environment cues.
Inspired by animal navigation, this work proposes a bionic and data-driven approach for long-distance underwater navigation.
The proposed approach uses measured geomagnetic data for the navigation, and requires no GPS systems or geographical maps.
arXiv Detail & Related papers (2024-02-06T13:20:56Z) - Quantum magnetometry using discrete-time quantum walk [2.732919960807485]
We propose a scheme for quantum magnetometry using discrete-time quantum walk (DTQW)
The dynamics of a spin-half particle implementing DTQW on a one-dimensional lattice gets affected by magnetic fields.
We find that one can use the position and spin measurements to estimate the strengths of the magnetic fields.
arXiv Detail & Related papers (2023-11-27T13:23:33Z) - Position fixing with cold atom gravity gradiometers [56.45088569868981]
We propose a position fixing method for autonomous navigation using partial gravity gradient solutions from cold atom interferometers.
Using standard open source global gravity databases, we show stable navigation solutions for trajectories of over 1000km.
arXiv Detail & Related papers (2022-04-11T16:42:32Z) - DC Quantum Magnetometry Below the Ramsey Limit [68.8204255655161]
We demonstrate quantum sensing of dc magnetic fields that exceeds the sensitivity of conventional $Tast$-limited dc magnetometry by more than an order of magnitude.
We used nitrogen-vacancy centers in a diamond rotating at periods comparable to the spin coherence time, and characterize the dependence of magnetic sensitivity on measurement time and rotation speed.
arXiv Detail & Related papers (2022-03-27T07:32:53Z) - Magnetic Field Prediction Using Generative Adversarial Networks [0.0]
We predict magnetic field values at a random point in space by using a generative adversarial network (GAN) structure.
The deep learning (DL) architecture consists of two neural networks: a generator, which predicts missing field values of a given magnetic field, and a critic, which is trained to calculate the statistical distance between real and generated magnetic field distributions.
Our trained generator has learned to predict the missing field values with a median reconstruction test error of 5.14%, when a single coherent region of field points is missing, and 5.86%, when only a few point measurements in space are available.
arXiv Detail & Related papers (2022-03-14T12:31:54Z) - Vector DC magnetic-field sensing with reference microwave field using
perfectly aligned nitrogen-vacancy centers in diamond [0.0]
We propose a method to measure vector DC magnetic fields using perfectly aligned NV centers without reference DC magnetic fields.
Our method of using a reference microwave field is a novel technique for sensitive vector DC magnetic-field sensing.
arXiv Detail & Related papers (2021-12-01T14:05:10Z) - Multiclass Permanent Magnets Superstructure for Indoor Localization
using Artificial Intelligence [1.3048920509133808]
Smartphones have become a popular tool for indoor localization and position estimation of users.
Existing solutions mainly employ Wi-Fi, RFID, and magnetic sensing techniques to track movements in crowded venues.
We present an extended version of that algorithm for multi-superstructure localization, which covers a broader localization area of the user.
arXiv Detail & Related papers (2021-07-14T09:59:58Z) - Surpassing the Energy Resolution Limit with ferromagnetic torque sensors [55.41644538483948]
We evaluate the optimal magnetic field resolution taking into account the thermomechanical noise and the mechanical detection noise at the standard quantum limit.
We find that the Energy Resolution Limit (ERL), pointed out in recent literature, can be surpassed by many orders of magnitude.
arXiv Detail & Related papers (2021-04-29T15:44:12Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.