Hardware-in-the-loop Simulation Testbed for Geomagnetic Navigation

TL;DR

This paper introduces a cost-effective hardware-in-the-loop testbed that synthesizes geomagnetic fields for experimental validation of geomagnetic navigation systems, reducing reliance on expensive real-world testing.

Contribution

It develops a novel, low-cost simulation platform combining hardware and software to generate controllable geomagnetic environments for navigation research.

Findings

Testbed accurately simulates geomagnetic fields

Achieves stable and uniform magnetic field generation

Enables cost-effective lab-based navigation experiments

Abstract

Geomagnetic navigation leverages the ubiquitous Earth's magnetic signals to navigate missions, without dependence on GPS services or pre-stored geographic maps. It has drawn increasing attention and is promising particularly for long-range navigation into unexplored areas. Current geomagnetic navigation studies are still in the early stages with simulations and computational validations, without concrete efforts to develop cost-friendly test platforms that can empower deployment and experimental analysis of the developed approaches. This paper presents a hardware-in-the-loop simulation testbed to support geomagnetic navigation experimentation. Our testbed is dedicated to synthesizing geomagnetic field environment for the navigation. We develop the software in the testbed to simulate the dynamics of the navigation environment, and we build the hardware to generate the physical magnetic field, which follows and aligns with the simulated environment. The testbed aims to provide controllable magnetic field that can be used to experiment with geomagnetic navigation in labs, thus avoiding real and expensive navigation experiments, e.g., in the ocean, for validating navigation prototypes. We build the testbed with off-the-shelf hardware in an unshielded environment to reduce cost. We also develop the field generation control and hardware parameter optimization for quality magnetic field generation. We conduct a detailed performance analysis to show the quality of the field generation by the testbed, and we report the experimental results on performance indicators, including accuracy, uniformity, stability, and convergence of the generated field towards the target geomagnetic environment.