Classification of unexploded ordnance-like targets with characteristic response in transient electromagnetic sensing

Chen, S.; Jiang, Hua; Zhu, Jun; Qiu, Yu; Zhang, S.

doi:10.1088/1748-0221/14/10/p10011

Cited by 8 publications

(4 citation statements)

References 20 publications

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“…Currently, detailed magnetic observations for geological surveys [ 13 , 14 ], unexploded ordnance detection [ 82 , 83 ], magnetic anomaly detection (e.g., of submarines or sea mines) [ 84 ], and other applications [ 5 , 11 ] are primarily conducted using magnetometers on manned vehicles, be they land-based [ 5 , 85 ], aircraft [ 83 , 86 , 87 ], ships [ 88 , 89 ], or underwater vehicles [ 90 ]. Manned aircraft are relatively large and able to generate significantly higher power than UAVs, making them suitable platforms for high-sensitivity airborne magnetometer solutions, such as the SQUID-based tensor magnetic gradient measurement system “UXOMAX” [ 91 ].…”

Section: Existing Applicationsmentioning

confidence: 99%

Precision Magnetometers for Aerospace Applications: A Review

Bennett

Vyhnalek

Greenall

et al. 2021

Sensors

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Aerospace technologies are crucial for modern civilization; space-based infrastructure underpins weather forecasting, communications, terrestrial navigation and logistics, planetary observations, solar monitoring, and other indispensable capabilities. Extraplanetary exploration—including orbital surveys and (more recently) roving, flying, or submersible unmanned vehicles—is also a key scientific and technological frontier, believed by many to be paramount to the long-term survival and prosperity of humanity. All of these aerospace applications require reliable control of the craft and the ability to record high-precision measurements of physical quantities. Magnetometers deliver on both of these aspects and have been vital to the success of numerous missions. In this review paper, we provide an introduction to the relevant instruments and their applications. We consider past and present magnetometers, their proven aerospace applications, and emerging uses. We then look to the future, reviewing recent progress in magnetometer technology. We particularly focus on magnetometers that use optical readout, including atomic magnetometers, magnetometers based on quantum defects in diamond, and optomechanical magnetometers. These optical magnetometers offer a combination of field sensitivity, size, weight, and power consumption that allows them to reach performance regimes that are inaccessible with existing techniques. This promises to enable new applications in areas ranging from unmanned vehicles to navigation and exploration.

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Section: Existing Applicationsmentioning

confidence: 99%

Precision Magnetometers for Aerospace Applications: A Review

Bennett

Vyhnalek

Greenall

et al. 2021

Sensors

View full text Add to dashboard Cite

show abstract

“…Currently, detailed magnetic observations for geological surveys [13,14], unexploded ordnance detection [133,134], magnetic anomaly detection (e.g., of submarines or sea mines) [135], and other applications [5,11] are primarily conducted using magnetometers on manned vehicles, be they land-based [5,136], aircraft [134,137,138], ships [139,140], or underwater vehicles [141]. Manned aircraft are relatively large and able to generate significantly higher power than UAVs, making them suitable platforms for high-sensitivity airborne magnetometer solutions, such as the SQUID-based tensor magnetic gradient measurement system UXOMAX [142].…”

Section: Magnetometers In Manned Aerial Vehiclesmentioning

confidence: 99%

Precision Magnetometers for Aerospace Applications

Bennett,

Vyhnalek,

Greenall

et al. 2021

Preprint

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Aerospace technologies are crucial for modern civilization; space-based infrastructure underpins weather forecasting, communications, terrestrial navigation and logistics, planetary observations, solar monitoring, and other indispensable capabilities. Extraplanetary exploration -including orbital surveys and (more recently) roving, flying, or submersible unmanned vehicles -is also a key scientific and technological frontier, believed by many to be paramount to the long-term survival and prosperity of humanity. All of these aerospace applications require reliable control of the craft and the ability to record high-precision measurements of physical quantities. Magnetometers deliver on both of these aspects, and have been vital to the success of numerous missions. In this review paper, we provide an introduction to the relevant instruments and their applications. We consider past and present magnetometers, their proven aerospace applications, and emerging uses. We then look to the future, reviewing recent progress in magnetometer technology. We particularly focus on magnetometers that use optical readout, including atomic magnetometers, magnetometers based on quantum defects in diamond, and optomechanical magnetometers. These optical magnetometers offer a combination of field sensitivity, size, weight, and power consumption that allows them to reach performance regimes that are inaccessible with existing techniques. This promises to enable new applications in areas ranging from unmanned vehicles to navigation and exploration.

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“…In terms of data processing, traditional detection methods usually store measurement data on hardware [4][5][6] . This system employs an ARM+FPGA dual-core system for real-time data acquisition and processing.…”

Section: Introductionmentioning

confidence: 99%

Real-time Detection System for Portable Transient Electromagnetic Unexploded Ordnance

Tang,

Zeng,

Wang

et al. 2023

J. Phys.: Conf. Ser.

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Portable transient electromagnetic systems are not limited by terrain and can detect unexploded ordnance very flexibly. However, existing data processing methods are slow and cannot achieve real-time positioning of targets. In this paper, based on a laboratory-made portable transient electromagnetic detection system, the magnetic dipole model and tensor positioning algorithm are used to achieve fast and accurate target positioning. Using the magnetic gradient tensor algorithm for positioning reduces the calculation load, allowing it to run on embedded systems, and improving target positioning speed while ensuring the accuracy of measurements. Experimental results show that the vertical and horizontal positioning errors of the UXO are within 10 cm, and single-point positioning can be completed within 10 ms.

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Classification of unexploded ordnance-like targets with characteristic response in transient electromagnetic sensing

Cited by 8 publications

References 20 publications

Precision Magnetometers for Aerospace Applications: A Review

Precision Magnetometers for Aerospace Applications: A Review

Precision Magnetometers for Aerospace Applications

Real-time Detection System for Portable Transient Electromagnetic Unexploded Ordnance

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