Objective

Three-Dimensional Steerable Magnetic Field (3DSMF) antenna in laboratory test position.

The Department of Defense (DoD) Base Realignment and Closure (BRAC) process requires environmental restoration and mitigation of millions of acres of former military bases to render them safe before they are returned to public use. Remediation of land contaminated with unexploded ordnance (UXO) entails the detection of buried metallic anomalies. A commonly used sensor for UXO detection is the electromagnetic induction (EMI) metal detector. Conventional EMI metal detectors, using either frequency-domain (FD) or time-domain (TD) eddy current methods, can detect large metal targets such as metal-cased high-metal content mines and UXOs at both shallow and deep depths under a wide range of environmental and soil conditions. However, other metal objects (clutter) commonly found in the environment pose a major problem. Clutter comprises a large fraction of detected anomalies and represents a major cost contribution to UXO clean-up efforts because, in the absence of anomaly classification as UXO or as clutter object, the anomaly must be remediated or dug up. Time-efficient and cost-effective remediation will be realized only when the detected metal targets can be accurately classified, preferably in real- or near real-time.

The project objectives were to develop the Three-Dimensional Steerable Magnetic Field (3DSMF) Sensor System and demonstrate that it directly measures the three components of the magnetic polarizability tensor (MPT) of a metal object for target classification. The 3DSMF Sensor System employs wide bandwidth TD EMI sensor technology originally developed for a landmine detection project for the U.S. Army using custom designed and constructed electronics optimized for metal detection sensitivity and data collection speed.