• Baum, C. E. (1999), Detection and Identification of Visually Obscured Targets, Taylor and Francis, Philadelphia, Pa.
  • Bell, T. H., B. Barrow, and N. Khadr (1998), Shape-based classification and discrimination of subsurface objects using electromagnetic induction, paper presented at International Geoscience and Remote Sensing Symposium (IGARS '98), Geosci. and Remote Sens. Soc., Seattle, Wash.
  • Candy, B. H. (1996), Pulse induction time domain metal detector, Patent 5576624, U.S. Patent and Trademark Off., Washington, D. C.
  • Carin, L., H. Yu, Y. Dalichaouch, A. R. Perry, P. V. Czipott, and C. E. Baum (2001), On the wideband EMI response of a rotationally symmetric permeable and conducting target, IEEE Trans. Geosci. Remote Sensing, 39(6), 12061213.
  • Chapman, G. T., and D. B. Kirk (1970), A method for extracting aerodynamic coefficients from free-flight data, AIAA J., 8, 753758.
  • Collins, L., P. Gao, and L. Carin (1999), An improved Bayesian decision theoretic approach for land mine detection, IEEE Trans. Geosci. Remote Sens., 37(2), 811819.
  • Corbyn, J. A. (1980), Pulse induction metal detector, Wireless World, 86, 4044.
  • Das, Y., J. D. Toews, K. Russell, and S. Lewis (2000), Results of in-air testing of metal detectors, Tech. Rep., Def. Res. Estab., Suffield, Ottawa, Ont.
  • Grant, F. S., and G. F. West (1965), Interpretation Theory in Applied Geophysics, McGraw-Hill, New York.
  • Kingdon, J., N. Khadr, T. Bell, and L. Riggs (2004), Development of an electromagnetic induction sensor for land mine discrimination, paper presented at SAGEEP 2004 Conference, Environ. and Eng. Geophys. Soc., Colorado Springs, Colo., 22 – 26 Feb.
  • Liao, X., and L. Carin (2004), Application of the theory of optimal experiments to adaptive electromagnetic-induction sensing of buried targets, IEEE Trans. Pattern Anal. Mach. Intell., in press.
  • Lowe, L. T. (2001), Enhanced land mine discrimination using the multi-axis electromagnetic induction response of a buried finitely conducting object, Ph.D. thesis, Auburn Univ., Auburn, Ala.
  • MacDonald, J., et al. (2003), Alternatives for Land mine Detection, RAND, Santa Monica, Calif.
  • Nelson, C. V., and T. B. Huynh (2001), Wide bandwidth, time decay responses from low-metal mines and ground voids, in Detection and Remediation Technologies for Mines and Minelike Targets, vol. VI, edited by A. C. Dubey et al., pp. 5564, Int. Soc. for Opt. Eng., Bellingham, Wash.
  • Nelson, C. V., C. B. Cooperman, W. Schneider, D. S. Wenstrand, and D. G. Smith (2001), Wide bandwidth time-domain electromagnetic sensor for metal target classification, IEEE Trans. Geosci. Remote Sensing, 39(6), 11291138.
  • Riggs, L. S. (1999), Red team final report: Comparison of the sensitivity of five commonly used metal detectors, Final Rep., U.S. Army CECOM RDEC, Night Vision and Electron. Sensors Dir., Fort Belvoir, Va.
  • Riggs, L. S., J. E. Mooney, and D. E. Lawrence (2001), Identification of metallic mine-like objects using low frequency magnetic fields, IEEE Trans. Geosci. Remote Sensing, 39(1), 5666.
  • Srinath, M. D., P. K. Rajasekaran, and R. Viswanathan (1996), Introduction to Statistical Signal Processing with, Prentice-Hall, Old Tappan, N. J.
  • Vantrees, H. (1968), Detection, Estimation, and Modulation Theory, John Wiley, Hoboken, N. J.
  • Won, I. J., D. A. Keiswetter, D. R. Hansen, E. Novikova, and T. Hall (1997), GEM-3: A monostatic broadband electromagnetic induction sensor, J. Environ. Eng. Geophys., 2, 5364.