1887
1st Australasian Exploration Geoscience Conference – Exploration Innovation Integration
  • ISSN: 2202-0586
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Abstract

Ground penetrating radar (GPR) is unique amongst geophysical tools in terms of its imaging resolution and the diversity of its applications. Since its commercialisation four decades ago, GPR has also been distinguished because of the prevalence of some of its purveyors to oversell the method’s capabilities, relying largely on the end users’ lack of understanding of the underlying physics. Early adopters in the 1980s and 90s were dismayed to find that environments suitable for its purported ubiquitous deep penetration capabilities were rare and that it required resistivities well into the 1000s of Ohm m. Regardless of the advances made in electronics and antenna design in the intervening decades, the fundamental limitations have not changed.

Misconceptions, “specsmanship” and hype have continued to abound in the GPR marketplace, particularly in recent years. Systems purporting to penetrate hundreds of metres using “megawatt” transmitters from the former Eastern Bloc have been promoted for mineral exploration, particularly in Australia and Africa. Other pseudo-radar concepts, such as the use of beam forming to achieve kilometres of penetration with centimetre accuracy, or THz laser scanners which can detect individual diamonds deep underground, have generally targeted junior exploration groups who lack in-house geophysical guidance.

This work provides an overview of the fundamentals of non-dispersive EM wave propagation in the ground and an examination of the recent published performance claims of some GPR and pseudo-GPR systems within the context of accepted EM theory. The accepted methods for potentially increasing GPR performance, given the emerging technologies such as novel transmitter and receiver designs and new GPR antennas, are also discussed.

© 2018 ASEG
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2018-12-01
2026-01-21

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References

  1. Annan, A. P., 2002, GPR - History, trends, and future developments: Subsurface Sensing Technologies and Applications, 3(4), 253270.
  2. Annan, A. P., and Chua, L. T., 1992, Ground penetrating radar performance predictions in Ground penetrating radar: Geological Survey of Canada.
  3. Annan, P., 1996, Transmission dispersion and GPR: Journal of Environmental and Engineering Geophysics, 1(B), 125-136. The Brisbane Courier, 1911, Science News, September 2, 12.
  4. Cabrera, R. A., 2011, GPR antenna resolution: Retrieved 31 August 2017 from Geoscanners A.B.: http://www.geoscanners.com/appnotes/antres.pdf
  5. Capital Consulting Corporation Ltd., 2016, CCC Exploration Ltd. Retrieved 31 August 2017 from CCC Exploration Ltd: https://www.cccexploration.com/process-zae5v
  6. Chisholm, W., 1998, Inventor gives archaeologists detector which sees for miles: The Scotsman, 28 Aug 1998. Daniels, D., 2005, Ground penetrating radar: John Wiley & Sons, Inc.
  7. Daniels, D., and Utsi, E., 2013, GPR case histories and known physical principles: Advanced Ground Penetrating Radar (IWAGPR), 2013 7th International Workshop on, IEEE, Nantes, France, 1-9.
  8. Elsheakh, D., and Abdallah, E., 2013, Novel shapes of Vivaldi antenna for ground penetrating radar (GPR): Antennas and Propagation
  9. (EuCAP), 2013 7th European Conference on, IEEE, Goteborg, Sweden, 2886-2889.
  10. Francke, J., 2016, The application of long-range GPR for seismic static corrections: Ground Penetrating Radar (GPR), 2016 16th International Conference on, IEEE, Hong Kong.
  11. Guangyou, F., and Pipan, M., 2004, Designing of a low frequency ultra wideband (UWB) antenna and its application in ground penetrating radar (GPR) system: Ground Penetrating Radar, 2004. GPR 2004. Proceedings of the Tenth International Conference on, IEEE, Delft, Netherlands, 109-111.
  12. Hodges, G., 2011, 6 May, There’s a dark side to geophysics: The Northern Miner. Jol, H., 2008, Ground penetrating radar theory and applications: Elsevier, Amsterdam.
  13. Leat, P., 2003, An investigation of magnetic antennas for ground penetrating radar: Progress In Electromagnetics Research, 43, 257-271.
  14. Lestari, A. A., Yarovoy, A., and Ligthart, L., 2004, RC-loaded bow-tie antenna for improved pulse radiation. IEEE transactions on Antennas and Propagation, 2555-2563.
  15. McCann, W. A., 1995, GPR and archaeology in central London: Archaeological Prospection, 155-166.
  16. Morey, R. M., 1974, Continuous subsurface profiling by impulse radar: Proceedings, Engineering Foundation Conference on Subsurface Exploration of Underground Excavation and Heavy Construction, Heuniker, N.H., 213-232.
  17. Rao, B., Ferris, J., and Zimmerian, W, 1969, Broadband characteristics of cylindrical antennas with exponentially tapered capacitive loading: IEEE Transactions on Antennas and Propagation, 145-151.
  18. Reeves, B., 2014, Noise modulated GPR: Second generation technology: 15th International Conference on Ground Penetrating Radar, 2014, IEEE, Brussels, Belgium.
  19. Revolution Metals Ltd., 2017, 23 July, Revolution Metals Ltd begins ultramag deep ground penetrating radar (GPR) at the Mt Remarkable Gold Deposit: Retrieved 28 August 2017, from Revolution Metals Ltd:
  20. http://www.revolutionmetals.com/pr/71591/Revolution Metals Ltd Begins ULTRAMAG Deep Ground Penetrating Radar (DG PR) At The Mt Remarkable Gold Deposit
  21. Shlager, K., Smith, G., and Maloney, J., 1994, Optimization of bow-tie antennas for pulse radiation: IEEE Transactions on Antennas and Propagation, 975-982.
  22. Stove, G. C., and Addyman, P. V., 1989, Ground probing impulse radar: an experiment in archaeological remote sensing at York, Antiquity, 337-342.
  23. Stove, G. D., Stove, G. C., and Robinson, M. J., 2013, Methods for determining material and/or subsurface composition: United States Patent No. US20150153470A1.
  24. Stove, G., & van den Doel, K., 2015, Large depth exploration using pulsed radar: ASEG Extended Abstracts 2015, ASEG, Perth, Australia, 1-4.
  25. Sugak, V., Klochko, G., and Koropets, E., 2007, Large current antennas in GPR applications: Electromagnetic Phenomena, 7(1), 170-173.
  26. Terravision Radar Ltd, 2016, Terravision radar: Retrieved 31 August 2017 from Terravision Radar: https://www.terravisionradar.com/details
  27. Ultramag Geophysics, 2016, Ultramag Geophysics DGPR: Retrieved 31 August 2017 from Ultramag Geophysics: http://www.ultramag.com/ultramag-dgpr.html
  28. Ultramag Geophysics, 2017, Brochure - Ultramag deep ground penetrating radar, mineral exploration examples.
  29. Utsi, V, 2007, Design of a GPR for deep investigations: 4th International Workshop on Advanced Ground Penetrating Radar, 2007, IEEE, Naples, Italy, 222-225.
  30. Vance, A., 2000, The Scot hired by Fidel Castro to dive for his sunken treasure ships: The Scotsman, 29 Sep 2000. Vance, A., 2004, Beagle-eye radar firm finds Darwin’s ship: The Scotsman, 24 Feb 2004. Waldemar, I., 1931, Transmitter: United States of America Patent No. US2002181 A.
  31. Xia, Z., Zhang, Q., Ye, S., Wang, Y., Chen, C., Yin, H., and Fang, G. (2015). A novel low-frequency coded ground penetrating radar for deep detection: IEICE Electronics Express, 12(11).
/content/journals/10.1071/ASEG2018abM2_3E
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  • Article Type: Research Article
Keyword(s): ground penetrating radar; megawatt transmitter

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