Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Exploration Geophysics Exploration Geophysics Society
Journal of the Australian Society of Exploration Geophysicists
Shopping Cart: ( empty )
You are here: Home > Journals > EG > EG08120
RESEARCH ARTICLE
Contents Vol 40(1)

A new approach to enhancement of ground penetrating radar target signals by pulse compression

Mahmoud Gaballah 1 3 Motoyuki Sato 2 3
+ Author Affiliations
- Author Affiliations

1 Graduate School of Engineering, Tohoku University, 41 Kawauchi, Aoba-Ku, Sendai, Miyagi 980-0862, Japan.

2 Center for Northeast Asian studies, Tohoku University, 41 Kawauchi, Aoba-Ku, Sendai, Miyagi 980-8576, Japan.

3 Corresponding authors. Email: gaballah@cneas.tohoku.ac.jp, sato@cneas.tohoku.ac.jp

Exploration Geophysics 40(1) 77-84 https://doi.org/10.1071/EG08120
Submitted: 6 September 2008  Accepted: 14 January 2009   Published: 27 February 2009

Abstract

Ground penetrating radar (GPR) is an effective tool for detecting shallow subsurface targets. In many GPR applications, these targets are veiled by the strong waves reflected from the ground surface, so that we need to apply a signal processing technique to separate the target signal from such strong signals. A pulse-compression technique is used in this research to compress the signal width so that it can be separated out from the strong contaminated clutter signals. This work introduces a filter algorithm to carry out pulse compression for GPR data, using a Wiener filtering technique. The filter is applied to synthetic and field GPR data acquired over a buried pipe.

The discrimination method uses both the reflected signal from the target and the strong ground surface reflection as a reference signal for pulse compression. For a pulse-compression filter, reference signal selection is an important issue, because as the signal width is compressed the noise level will blow up, especially if the signal-to-noise ratio of the reference signal is low. Analysis of the results obtained from simulated and field GPR data indicates a significant improvement in the GPR image, good discrimination between the target reflection and the ground surface reflection, and better performance with reliable separation between them. However, at the same time the noise level slightly increases in field data, due to the wide bandwidth of the reference signal, which includes the higher-frequency components of noise. Using the ground-surface reflection as a reference signal we found that the pulse width could be compressed and the subsurface target reflection could be enhanced.

Key words: clutter, deconvolution, GPR, pulse compression, reference signal, Wiener filter.


Acknowledgment

The author thanks the Japanese Society for the Promotion of Science (JSPS) as a part of this work was supported by JSPS Grant-in-Aid for Scientific Research (S) 18106008.


References

Bancroft J. C. , 2002, Introduction to matched filters. CREWES Research Report, volume 14.

Caldecott R. , Young J. D. , Hall J. P. , and Terzuoli A. J., 1985, An underground obstacle detection and mapping system. Tech. Rep. EL-3984, ElectroSci. Lab., The Ohio State Univ. and the Elect. Power Res. Inst., Palo Alto, CA.

Curlander J. C. , and McDonough R. N. , 1991, Synthetic Aperture Radar Systems & Signal Processing, John Wiley & Sons, New York, pp. 126–152.

Daniels D. J., 1996, Surface Penetrating Radar. IEE, London. GPRMAX-2D, 2005, Electromagnetic simulator for Ground Probing Radar, V.2.0.

Mertins A. , 1999, Signal Analysis, John Wiley and Sons Ltd, Chichester.

Nag, S., and Peters, L., 2001, Radar images of penetrable targets generated from ramp profile functions: IEEE Transactions on Antennas and Propagation 49, 32–40.
Crossref | GoogleScholarGoogle Scholar | Roth F. , 2005, Conventional models for landmine identification with ground penetrating radar, Ph.D. dissertation, Delft Univ. Technology., Delft, The Netherlands.

Roth F. , Van Genderen P. , and Verhaegen M. , 2003, Processing and analysis of polarimetric ground penetrating radar landmine signatures, in Proc. of the 2nd Int. Workshop on Advanced Ground Penetrating Radar, Delft, The Netherlands, pp. 70–75.

Savelyev, T. G., and Sato, M., 2004, Comparative analysis of UWB deconvolution and feature extraction algorithms for GPR landmine detection. Detection and Remediation Technologies for Mines and Minelike Targets IX: Proceedings of the Society for Photo-Instrumentation Engineers 5415, 1008–1018.
Stearns D. S. , 2003, Digital Signal Processing, CRC Press, New York.

Tanaka R. , and Sato M. , 2004, A GPR System Using a Broadband Passive Optical Sensor for Land Mine Detection; 10th International Conference on Ground Penetrating Radar, 21–24 June, Delft, Netherlands.

van der Merwe, A., and Gupta, I. J., 2000, A novel signal processing technique for clutter reduction in GPR measurements of small, shallow mines: IEEE Transactions Geoscience Remote Sensing 38, 2627–2637.
Crossref | GoogleScholarGoogle Scholar | Wehner D. R. , 1995, High-Resolution Radar, 2nd edn., Artech House, Norwood, pp. 72–75.