Through-Wall Imaging With UWB Radar System - KEMT FEI TUKE
Through-Wall Imaging With UWB Radar System - KEMT FEI TUKE
Through-Wall Imaging With UWB Radar System - KEMT FEI TUKE
Create successful ePaper yourself
Turn your PDF publications into a flip-book with our unique Google optimized e-Paper software.
BIBLIOGRAPHY 105<br />
[115] J. Sachs, M. Aftanas, S. Crabbe, M. Drutarovsky, R. Klukas, D. Kocur, T. Nguyen, P. Peyerl,<br />
J. Rovnakova, and E. Zaikov, “Detection and Tracking of Moving or Trapped People<br />
Hidden by Obstacles using Ultra-Wideband Pseudo-Noise <strong>Radar</strong>,” 5th European <strong>Radar</strong><br />
Conference, EuRAD 2008, pp. 408–411, Oct. 2008.<br />
[116] J. Sachs, P. Peyerl, P. Rauschenbach, F. Tkac, M. Kmec, and S. Crabbe, “Integrated<br />
Digital <strong>UWB</strong>-<strong>Radar</strong>,” Amerem 2002, pp. 507–514, Juny 2002.<br />
[117] J. Sachs, P. Peyerl, and M. Rossberg, “A New <strong>UWB</strong>-Principle for Sensor-Array Application,”<br />
IEEE proceedings of IMTC/99, vol. 3, May 1999.<br />
[118] J. Sachs, P. Peyerl, R. Zetik, and S. Crabbe, “M-Sequence Ultra-Wideband-<strong>Radar</strong>: State<br />
of Development and Applications,” <strong>Radar</strong> 2003, Adelaide (Australia), pp. 224–229, Sep.<br />
2003.<br />
[119] F. Sagnard and G. E. Zein, “In Situ Characterization of Building Materials for Propagation<br />
Modeling: Frequency and Time Responses,” IEEE Transactions on Antennas and<br />
Propagation, vol. 53, pp. 3166–3173, Oct. 2005.<br />
[120] T. Sakamoto and T. Sato, “A target shape estimation algorithm for pulse radar systems<br />
based on Boundary Scattering Transform,” IEICE Transactions on Communications,<br />
vol. 87, pp. 1357–1365, May 2004.<br />
[121] ——, “A fast algorithm of 3-dimensional imaging for pulse radar systems,” IEEE AP-S<br />
International Symposium and USNC/URSI National Radio Science Meeting, vol. 3, pp.<br />
2099–2102, June 2004.<br />
[122] P. C. Sava, “Prestack residual migration in the frequency domain,” Geophysics, vol. 68,<br />
pp. 634–640, Mar. 2003.<br />
[123] T. Savelyev, L. van Kempen, and H. Sahli, “GPR Antipersonnel Mine Detection: Improved<br />
Deconvolution and Time-Frequency Feature Extraction,” SPIE, Nondestructive Evaluation<br />
and Health Monitoring of Aerospace Materials and Composites II, vol. 5046, pp. 232–241,<br />
2003, san Diego, USA.<br />
[124] J. A. Scales, Theory of Seismic <strong>Imaging</strong>. New York: Springer, Jan. 1995.<br />
[125] B. Scheers, “Ultra-wideband ground penetrating radar, with application to the detection of<br />
anti personnel landmines,” Ph.D. dissertation, Universit Catholique de Louvain, Belgium,<br />
2001.<br />
[126] B. Scheers, M. Archeroy, and A. V. Vander, “Time-domain modeling of <strong>UWB</strong> GPR and<br />
its application to land mine detection,” SPIE, Detection and Remediation Technologies for<br />
Mines and Minelike Targets V, vol. 4038, pp. 1452–1460, Aug. 2000, orlando, FL, USA.<br />
[127] R. O. Schmidt, “Multiple emitter location and signal parameter estimation,” IEEE Trans.,<br />
vol. 34, pp. 276–280, Mar. 1986.<br />
[128] W. S. Schneider, “Integral formulation for migration in two or three dimensions,” Geophysics,<br />
vol. 43, pp. 49–76, 1978.<br />
[129] L. G. Shapiro and G. Stockman, Computer Vision. Prentice-Hall, 2001.<br />
[130] P. Shargo and J. Melody, “Model-based Correction of <strong>Through</strong>-wall SAR Imagery via<br />
Raytracing,” IEEE <strong>Radar</strong> Conference 2007, pp. 706–711, Apr. 2007.<br />
[131] F. Soldovieri and R. Solimene, “<strong>Through</strong>-<strong>Wall</strong> <strong>Imaging</strong> via a Linear Inverse Scattering<br />
Algorithm,” IEEE Geoscience and Remote Sensing Letters, vol. 4, pp. 513–517, Oct. 2007.