3-D Imaging of Materials at 0.1 THz for Inner- Defect Detection Using a Frequency-Modulated Continuous-Wave Radar

This article reports a novel 3-D imaging approach for remote, nondestructive material inspection at depth. The approach is based on a frequency-modulated continuous-wave (FMCW) radar system operating in the 75–110-GHz frequency band. Time-domain spectroscopy (TDS) measurements demonstrate that such a frequency band has manage-able attenuation levels in centimeter-long materials, thereby offering an advantageous resolution-versus-measurement-depth tradeoff compared with higher frequencies. The proposed setup includes a long delay on the reference signal in order to cancel redundant signals that would otherwise degrade the measurement. Furthermore, specific signal-processing techniques used to improve the performance of the system, which requires stringent component performances in terms of radio-frequency nonlinearity and return loss, are presented. Radio-frequency nonlinearity correction is based on a reference measurement, and the impact of deleterious reflections is reduced by averaging measurements conducted on a target at different longitudinal positions. As a result, an improvement of the signal-to-noise (S/N) ratio up to 20 dB is demonstrated. Tomography experiments were conducted on building materials showing 3-D imaging with theoretically limited longitudinal and transverse resolutions of 5 and 20 mm, respectively, thus opening the door to civil infrastructure monitoring applications.

[1]  J. Grajal,et al.  3-D High-Resolution Imaging Radar at 300 GHz With Enhanced FoV , 2015, IEEE Transactions on Microwave Theory and Techniques.

[2]  Galia Ghazi,et al.  Modeling and experimental validation for 3D mm-wave radar imaging , 2017 .

[3]  S. O. Piper Homodyne FMCW radar range resolution effects with sinusoidal nonlinearities in the frequency sweep , 1995, Proceedings International Radar Conference.

[4]  Jason C. Dickinson,et al.  1.56 Terahertz 2-frames per second standoff imaging , 2008, SPIE OPTO.

[5]  Duncan A. Robertson,et al.  340-GHz 3D radar imaging test bed with 10-Hz frame rate , 2012, Defense + Commercial Sensing.

[6]  Masayoshi Tonouchi,et al.  Cutting-edge terahertz technology , 2007 .

[7]  J. Grajal,et al.  Low-Cost CW-LFM Radar Sensor at 100 GHz , 2013, IEEE Transactions on Microwave Theory and Techniques.

[8]  N. Llombart,et al.  Penetrating 3-D Imaging at 4- and 25-m Range Using a Submillimeter-Wave Radar , 2008, IEEE Transactions on Microwave Theory and Techniques.

[9]  Nuria Llombart,et al.  THz Imaging Radar for Standoff Personnel Screening , 2011, IEEE Transactions on Terahertz Science and Technology.

[10]  A. Benbassou,et al.  THz reflectometer for 3D imaging at 100 GHz , 2017, 2017 International Conference on Wireless Technologies, Embedded and Intelligent Systems (WITS).

[11]  Torsten Loffler,et al.  3D-terahertz-tomography for material inspection and security , 2009, 2009 34th International Conference on Infrared, Millimeter, and Terahertz Waves.

[12]  J. Fujimoto,et al.  Optical coherence tomography using a frequency-tunable optical source. , 1997, Optics letters.

[13]  Maya R. Gupta,et al.  Recent advances in terahertz imaging , 1999 .

[14]  Hsuan-Jung Su,et al.  Range resolution improvement for FMCW radars , 2008, 2008 European Radar Conference.

[15]  Christian Bredendiek,et al.  High-Precision D-Band FMCW-Radar Sensor Based on a Wideband SiGe-Transceiver MMIC , 2014, IEEE Transactions on Microwave Theory and Techniques.

[16]  Thomas E. Hall,et al.  Active millimeter-wave standoff and portal imaging techniques for personnel screening , 2009, 2009 IEEE Conference on Technologies for Homeland Security.

[17]  Wai Lam Chan,et al.  Imaging with terahertz radiation , 2007 .

[18]  Jesus Grajal,et al.  DDS-Based Signal-Generation Architecture Comparison for an Imaging Radar at 300 GHz , 2015, IEEE Transactions on Instrumentation and Measurement.

[19]  Thomas Musch A high precision 24 GHz FMCW-radar based on a fractional-N ramp-PLL , 2002, Conference Digest Conference on Precision Electromagnetic Measurements.

[20]  Daniel M Mittleman,et al.  Twenty years of terahertz imaging [Invited]. , 2018, Optics express.

[21]  E. Castro-Camus,et al.  Beating the wavelength limit: three-dimensional imaging of buried subwavelength fractures in sculpture and construction materials by terahertz time-domain reflection spectroscopy. , 2013, Applied optics.

[22]  Duncan A. Robertson,et al.  High resolution, wide field of view, real time 340GHz 3D imaging radar for security screening , 2017, Defense + Security.

[23]  Jean-Charles Bolomey,et al.  Quantitative Microwave Imaging for Breast Cancer Detection Using a Planar 2.45 GHz System , 2010, IEEE Transactions on Instrumentation and Measurement.

[24]  A. Jeglic,et al.  Applications of Terahertz Spectroscopy in the Field of Construction and Building Materials , 2015 .

[25]  Hugh Griffiths,et al.  The effect of phase and amplitude errors in FM radar , 1991 .

[26]  Ralf Henneberger,et al.  Fast Active THz Cameras with Ranging Capabilities , 2009 .

[27]  Guangyou Fang,et al.  Terahertz Aperture Synthesized Imaging With Fan-Beam Scanning for Personnel Screening , 2012, IEEE Transactions on Microwave Theory and Techniques.

[28]  Nick Savage,et al.  Terahertz Radome Inspection , 2018 .

[29]  M. Koch,et al.  Properties of Building and Plastic Materials in the THz Range , 2007 .

[30]  K. Kawase,et al.  THz imaging techniques for nondestructive inspections , 2010 .

[31]  Qian Song,et al.  Fast continuous terahertz wave imaging system for security , 2009 .

[32]  Frédéric Garet,et al.  Principles and Applications of THz Time Domain Spectroscopy , 2014 .

[33]  Reza Zoughi,et al.  Novel Reflectometer for Millimeter-Wave 3-D Holographic Imaging , 2014, IEEE Transactions on Instrumentation and Measurement.