Impulse radar imaging system for concealed object detection

Podd, Frank; Mata-Moya, David; Iqbal, G.; Hussain, Fiazal; Morris, David; Osakue, E.; You, Kok Yeow; Zahir, Saif; Armitage, David; Peyton, A. J.

doi:10.1117/12.2029462

Cited by 2 publications

(2 citation statements)

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“…The use of EM waves in the 10-30 GHz range allows better penetration of clothing (especially if damp) compared with *lara.stec@manchester.ac.uk tel: +44 (0)161 306 8945 operation above 80 GHz, while still potentially providing adequate resolution. The recent availability of low-cost integrated circuits designed for the communication sector means this option brings the cost down 17 . In one study 19 ,frequencies in the range [15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30] GHz range are used to monitor people on a conveyor.…”

Section: Introductionmentioning

confidence: 99%

“…These wavelengths have good resolution, since they are much shorter than the dimensions of the body/object details to be examined. However, the higher frequencies can have difficulty penetrating thick clothing 15,17 . In addition, these shorter wavelengths/higher frequencies make the material appear rougher, resulting in more scattering and less power at the receiving antenna 18 .…”

Section: Introductionmentioning

confidence: 99%

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A methodology for the optimisation of a mm-wave scanner

2016

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The need to detect non-metallic items under clothes to prevent terrorism at transport hubs is becoming vital. Millimetre wave technology is able to penetrate clothing, yet able to interact with objects concealed underneath. This paper considers active illumination using multiple transmitter and receiver antennas. The positioning of these antennas must achieve full body coverage, whilst minimising the number of antenna elements and the number of required measurements. It sets out a rapid simulation methodology, based on the Kirchhoff equations, to explore different scenarios for scanner architecture optimisation.The paper assumes that the electromagnetic waves used are at lower frequencies (say, 10-30 GHz) where the body temperature does not need to be considered. This range allows better penetration of clothing than higher frequencies, yet still provides adequate resolution.Since passengers vary greatly in shape and size, the system needs to be able to work well with a range of body morphologies. Thus we have used two very differently shaped avatars to test the portal simulations. This simulation tool allows many different avatars to be generated quickly.Findings from these simulations indicated that the dimensions of the avatar did indeed have an effect on the pattern of illumination, and that the data for each antenna pair can easily be combined to compare different antenna geometries for a given portal architecture, resulting in useful insights into antenna placement. The data generated could be analysed both quantitatively and qualitatively, at various levels of scale.

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