Tomographic Image and the Inverse Scattering Problem Using Multiple Incidence on Biological Object in Terahertz

Document Type : Original Article

Authors

1 Electronics and Electrical Communication Engineering Department, Faculty of Electronic Engineering, Menufia University, Menouf, Egypt

2 Medical Equipment Department Emergency Hospital –Tanta Universit Tanta, Egypt

Abstract

Tomographic image and the inverse scattering problem using multiple incidence of biological object in Terahertz has been presented.The feasibility of a three-dimensional terahertz imaging using an electromagnetic exploration that has been proven, it remains to be determined in what conditions may be could obtain a good resolution in all directions. The recipe of conditions that will make collaboration engineering and economy comes together has been taken into account.Numerical results are given to demonstrate the capability to solve of inverse scattering problem algorithm for biological object of smooth cells which make up the intestine.  Also, the biological object of laceration in the tissue or puncture. The scattered field distribution is measured in a plane situated behind the object. They show that this field distribution depends on the object shape. The results of scattered electromagnetic field measurements carried out on different material objects are given. Good reconstruction is obtain from measured data even the results of scattered electromagnetic field measurements carried out on different material objects are given.

References

[1] AnandoSen,Demetrio Labate,Bernhard G. andRobert Azencott, “3D ROI image reconstruction from truncated computed tomography”, IEEE Transactions on Medical Imaging, pp. 1-24, May 26, 2013.
[2] Greg Michael, “X-ray computed tomography”, journal of Medical Physics, pp. 442-451, 2012.
[3] Robert Azencott, Bernhard G. Bodmann, Demetrio Labate, AnandoSen, Igor Patrikeev, and MassoudMotamedi, “3D-image reconstruction in highly collimated”, IEEE Transactions on Medical Engineering, pp.1-4, 2007,
[4] Stéphane Bonnet, Françoise Peyrin, Francis Turjman, and Rémy Prost, “Tomographic reconstruction using nonseparable wavelets”, IEEE Transactions on Image Processing, Vol. 9, No. 8, pp. 1445-1450, August 2000.
[5] Stéphane Bonnet, Françoise Peyrin, Francis Turjman, and Rémy Prost, “Multiresolution reconstruction in fan-beam tomography”, IEEE Transactions on Image Processing, Vol. 11, No. 3, pp. 169-170, March 2002.
[6] Sven van Berkel, OzanYurduseven, Angelo Freni, Andrea Neto, and NuriaLlombart, “THz imaging using uncooled wideband direct detection focal plane arrays”, IEEE Transaction on Terahertz Science and Technology, Vol. 7, No. 5, pp. 481-492, September 2017.
[7] Katsuhiro Ajito, and Yuko Ueno,” THz Chemical Imaging for Biological Applications”, IEEE Transaction on Terahertz Science and Technology, Vol. 1, No. 1, pp. 293-300, September 2011.
[8] ChengyanJia, GuoshuaiGeng, Tianying Chang, Chuanfa Yang, Wei Fan, Yao Guo, Zhonglin Sun,Lingyu Liu, QijiaGuo, and Hong-Liang Cui,” Millimeter wave imaging of cracks in bulk coal”, IEEE Transaction on Terahertz Science and Technology, Vol. 6, No. 4, pp. 554-562, July 2016.
[9] Sven van Berkel, OzanYurduseven, Angelo Freni, Andrea Neto, and NuriaLlombart,“THz imaging using uncooled wideband direct detection focal plane arrays”, IEEE Transaction on Terahertz Science and Technology, Vol. 7, No. 5, pp. 481-492, September 2017.
[10] Haishun Liu , Zhenwei Zhang , Xin Zhang, Yuping Yang, Zhuoyong Zhang, Xiangyi Liu , Fan Wang, Yiding Han, and Cunlin Zhang,” Dimensionality reduction for identification of hepatic tumor samples based on terahertz time-domain spectroscopy”, IEEE Transaction on Terahertz Science and Technology, Vol. 8, No. 3, pp. 271-277, May 2018.
[11] Zachary D. Taylor, James Garritano, Shijun Sung, NehaBajwa, David B. Bennett, Bryan Nowroozi, PriyamvadaTewari, James W. Sayre, Jean-Pierre Hubschman, Sophie X. Deng, Elliott R. Brown, and Warren S. Grundfest,” THz and mm-wave sensing of corneal tissue water content: In Vivo Sensing and imaging results”, IEEE Transaction on Terahertz Science and Technology, Vol. 5, No. 2, pp. 184-195, March 2015.
[12] Jongwon Yun, Seung Jae Oh, Kiryong Song, Daekeun Yoon, Hye Young Son, Yuna Choi, Yong-Min Huh, and Jae-Sung Rieh,”Terahertz reflection-mode biological imaging based on inP HBT source and detector”, IEEE Transaction on Terahertz Science and Technology, Vol. 7, No. 3, pp. 274-283, May 2017.
[13] Ken B. Cooper, Robert J. Dengler, NuriaLlombart, Bertrand Thomas, GoutamChattopadhyay, and Peter H. Siegel,”THz imaging radar for standoff personnel screening”, ”, IEEE Transaction on Terahertz Science and Technology, Vol. 1, No. 1, pp. 169-181, September 2011.
[14] Jochen Moll, Philipp Schöps, and Viktor Krozer,”Towards three-dimensional millimeter-wave radar with the bistaticfast-factorized back-projection algorithm—potential and limitations”, IEEE Transaction on Terahertz Science and Technology, Vol. 2, No. 4, pp. 
Menoufia Journal of Electronic Engineering Research
Volume 28, ICEEM2019-Special Issue
ICEEM2019-Special Issue: 1st International Conference on Electronic Eng., Faculty of Electronic Eng., Menouf, Egypt, 7-8 Dec.
2019
Pages 153-157

Files

Share

How to cite

Statistics