Citation: Reza K. Amineh. Developments in three-dimensional near-field imaging with FMCW radar: A comparative study[J]. AIMS Electronics and Electrical Engineering, 2020, 4(4): 359-368. doi: 10.3934/ElectrEng.2020.4.359
[1] | Nikolova N (2011) Microwave imaging for breast cancer. IEEE Microw Mag 12: 78-94. |
[2] | Sheen D, Mcmakin D, Hall T (2001) Three-dimensional millimeter-wave imaging for concealed weapon detection. IEEE T Microw Theory 49: 1581-1592. |
[3] | Ghazi G, Rappaport CM, Martinez-Lorenzo JA (2016) Improved SAR imaging contour extraction using smooth sparsity-driven regularization. IEEE Antenn Wirel Pr 15: 266-269. |
[4] | Amineh RK, Ravan M, Sharma R (2020) Nondestructive testing of nonmetallic pipes using wideband microwave measurements. IEEE T Microw Theory 65: 1763-1772. |
[5] | Wu H, Ravan M, Sharma R, et al. (2020) Microwave holographic imaging of non-metallic concentric pipes. IEEE T Instrum Meas 69: 7594-7605. |
[6] | Yemelyanov KM, Engheta N, Hoorfar A, et al. (2009) Adaptive polarization contrast techniques for through-wall microwave imaging applications. IEEE T Geosci Remote 47: 1362-1374. |
[7] | Hajebi M, Tavakoli A, Dehmollaian M, et al. (2018) An iterative modified diffraction tomography method for reconstruction of a high-contrast buried object. IEEE T Geosci Remote 56: 4138-4148. |
[8] | Amineh RK, Nikolova NK, Ravan M (2019) Real-Time Three-Dimensional Imaging of Dielectric Bodies Using Microwave/Millimeter Wave Holography. Hoboken, NJ, USA: Wiley. |
[9] | Amineh RK, Ravan M, McCombe J, et al. (2013) Three-dimensional microwave holographic imaging employing forward- scattered waves only. Int J Antenn Propag 2013. |
[10] | Stove AG (1992) Linear FMCW radar techniques. IEE Proceedings F (Radar and Signal Processing) 139: 343-350. |
[11] | Hägelen M, Briese G, Essen H, et al. (2008) Millimetre wave near field SAR scanner for concealed weapon detection. EUSAR2008, Friedrichshafen, Germany. |
[12] | Álvarez-Narciandi G, López-Portugués M, Las-Heras F, et al. (2019) Freehand, agile, and high-resolution imaging with compact mm-wave radar. IEEE Access 7: 95516-95526. |
[13] | Yang J, Thompson J, Huang X, et al. (2012) FMCW radar near field three-dimensional imaging. Proc IEEE Int Conf Commun (ICC), 6353-6356. |
[14] | Zhou W, Bovik AC, Sheikh HR, et al. (2004) Image quality assessment: from error visibility to structural similarity. IEEE T Image Process 13: 600-612. |
[15] | Meta A, Hoogeboom P, Ligthart LP (2007) Signal processing for FMCW SAR. IEEE T Geosci Remote 45: 3519-3532. |
[16] | Chew W (1995) Waves and Fields in Inhomogeneous. Media Piscataway, NJ: IEEE Press. |
[17] | Detlefsen J, Dallinger A, Schelkshorn S, et al. (2006) UWB millimeterwave FMCW radar using Hubert transform methods. 9th IEEE Int Symp Spread Spectr Techn Appl, 46-48. |
[18] | Lopez-Sanchez JM, Fortuny-Guasch J (2000) 3-D radar imaging using range migration techniques. IEEE T Antenn Propag 48: 728-737. |
[19] | Zhuge X, Yarovoy AG (2012) Three-dimensional near-field MIMO array imaging using range migration techniques. IEEE T Image Process 21: 3026-3033. |
[20] | Zhou M, Alfadhl Y, Chen X (2018) Optimal spatial sampling criterion in a 2D THz holographic imaging system. IEEE Access 6: 8173-8177. |
[21] | Amineh RK, Ravan M, Sharma R, et al. (2018) Three-dimensional holographic imaging using single frequency microwave data. Int J Antenn Propag 2018: 6542518. |
[22] | Tsai CH, Chang J, Yang LYO, et al. (2018) 3-D microwave holographic imaging with probe and phase compensations. IEEE T Antenn Propag 66: 368-380. |