Search search
Publication Date
to
Vol. 162
Latest Volume
All Volumes
PIER 185 [2026] PIER 184 [2025] PIER 183 [2025] PIER 182 [2025] PIER 181 [2024] PIER 180 [2024] PIER 179 [2024] PIER 178 [2023] PIER 177 [2023] PIER 176 [2023] PIER 175 [2022] PIER 174 [2022] PIER 173 [2022] PIER 172 [2021] PIER 171 [2021] PIER 170 [2021] PIER 169 [2020] PIER 168 [2020] PIER 167 [2020] PIER 166 [2019] PIER 165 [2019] PIER 164 [2019] PIER 163 [2018] PIER 162 [2018] PIER 161 [2018] PIER 160 [2017] PIER 159 [2017] PIER 158 [2017] PIER 157 [2016] PIER 156 [2016] PIER 155 [2016] PIER 154 [2015] PIER 153 [2015] PIER 152 [2015] PIER 151 [2015] PIER 150 [2015] PIER 149 [2014] PIER 148 [2014] PIER 147 [2014] PIER 146 [2014] PIER 145 [2014] PIER 144 [2014] PIER 143 [2013] PIER 142 [2013] PIER 141 [2013] PIER 140 [2013] PIER 139 [2013] PIER 138 [2013] PIER 137 [2013] PIER 136 [2013] PIER 135 [2013] PIER 134 [2013] PIER 133 [2013] PIER 132 [2012] PIER 131 [2012] PIER 130 [2012] PIER 129 [2012] PIER 128 [2012] PIER 127 [2012] PIER 126 [2012] PIER 125 [2012] PIER 124 [2012] PIER 123 [2012] PIER 122 [2012] PIER 121 [2011] PIER 120 [2011] PIER 119 [2011] PIER 118 [2011] PIER 117 [2011] PIER 116 [2011] PIER 115 [2011] PIER 114 [2011] PIER 113 [2011] PIER 112 [2011] PIER 111 [2011] PIER 110 [2010] PIER 109 [2010] PIER 108 [2010] PIER 107 [2010] PIER 106 [2010] PIER 105 [2010] PIER 104 [2010] PIER 103 [2010] PIER 102 [2010] PIER 101 [2010] PIER 100 [2010] PIER 99 [2009] PIER 98 [2009] PIER 97 [2009] PIER 96 [2009] PIER 95 [2009] PIER 94 [2009] PIER 93 [2009] PIER 92 [2009] PIER 91 [2009] PIER 90 [2009] PIER 89 [2009] PIER 88 [2008] PIER 87 [2008] PIER 86 [2008] PIER 85 [2008] PIER 84 [2008] PIER 83 [2008] PIER 82 [2008] PIER 81 [2008] PIER 80 [2008] PIER 79 [2008] PIER 78 [2008] PIER 77 [2007] PIER 76 [2007] PIER 75 [2007] PIER 74 [2007] PIER 73 [2007] PIER 72 [2007] PIER 71 [2007] PIER 70 [2007] PIER 69 [2007] PIER 68 [2007] PIER 67 [2007] PIER 66 [2006] PIER 65 [2006] PIER 64 [2006] PIER 63 [2006] PIER 62 [2006] PIER 61 [2006] PIER 60 [2006] PIER 59 [2006] PIER 58 [2006] PIER 57 [2006] PIER 56 [2006] PIER 55 [2005] PIER 54 [2005] PIER 53 [2005] PIER 52 [2005] PIER 51 [2005] PIER 50 [2005] PIER 49 [2004] PIER 48 [2004] PIER 47 [2004] PIER 46 [2004] PIER 45 [2004] PIER 44 [2004] PIER 43 [2003] PIER 42 [2003] PIER 41 [2003] PIER 40 [2003] PIER 39 [2003] PIER 38 [2002] PIER 37 [2002] PIER 36 [2002] PIER 35 [2002] PIER 34 [2001] PIER 33 [2001] PIER 32 [2001] PIER 31 [2001] PIER 30 [2001] PIER 29 [2000] PIER 28 [2000] PIER 27 [2000] PIER 26 [2000] PIER 25 [2000] PIER 24 [1999] PIER 23 [1999] PIER 22 [1999] PIER 21 [1999] PIER 20 [1998] PIER 19 [1998] PIER 18 [1998] PIER 17 [1997] PIER 16 [1997] PIER 15 [1997] PIER 14 [1996] PIER 13 [1996] PIER 12 [1996] PIER 11 [1995] PIER 10 [1995] PIER 09 [1994] PIER 08 [1994] PIER 07 [1993] PIER 06 [1992] PIER 05 [1991] PIER 04 [1991] PIER 03 [1990] PIER 02 [1990] PIER 01 [1989]
All Journals
PIER PIER B PIER C PIER M PIER Letters
2018-07-31
An UWB Antenna Array for Flexible IoT Wireless Systems
By
Haider Khaleel Raad

    Dr. Haider Khaleel Raad

    Physics Department

    Xavier University

    USA

    Homepage

Progress In Electromagnetics Research, Vol. 162, 109-121, 2018
doi:10.2528/PIER18060804 | Google Scholar

Abstract
In this paper, a flexible compact antenna array operating in the 3.2-13 GHz which covers the standard Ultra-Wide Band (UWB) frequency range is presented. The design is aimed at integration within Multiple Input Multiple Output (MIMO) based flexible electronics for Internet of Things (IoT) applications. The proposed antenna is printed on a single side of a 50.8 μm Kapton Polyimide substrate and consists of two half-elliptical shaped radiating elements fed by two Coplanar Waveguide (CPW) structures. The simulated and measured results show that the proposed antenna array achieves a broad impedance bandwidth with reasonable isolation performance (S12 < -23 dB) across the operating bandwidth. Furthermore, the proposed antenna exhibits a low susceptibility to performance degradation caused by the effect of bending. The system's isolation performance along with its flexible and thin profile suggests that the proposed antenna is suitable for integration within flexible Internet of Things (IoT) wireless systems.
Download Full Article (1137) View Full Article volume
Citation
Haider Khaleel Raad, "An UWB Antenna Array for Flexible IoT Wireless Systems," Progress In Electromagnetics Research, Vol. 162, 109-121, 2018.
doi:10.2528/PIER18060804
References

1. Awais, Q., H. Tariq Chattha, M. Jamil, Y. Jin, F. A. Tahir, and M. Ur Rehman, "A novel dual ultrawideband CPW-fed printed antenna for Internet of Things (IoT) applications," Wireless Communications and Mobile Computing, Vol. 10, 1-9, 2018.
doi:10.1155/2018/2179571        Google Scholar

2. Tao, J. and Q. Feng, "Compact ultrawideband MIMO antenna with half-slot structure," IEEE Antennas and Wireless Propagation Letters, Vol. 16, 792-795, 2017.
doi:10.1109/LAWP.2016.2604344        Google Scholar

3. Ren, J., D. Mi, and Y. Yin, "Compact ultrawideband MIMO antenna with WLAN/UWB bands coverage," Progress In Electromagnetics Research C, Vol. 50, 121-129, 2014.
doi:10.2528/PIERC14041701        Google Scholar

4. Raad, H., H. Al-Rizzo, A. Isaac, and A. Hammoodi, "A compact dual band polyimide based antenna for wearable and flexible telemedicine devices," Progress In Electromagnetics Research C, Vol. 63, 153-161, 2016.
doi:10.2528/PIERC16010707        Google Scholar

5. Raad, H., A. Abbosh, H. M. Al-Rizzo, and D. G. Rucker, "Flexible and compact AMC based antenna for telemedicine applications," IEEE Transactions on Antennas and Propagation, Vol. 61, No. 2, 524, 531, Feb. 2013.
doi:10.1109/TAP.2012.2223449        Google Scholar

6. Khaleel, H. R., H. Al-Rizzo, and D. Rucker, "Compact polyimide-based antennas for flexible displays," IEEE Journal of Display Technology, Vol. 8, No. 2, 91-97, Feb. 2012.
doi:10.1109/JDT.2011.2164235        Google Scholar

7. Al-Adhami, Y. and E. Ercelebi, "Plasmonic metamaterial dipole antenna array circuitry based on flexible solar cell panel for self-powered wireless systems," Microw. Opt. Technol. Lett., Vol. 59, 2365-2371, 2017.
doi:10.1002/mop.30747        Google Scholar

8. Al-Adhami, Y. and E. Ercelebi, "A plasmonic monopole antenna array on flexible photovoltaic panels for further use of the green energy harvesting," Progress In Electromagnetics Research M, Vol. 68, 143-152, 2018.
doi:10.2528/PIERM18032104        Google Scholar

9. Politano, A., L. Viti, and M. Vitiello, "Optoelectronic devices, plasmonics, and photonics with topological insulators," APL Materials, Vol. 5, 035504, 2017.
doi:10.1063/1.4977782        Google Scholar

10. Viti, L., A. Politano, and M. Vitiello, "Black phosphorus nanodevices at terahertz frequencies: Photodetectors and future challenges," APL Materials, Vol. 5, 035602, 2017.
doi:10.1063/1.4979090        Google Scholar

11. Politano, A., M. S. Vitiello, L. Viti, D. W. Boukhvalov, and G. Chiarello, "The role of surface chemical reactivity in the stability of electronic nanodevices based on two-dimensional materials “beyond graphene” and topological insulators," Materials Science (cond-mat.mtrl-sci); Mesoscale and Nanoscale Physics, FlatChem 1, 60-64, 2017.        Google Scholar

12. Politano, A., G. Chiarello, R. Samnakay, G. Liu, B. Gurbulak, S. Duman, A. Balandin, and D. Boukhvalov, "The influence of chemical reactivity of surface defects on ambient-stable InSebased nanodevices," Nanoscale, Vol. 8, 1039, 2016.        Google Scholar

13. Weinan, Z., P. Saungeun, N. Maruthi, K. Yogeesh, M. McNicholas, R. Seth, and A. Deji, "Black phosphorus flexible thin film transistors at gigahertz frequencies," Nano Letters, Vol. 16, 2301, 2016.        Google Scholar

14. Weinan, Z., N. Maruthi, S. Yogeesh, S. Yang, H. Aldave, K. Joon-Seok, S. Sushant, L. Tao, L. Nanshu, and A. Deji, "Flexible black phosphorus ambipolar transistors, circuits and AM demodulator," Nano Letters, Vol. 15, No. (3), 1883-1890, 2015.        Google Scholar

15. Akinwande, D., N. Petrone, and J. Hone, "Two-dimensional flexible nanoelectronics," Nat. Commun., Vol. 5, 5678, 2014.
doi:10.1038/ncomms6678        Google Scholar

16. Boukhvalov, D., B. Gurbulak, S. Duman, L. Wang, A. Politano, L. Caputi, G. Chiarello, and A. Cupolillo, "The advent of indium selenide: Synthesis, electronic properties, ambient stability and applications," Nanomaterials, Vol. 7, No. 11, 3390, 2017.
doi:10.3390/nano7110372        Google Scholar

7. Wong, K., S. Su, and Y. Kuo, "A printed ultra-wideband diversity monopole antenna," Microw. Opt. Technol. Lett., Vol. 38, 257-259, 2003.
doi:10.1002/mop.11031        Google Scholar

18. See, T. S. P. and Z. N. Chen, "An ultrawideband diversity antenna," IEEE Transactions on Antennas and Propagation, Vol. 57, No. 6, 1597-1605, 2009.
doi:10.1109/TAP.2009.2019908        Google Scholar

19. Yoon, H. K., Y. J. Yoon, H. Kim, and C. Lee, "Flexible ultra-wideband polarisation diversity antenna with band-notch function," IET Microwaves, Antennas and Propagation, Vol. 5, No. 12, 1463-1470, 2011.
doi:10.1049/iet-map.2010.0126        Google Scholar

20. http/www.cst.com.

21. Dupont Kapton Polyimide specification sheet, www2.dupont.com/kapton.

22. Khaleel, H., H. Al-Rizzo, D. Rucker, and S. Mohan, "A compact polyimide-based UWB antenna for flexible electronics," IEEE Antennas and Wireless Propagation Letters, Vol. 11, 564-567, 2012.
doi:10.1109/LAWP.2012.2199956        Google Scholar

23. http://www.fujifilmusa.com/products/industrial inkjet print heads/index.html.

24. Vaughan, R. and J. Andersen, "Antenna diversity in mobile communications," IEEE Trans. Veh. Technol., Vol. 36, No. 4, 149-172, 1987.
doi:10.1109/T-VT.1987.24115        Google Scholar

25. Hui, H. and H. Lui, "Expression of correlation coefficient for two omindirectional antennas using conventional mutual impedances," Electron. Lett., Vol. 44, No. 20, 1177-1178, 2008.
doi:10.1049/el:20081708        Google Scholar

26. Blanch, S., J. Romeu, and I. Corbella, "Exact representation of antenna system diversity performance from input parameter description," Electron. Lett., Vol. 39, No. 9, 705-707, 2003.
doi:10.1049/el:20030495        Google Scholar

27. Castel, T., S. Lemey, P. Van Torre, C. Oestges, and H. Rogier, "Four-element ultrawideband textile cross array for dual-spatial and dual-polarization diversity," IEEE Antennas and Wireless Propagation Letters, Vol. 16, 481-484, 2017.
doi:10.1109/LAWP.2016.2585308        Google Scholar

28. Ahmed, M., E. Abdallah, and H. Elhennawy, "Novel wearable eagle shape microstrip antenna array with mutual coupling reduction," Progress In Electromagnetics Research B, Vol. 62, 87-103, 2015.
doi:10.2528/PIERB14120901        Google Scholar

29. Raj, K., R. Krishna, and N. Kushwaha, "Design of a compact MIMO/diversity antenna for UWB applications with modified TH-like structure," Microwave and Optical Technology Letters, Vol. 58, 1181-1187, 2016.        Google Scholar

30. Zhao, H., F. Zhang, X. Zhang, and C. Wang, "A compact band-notched ultra-wideband spatial diversity antenna," Progress In Electromagnetics Research C, Vol. 51, 9-26, 2014.        Google Scholar

Download Full Article (1137) View Full Article volume


The EM Academy piers.org jpier.org Who's Who in EM
Copyright © 2022 The Electromagnetics Academy. All Rights Reserved.