臺灣博碩士論文加值系統

誌謝i
摘要ii
Abstractiii
目錄v
表目錄vii
圖目錄viii
1.緒論1
1.1研究背景1
1.2文獻導覽2
1.3論文提要17
2.應用於智慧型手機之4G雙天線設計18
2.1 概述18
2.2 天線結構設計與技術原理說明18
2.3 天線實驗與量測結果21
2.4 天線設計之輻射特性及效率26
2.5 天線設計機制27
2.6 雙天線參數分析29
2.7 雙天線間隔離度分析31
2.8本章結論32
3.雙頻帶5G 連體四天線33
3.1概述33
3.2天線結構設計與技術原理說明33
3.3天線實驗與量測結果35
3.4天線設計之輻射特性及效率41
3.5天線設計機制42
3.6四天線參數分析44
3.7四天線隔離度分析46
3.8本章結論47
4.結論48
參考文獻49
自傳52

[1]https://www.eettaiwan.com/20211119nt21-smartphone-shipments-in-2022
[2]Di Liu., Chang J Deng., “A Compact Octa-Band Planar Antenna for LTE Mobile Phone,”2019 International Conference on Microwave and Millimeter Wave Technology (ICMMT) (Guangzhou, China, May 19-22, 2019)
[3]Cheng C Yu., Chien Y Huarig., Jiin H Yang., Cheng H Hsu., Ja H Chen “A Low-Profile Antenna Design for LTE WWAN Smartphone Applicatio,” 2018 Progress in Electromagnetics Research Symposium (PIERS) (Toyama, Japan, Aug. 01-04, 2018)
[4]R. Ullah, S. Ullah, R. Ullah, F. Faisal, I. B. Mabrouk and M. J. A. Hasan., “A 10-Ports MIMO antenna system for 5G smart-phone applications,” IEEE Access, vol. 8, pp. 218477–218488, 2020.
[5]X. Wang, Y. Wu, W. Wang and A. A. Kishk, “A Simple MultiBroadband Planar Antenna for LTE/GSM/UMTS and WLAN/WiMAX Mobile Handset Applications,” IEEE Access, vol. 6, pp. 74453-74461, 2018.
[6]Z. Xu, Q. Zhou, Y. Ban and S. S. Ang, “Hepta-band coupled-Fed loop antenna for LTE/WWAN unbroken metal-rimmed smartphone applications,” IEEE Antennas and Wireless Propagation Letters, vol. 17, pp. 311-314, 2018.
[7]L.-W. Zhang, Y.-L. Ban, J. Guo, Z.-F. Yu et al., “Parallel dual-loop antenna for wwan/lte metal-rimmed smartphone,” IEEE Transactions on Antennas and Propagation, vol. 66, no. 3, pp. 1217–1226, 2018.
[8]Q. Chen, H. Lin, J. Wang, L. Ge, Y. Li, T. Pei, and C.-Y.-D. Sim, “Single ring slot-based antennas for metal-rimmed 4G/5G smartphones,” IEEE Transactions on Antennas and Propagation, vol. 67, no. 3, pp. 1476– 1487, 2019.
[9]Xiaocheng Wang, Yongle Wu, Weimin Wang, Ahmed A. Kishk, “A simple multi-broadband planar antenna for LTE/GSM/UMTS and WLAN/WiMAX mobile handset applications” IEEE Access, vol. 6, pp. 74453-74461, 2018.
[10]J. Choi, W. Hwang, C. You, B. Jung, and W. Hong, ‘‘Four-element reconfigurable coupled loop MIMO antenna featuring LTE full-band operation for metallic-rimmed smartphone,’’ IEEE Trans. Antennas Propag., vol. 67, no. 1, pp. 99–107, 2019.
[11]I.R.R. Barani and K.L. Wong, "Dual-feed U-slot antenna having low envelope correlation coefficients for the LTE MIMO operation in the metal-framed smartphone," Microwave Opt. Technol. Lett., Vol. 60, pp. 295-302, 2018.
[12]Y. Liu, W. Cui, Y. Jia, and A. Ren, “Hepta-band metal-frame antenna for LTE/WWAN full-screen smartphone,” IEEE Antennas and Wireless Propagation Letters, vol. 19, no. 7, pp. 1241–1245, 2020.
[13]K.L. Wong, S.N. Lin, I.R.R. Barani, and W.Y. Li, "One LTE LB antenna and two conjoined LTE M/HB MIMO antennas with a compact symmetric frame structure at the short edge of the metal-framed smartphone," Microwave Opt. Technol. Lett., Vol. 61, pp. 1358-1364, 2019.
[14]I.R.R. Barani and K.L. Wong, "Integrated inverted-F and open-slot antennas in the metal-framed smartphone for 2 x 2 LTE LB and 4 x 4 LTE M/HB MIMO operations," IEEE Trans. Antennas Propag., Vol. 66, pp. 5004-5012, 2018.
[15]W. Jiang, Y. Cui, B. Liu, W. Hu, and Y. Xi, ‘‘A dual-band MIMO antenna with enhanced isolation for 5G smartphone applications,’’ IEEE Access, vol. 7, pp. 112554–112563, 2019.
[16]K.L. Wong, Y.H Chen, and W.Y. Li, "Decoupled compact ultra-wideband MIMO antennas covering 3.3~6.0 GHz for the fifth-generation mobile and 5GHz-WLAN operations in the future smartphone," Microwave Opt. Technol. Lett., Vol. 60, pp. 2345-2351, 2018.
[17]K.L. Wong, B.W. Lin, and W.Y. Li, "Dual-band dual inverted-F/loop antennas as a compact decoupled building block for forming eight 3.5/5.8-GHz MIMO antennas in the future smartphone," Microwave Opt. Technol. Lett., Vol. 59, pp. 2715-2721, 2017.
[18]K.L. Wong, B.W. Lin, and S.E. Lin, "High-isolation conjoined loop MIMO antennas for the 5G tablet devices," Microwave Opt. Technol. Lett., Vol. 61, pp. 111-119, 2019.
[19]K.L. Wong, Y.H. Chen, and W.Y. Li, "Conjoined ultra-wideband (2300~6000 MHz) dual antennas for LTE HB/WiFi/5G MIMO operation in the fifth-generation tablet device," Microwave Opt. Technol. Lett., Vol. 61, pp. pp. 1958-1963, 2019.
[20]I.R.R. Barani, K.L. Wong, Y. X. Zhang, and W.Y. Li, "Low-profile wideband conjoined open-slot antennas fed by grounded coplanar wavegudides for 4 x 4 5G MIMO operation," IEEE Trans. Antennas Propag., Vol. 68, pp. 2646-2657, 2020.
[21]K.L. Wong, M.F. Jian, and W.Y. Li, "Low-profile wideband four-corner-fed square patch antenna for 5G MIMO mobile antenna application," IEEE Antennas Wireless Propag. Lett., Vol. 21, pp. 2554-2558, 2021.
[22]http://www.ansys.com/Products/Simulation+Technology/Electronics/Signal+Integrity/ANSYS+HFSS
[23]A.W. M. S, K. A., P. R., T. A. and J. A., 2020 “A uniquely shaped MIMO antenna on FR4 material to enhance isolation and bandwidth for wireless applications, ” AEU - International Journal of Electronics and Communications, Vol. 123, pp. 153316.