本論文提出應用於高屏占比輕薄筆記型電腦之邊框天線整合設計，由於近年來通訊系統技術蓬勃發展及消費者基外觀需求考量，使筆記型電腦天線設計空間逐漸嚴峻，所以提出五款應用於高屏占比輕薄筆記型電腦之邊框天線整合設計，天線均具有小型化多頻段天線設計特性，分別設計各兩款可應用於非金屬邊框之筆電螢幕面與金屬邊框之筆電螢幕面環境之操作於Wi-Fi 6E(2.4-2.5 GHz、5.15-5.85 GHz、5.925-7.125 GHz)及5G NR n77(3300-4200 MHz)；n78(3300-3800 MHz)；n79(4400-5000 MHz)頻段天線設計，及一款應用於金屬邊框之筆電鍵盤面環境之操作於 4G LTE(698-787 MHz、2.3-2.69 GHz)頻段天線設計。

　　第一款天線結合IFA、Loop Antenna設計在螢幕面非金屬邊框天線架構，操作於Wi-Fi 6E頻段，可實現2 × 2 MIMO系統(以下稱Antenna-1)；第二款結合IFA、Loop Antenna及上下結構交錯的方式擺放於螢幕面非金屬邊框天線架構，操作於5G n77/n78/n79頻段，可實現4 × 4 MIMO系統(以下稱Antenna-2)；第三款天線結合 Loop、Slot Antenna設計於筆電螢幕面角落金屬邊框天線，操作於5G n77/n78/n79頻段，可實現4 × 4 MIMO系統(以下稱Antenna-3)；第四款天線是基於Antenna-3的結構進行延伸設計，其中Port I1、Port I3天線以Slit Antenna、Slot Antenna、IFA結合設計於筆電螢幕面角落金屬邊框天線，Port I2、Port I4天線均採用Antenna-3結構，操作於Wi-Fi 6E & 5G n77/n78/n79頻段可實現2 × 2 MIMO系統(以下稱Antenna-4)；第五款天線結合IFA、Monopole Antenna、匹配電路設計於筆電鍵盤面角落金屬邊框操作於4G LTE頻段，此筆記型電腦環境適用於兩組模組共四支天線，可實現4 × 4 MIMO系統(以下稱Antenna-5)。

　　The main objective of this thesis design of integrated frame antennas for high screen-to-body ratio of laptop. Due to the vigorous development of communication system technology and consumer-based appearance requirements in recent years, the design space of notebook computer antennas has gradually become severe. Therefore, five integrated design of frame antennas applied to thin and light notebook computers with high screen-to-body ratio are proposed. Design features of miniaturized multi-band antennas, each designed to be applicable to the laptop screen with non-metal frame and the laptop screen with metal frame. Operation in Wi-Fi 6E (2.4-2.5 GHz, 5.15-5.85 GHz) , 5.925-7.125 GHz) and 5G NR n77 (3300-4200 MHz); n78 (3300-3800 MHz); n79 (4400-5000 MHz) frequency band antenna design, and a laptop keyboard surface environment for metal frame Operate in 4G LTE (698-787 MHz, 2.3-2.69 GHz) frequency band antenna design.

　　The first antenna combined with IFA and Loop Antenna is designed on the screen surface with a non-metal frame antenna structure, which operates in the Wi-Fi 6E frequency band and can realize a 2 × 2 MIMO system (hereinafter referred to as Antenna-1); the second combined with IFA and Loop Antenna And the upper and lower structures are placed in a non-metallic frame antenna structure on the screen surface in a staggered manner, operating in the 5G n77/n78/n79 frequency band, which can realize a 4 × 4 MIMO system (hereinafter referred to as Antenna-2); the third antenna combines Loop and Slot Antenna is designed for the metal frame antenna at the corner of the laptop screen. It operates in the 5G n77/n78/n79 frequency band and can realize a 4×4 MIMO system (hereinafter referred to as Antenna-3); the fourth antenna is an extension based on the structure of Antenna-3 Design, Port I1 and I3 antennas are designed in combination with Slit Antenna, Slot Antenna, IFA and metal frame antennas at the corners of the laptop screen. Port I2 and I4 antennas are all designed with Antenna-3 structure and operate on Wi-Fi 6E & 5G n77/ The 78/79 frequency band can realize the 2 × 2 MIMO system (hereinafter referred to as Antenna-4); the fifth antenna is combined with IFA, Monopole Antenna, and matching circuit designed in the corner of the laptop keyboard surface. The metal frame operates in the 4G LTE frequency band. This laptop The environment is suitable for two groups of modules with a total of four antennas, which can realize a 4 × 4 MIMO system(hereinafter referred to as Antenna-5).

摘 要
ABSTRACT
誌 謝
目 錄
表目錄
圖目錄
第一章 序論
1.1 研究背景
1.2 研究目的
1.3 文獻導覽
1.4 論文題要
第二章 非金屬邊框之筆電螢幕面天線整合設計
2.1 前言
2.2 天線設計原理與結構
2.3 天線實驗與量測結果
2.4 天線結構參數與探討
2.5 結論
第三章 金屬邊框之筆電螢幕面天線整合設計
3.1 前言
3.2 天線設計原理與結構
3.3 天線實驗與量測結果
3.4 天線結構參數與探討
3.5 結論
第四章 金屬邊框之筆電鍵盤面天線整合設計
4.1 前言
4.2 天線設計原理與結構
4.3 天線實驗與量測結果
4.4 天線結構參數與探討
4.5 結論
第五章 結論與未來展望
參考文獻

[1]綜觀全頻段組態/介面/佈局5G筆電天線設計細思量|新通訊，網址：https://www.2cm.com.tw/2cm/zh-tw/tech/9A2442E66D9541BEA4C33E3DCD9B9567
[2]3GPP Release 15，網址：https://www.3gpp.org/release-15
[3]Wi-Fi CERTIFIED 6 | Wi-Fi Alliance，網址：https://www.wi-fi.org/discover-wi-fi/wi-fi-certified-6
[4]Wikipedia, IEEE 802.11ax，網址：https://zh.wikipedia.org/wiki/IEEE_802.11ax
[5]Wikipedia, 5G_NR_frequency_bands，網址：https://en.wikipedia.org/wiki/5G_NR_frequency_bands
[6]郭宥睿，應用於全金屬筆電天線設計，碩士論文，國立成功大學電機工程學系，台南，2018。
[7]黃柏瑀，螢幕高佔比筆記型電腦之多天線設計，碩士論文，國立高雄科技大學光電工程研究所，高雄，2020。
[8]K. L. Wong, "5G/B5G multi-Gbps antennas for user terminals and their throughput verification," 2020 IEEE Asia-Pacific Microwave Conference (APMC), Hong Kong, Hong Kong, 2020, pp. 366-368.
[9]Y. H. Chen, K. L. Wong, and W. Y. Li, " 4×4 MIMO performance of two conjoined dual wideband antennas including the feedline effects for 5G smartphones," 2019 IEEE Asia-Pacific Microwave Conference (APMC), Singapore, 2019, pp. 1488-1490.
[10]C. Y. Tsai, K. L. Wong, and W. Y. Li, "Experimental results of the multi-Gbps smartphone with 20 MIMO antennas in the 20x12 MIMO operation," Microwave Opt. Technol. Lett., Vol. 60, pp. 2001-2010, Aug. 2018.
[11]K. L. Wong, B. W. Lin, and W. Y. Lin, “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, Apr. 2017.
[12]S. Chen, C. Chiang, and C. I. G. Hsu, "Compact four-element MIMO antenna system for 5G laptops," IEEE Access, vol. 7, pp. 186056-186064,Dec. 2019
[13]K. L. Wong, C. Y. Tsai, and W. Y. Li, "Integrated yet decoupled dual antennas with inherent decoupling structures for 2.4/5.2/5.8-GHz WLAN MIMO operation in the smartphone," Microwave Opt. Technol. Lett., Vol. 59, pp. 2235-2241, Sep. 2017.
[14]W. Y. Li, W. Chung, and K. L. Wong, "Compact quad-offset loop/IFA hybrid antenna array for forming eight 3.5/5.8 GHz MIMO antennas in the future smartphone," 2018 ISAP, pp. 179-180, Oct. 2018.
[15]J. Guo, L. Cui, C. Li, and B. Sun, "Side-edge frame printed eight-port dual-band antenna array for 5G smartphone applications," IEEE Transactions on Antennas and Propagation, vol. 66, no. 12, pp. 7412-7417, Dec. 2018.
[16]S. Chen, Y. Tsou and, C. Huang, "LTE/WWAN monopole antenna integration with hinge slot region in the laptop computer," 2016 IEEE 5th Asia-Pacific Conference on Antennas and Propagation (APCAP), Kaohsiung, Taiwan, 2016, pp. 113-114.
[17]S. Chen, J. Sze, H. Jian, and W. Cai, "Loop antenna for the LTE/WWAN metal-casing laptop computer," 2017 IEEE International Conference on Computational Electromagnetics (ICCEM), Kumamoto, 2017, pp. 150-152.
[18]S. Chen and C. Fu, "Switchable long-term evolution/ wireless wide area network/ wireless local area network multiple-input and multiple-output antenna system for laptop computers," IEEE Access, vol. 5, pp. 9857-9865, May 2017.
[19]S. Chen and M. Hsu, "LTE MIMO closed slot antenna system for laptops with a metal cover," IEEE Access, vol. 7, pp. 28973-28981, Mar. 2019.
[20]P. W. Lin and K. L. Wong, "Dual-feed small-size LTE/WWAN strip monopole antenna for tablet computer applications," Microwave Opt. Technol. Lett., Vol. 55, pp. 2571-2576, Nov. 2013.
[21]M. S. Sharawi, "Printed multi-band MIMO antenna systems and their performance metrics [wireless corner]," IEEE Antennas and Propagation Magazine, vol. 55, no. 5, pp. 218-232, Oct. 2013.
[22]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, May 2019.