0. 天線工程期中報告
論文研討:
Kin-Lu Wong and Yu-Chen Chen
“Small-Size Hybrid Loop/Open-Slot Antenna for the LTE Smartphone ,” IEEE Transactions on Antenna and Propagation , no. 99 , pp.1-1, 2015.
報告人:
碩研電子一甲 MA 呂子齊
Southern Taiwan University of Science and Technology

1. Outline
1.摘要
2.天線設計
3.實測與模擬天線輻射效率
4.結論
5.心得
參考文獻

2. 摘要 運用LOOP、開槽孔作為天線的架構。 運用LC電路特性來調整模態的匹配。 利用槽孔激發模態，並有效地增加頻寬。
參考文獻 A simple circularly polarized loop tag antenna for increased reading distance

3. 天線設計(1) 1.整體尺寸:140 X 75 X 5.8 mm3 2.天線輻射尺寸:40 X 7 X 5.8 mm3
3.操作頻帶:0.698GHz~0.96GHz、1.71GHz~2.69GHz、3.4GHz~3.8GHz

4. 天線設計(2)
探討Ant1和Ant1a不同類型所產生不同的結果，當為Ant1a(增加LC)時，可以發現在低頻會比Ant1多一個模態，高頻的部分也會有較寬的頻寬。

5. 天線設計(3) 左圖為探討開槽孔天線部分(將正面移除)和Proposed的差異，可以發現再1/4波長共振出一個約在1.8GHz的模態。
右圖則是探討 t 路徑長度改變，所造成的變化，可以看到在1.9GHz的模態會隨著路徑的增加而漸漸往低頻移動。

6. 實測與模擬天線輻射效率
此圖為表示天線在低、中、高頻，所表現出的天線輻射效率，可以看見在實測與模擬之間並沒有太大的不同。

7. 結論
本天線利用各以1/4波長共振的LOOP及開槽孔架 構來產生出我們所需要的模態，該天線更以一小 尺寸面積(7*40mm2)作為天線輻射主體面積，以 有效減少天線在產品內部所佔據的範圍，同時該 天線設計可以將LTE的低、中、高頻的操作頻段 都包含進去，以達到多頻的應用。

8. 心得 本文的天線設計是以開槽孔及LOOP的方式下去共振出所需要的模態，在近一步以LC電路匹配的方式來達成我們所需要的頻帶。

9. 參考文獻
[1] Y. W. Chi and K. L. Wong, “Very-small-size printed loop antenna for GSM/DCS/PCS/UMTS operation in the mobile phone,” Microwave Opt. Technol. Lett., vol. 51, pp , Jan
[2] Y. W. Chi and K. L. Wong, “Quarter-wavelength printed loop antenna with an internal printed matching circuit for GSM/DCS/PCS/UMTS operation in the mobile phone,” IEEE Trans. Antennas Propag., vol. 57, pp , Sep
[3] K. L. Wong, W. Y. Chen, and T. W. Kang, “On-board printed coupled-fed loop antenna in close proximity to the surrounding ground plane for penta-band WWAN mobile phone,” IEEE Trans. Antennas Propag., vol. 59, pp , Mar
[4] Y. L. Ban, S. Yang, Z. Chen, K. Kang, and J. L. W. Li, “Decoupled planar WWAN antennas with T-shaped protruded ground for smartphone applications,” IEEE Antennas Wireless Propag. Lett., vol. 13, pp , 2014.
[5] H. Wang, M. Zheng, and S. Q. Zhang, “Monopole slot antenna,” US
Patent No B2, Sep
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10. [8] K. L. Wong, P. W. Lin, and C. H. Chang, “Simple printed monopole slot antenna for penta-band WWAN operation in the mobile handset,” Microwave Opt. Technol. Lett., vol. 53, pp , Jun [9] B. Yuan, Y. Cao, G. Wang, and B. Cui, “Slot antenna for metal-rimmed mobile handsets,” IEEE Antennas Wireless Propag. Lett., vol. 11, pp , [10] C. Q. Lei, Y. L. Ban, J. H. Chen and J. L. W. Li, “Small-size slot antenna for seven-band LTEIWWAN mobile phone operation,” 2012 IEEE International Workshop on Electromagnetics: Applications and Student Innovation Competition (iWEM), pp. 1- 2, Chengdu, China. [11] K. L. Wong, Planar Antennas for Wireless Communications. New York: Wiley, [12] I. Poole, “LTE frequency bands and spectrum allocations,” [Online] Available: [13] K. L. Wong and T. W. Weng, “Small-size triple-wideband LTE/WWAN tablet device antenna,” IEEE Antennas Wireless Propag. Lett., vol. 12, pp , [14] K. L. Wong and Z. G. Liao, “Passive reconfigurable triple-wideband antenna for LTE tablet computer,” IEEE Trans. Antennas Propag., vol. 63, Mar (to appear) [15] C. W. Chiu, C. H. Chang, and Y. J. Chi, “A meandered loop antenna for LTE/WWAN operations in a smartphone,” Progress In Electromagnetics Research C, vol. 16, pp , 2010.

11. [16] K. L. Wong and W. Y. Chen, “Small-size printed loop-type antenna integrated with two stacked coupled-fed shorted strip monopoles for eight-band LTE/GSM/UMTS operation in the mobile phone,” Microwave Opt. Technol. Lett., vol. 52, pp , [17] C. T. Lee and K. L. Wong, “Planar monopole with a coupling feed and an inductive shorting strip for LTE/GSM/UMTS operation in the mobile phone,” IEEE Trans. Antennas Propag., vol. 58, pp , Jul [18] K. L. Wong, T. W. Kang, and M. F. Tu, “Internal mobile phone antenna array for LTE/WWAN and LTE MIMO operations,” Microwave Opt. Technol. Lett., vol. 53, pp , [19] F. H. Chu and K. L. Wong, “Internal coupled-fed dual-loop antenna integrated with a USB connector for WWAN/LTE mobile handset,” IEEE Trans. Antennas Propag., vol. 59, pp , Nov [20] C. W. Yang, Y. B. Jung, and C. W. Jung, “Octaband internal antenna for 4G mobile handset,” IEEE Antennas Wireless Propag. Lett., vol. 10, pp , [21] D. G. Kang and Y. Sung, “Coupled-fed planar printed shorted monopole antenna for LTE/WWAN mobile handset applications,” IET Microw. Antennas Propag., vol. 6, pp. 1007–1016, [22] Y. L. Ban, C. L. Liu, J. L. W. Li, J. Guo, and Y. Kang, “Small-size coupled-fed antenna with two printed distributed inductors for seven-band WWAN/LTE mobile handset,” IEEE Trans. Antennas Propag., vol. 61, pp , Nov

12. [23] J. H. Lu and J. L. Guo, “Small-size octaband monopole antenna in an LTE/WWAN mobile phone,” IEEE Antennas Wireless Propag., vol. 13, pp , [24] ANSYS HFSS. [Online] Available: ANSYS/staticassets/resourcelibrary/brochure/ansys-hfss-brochu re-16.0.pdf, [25] K. L. Wong and M. T. Chen, “Small-size LTE/WWAN printed loop antenna with an inductively coupled branch strip for bandwidth enhancement in the tablet computer,” IEEE Trans. Antennas Propag., vol. 61, pp , Dec

13. THE END