王蒼容 Chun-Long Wang

職稱
王蒼容 Chun-Long Wang
教授
學歷
國立台灣大學電信博士
電子郵件
clw@mail.ntust.edu.tw
辦公室
EE711

Office Hours	Every Wednesday, 10:30~12:30 A.M.
電話	886-2-27301237
個人網頁	http://homepage.ntust.edu.tw/CLW/
實驗室	EE702-3
研究領域	電路轉接與連接、訊號完整度、電磁干擾、電磁封裝及微波元件
開授課程	被動微波元件, 高速電路板系統設計, 工程數學(一)

現職及經歷

2017.08 ~ 迄今	台灣科技大學電子系教授
2012.08 ~ 2017.07	台灣科技大學電子系副教授
2005.08 ~ 2012.07	台灣科技大學電子系助理教授
2005.04 ~ 2005.07	台灣大學電信所博士後研究
2003.10 ~ 2005.04	國防部少尉
2003.08 ~ 2003.10	台灣大學電信所博士後研究

重要研究成果

[1]	Introduction to Chun-Long Wang
[2]	王蒼容(中文簡介)

榮譽及獎勵

2023	chairman for Session A1, 2023 IEEE 5th Eurasia Conference on IoT, Communication and Engineering, 27-29 Oct. 2023, Yunlin, Taiwan.
2023	best paper award, 2023 IEEE 5th Eurasia Conference on IoT, Communication and Engineering, 27-29 Oct. 2023, Yunlin, Taiwan.
2023	全國高中職電機應用專題競賽審查委員
2017	committee member, 2017橋接未來電磁研討會暨科技部成果發表會, 16-18 Jan. 2017, Taipei, Taiwan.
2017	chairman, 明日之星, 2017橋接未來電磁研討會暨科技部成果發表會, 16-18 Jan. 2017, Taipei, Taiwan.
2017	chairman, 科技部成果展, 2017橋接未來電磁研討會暨科技部成果發表會, 16-18 Jan. 2017, Taipei, Taiwan.
2016	chairman for Antenna Techniques (II) session, 2016 IEEE International Symposium on Radio-Frequency Integration Technology (RFIT2016), 24-26 Aug. 2016, Taipei, Taiwan.
2016	committee member, 2016橋接未來電磁研討會暨科技部成果發表會, 25-27 Jan. 2016, Ilan, Taiwan.
2016	chairman, 科技部成果展, 2016橋接未來電磁研討會暨科技部成果發表會, 25-27 Jan. 2016, Ilan, Taiwan.
2015	chairman for signal integrity and power integrity session, Asia-Pacific International Symposium on Electromagnetic Compatibility, 25-29 May 2015, Taipei, Taiwan.
2015	committee member, 2015橋接未來電磁研討會暨科技部成果發表會, 28-30 Jan. 2015, Taoyuan, Taiwan.
2015	chairman, 廠商博覽會, 2015橋接未來電磁研討會暨科技部成果發表會, 28-30 Jan. 2015, Taoyuan, Taiwan.
2015	chairman, 科技部成果展, 2015橋接未來電磁研討會暨科技部成果發表會, 28-30 Jan. 2015, Taoyuan, Taiwan.
2011	best teaching award from the department of electronics engineering
2006	co-chairman for recent advances on periodic and multilayered structures session, Asia-Pacific Microwave Conference, 12-15 Dec. 2006, Yokohama, Japan.
2005	co-chairman for signal integrity session, Asia Pacific Symposium on EMC, 6-9 Dec. 2005, Taipei, Taiwan.
1995	斐陶斐學會榮譽會員

研究成果

期刊論文

[1]	I.-V. Tseng, M.-F. Zheng, T.-T. Cho, and C.-L. Wang, “Compact and broadband CPW-to-RWG transition using resonator with impedance-matching element,” Progress In Electromagnetics Research Letters, vol. 116, pp. 71-78, Jan. 2024.
[2]	J.-D. Cai, K.-C. Chen, and C.-L. Wang, “Mode conversion and common-mode noise reduction using periodic structure filter,” IEEE Trans. Electromagnetic Compatibility, vol. 64, no. 4, pp. 1021-1030, Aug. 2022.
[3]	W.-C. Lu, C.-H. Wu, C.-Y. Yeh, C.-H. Wu, C.-L. Wang, and L. A. Wang, “D-shaped silicon-cored fibers as platform to build in-line Schottky photodetectors,” Photonics Technology Letters, vol. 33, no. 6, pp. 317-320, Mar. 2021.
[4]	C.-Y. Liao, J.-D. Cai, J.-C. Guo, and C.-L. Wang, “Right-angled coplanar waveguide using short-circuited slotline,” IEEE Trans. Electromagnetic Compatibility, vol. 63, no. 1, pp. 215-228, Feb. 2021.
[5]	S.-H. Wang, C.-C. Chang, Y.-C. Lee, and C.-L. Wang, “Compact and broadband CPW-to-RWG transition using stub resonators,” IEEE Trans. Microwave Theory and Techniques, vol. 64, no. 10, pp. 3198–3207, Oct. 2016.
[6]	B.-R. Huang, K.-C. Chen, and C.-L. Wang, “Far-end crosstalk noise reduction using decoupling capacitor,” IEEE Trans. Electromagnetic Compatibility, vol. 58, no. 3, pp. 836–848, Jun. 2016.
[7]	C.-C. Yeh, K.-C. Chen, and C.-L. Wang, “Common-mode noise suppression of differential serpentine delay line using timing-offset differential signal,” IEEE Trans. Electromagnetic Compatibility, vol. 57, no. 6, pp. 1457–1465, Dec. 2015.
[8]	C.-C. Yeh, B.-R. Huang, K.-C. Chen, R.-Y. Fang, and C.-L. Wang, “Reduction of common-mode and differential-mode noises using timing-offset differential signal,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 5, no. 12, pp. 1818–1827, Dec. 2015.
[9]	B. R. Huang, C. H. Chang, R. Y. Fang, and C. L. Wang, “Common-mode noise reduction using asymmetric coupled line with SMD capacitor,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 4, no. 6, pp. 1082–1089, Jun. 2014.
[10]	J. K. Chuang, R. Y. Fang, and C. L. Wang, “Compact and broadband rectangular waveguide power divider/combiner using microstrip-fed antisymmetric tapered probe,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 4, no. 1, pp. 109–116, Jan. 2014.
[11]	J. K. Chuang, R. Y. Fang, Y. J. Huang, Y. C. Lee, C. L. Wang, and K. Y. Lee, “A broadband-matched load using multiwalled carbon nanotubes,” IEEE Trans. Nanotechnol., vol. 12, no. 6, pp. 1213–1218, Nov. 2013.
[12]	R. Y. Fang, and C. L. Wang, “Miniaturized microstrip-to-waveguide transition using capacitance-compensated broadside-coupled microstrip line,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 9, no. 9, pp. 1588–1596, Sep. 2013.
[13]	R. Y. Fang, C. T. Wang, and C. L. Wang, “A broadband CPW to rectangular waveguide power divider using a slot,” International Journal of RF and Microwave Computer-Aided Engineering, vol. 23, no. 2, pp. 232–237, Mar. 2013.
[14]	R. Y. Fang, C.-F. Liu, and C. L. Wang, “Compact and broadband CB-CPW-to-SIW transition using stepped-impedance resonator with 90°-bent slot,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 3, no. 2, pp. 247–252, Feb. 2013.
[15]	R. Y. Fang and C. L. Wang, “Miniaturized coplanar waveguide to rectangular waveguide transition using inductance-compensated slotline,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 2, no. 10, pp. 1666–1671, Oct. 2012.
[16]	C. H. Chang, R. Y. Fang, and C. L. Wang, “Bended differential transmission line using compensation inductance for common-mode noise suppression,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 2, no. 9, pp. 1518–1525, Sep. 2012.
[17]	J. K. Chuang, R. Y. Fang, and C. L. Wang, “Compact and broadband microstrip-to-waveguide transition using antisymmetric tapered probes,” Electron. Lett., vol. 48, no. 6, 15th Mar. 2012.
[18]	R. Y. Fang and C. L. Wang, “Broadband slotline-to-rectangular waveguide transition using a truncated bow-tie antenna,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 1, no. 8, pp. 1154–1159, Aug. 2011.
[19]	R. Y. Fang, C. T. Wang, and C. L. Wang, “Coplanar-to-rectangular waveguide transitions using slot antennas,” IEEE Trans. Components, Packaging, and Manufacturing Technology, vol. 1, no. 5, pp. 681–688, May 2011.
[20]	C. F. Hung, A. S. Liu, C. H. Chien, C. L. Wang, and R. B. Wu, “Bandwidth enhancement on waveguide transition to conductor backed CPW with high dielectric constant substrate,” IEEE Microwave Wireless Compon. Lett., vol. 15, pp. 128–130, Feb. 2005.
[21]	S. W. Wang, C. H. Chien, C. L. Wang, and R. B. Wu, “A circular polarizer designed with a dielectric septum loading,” IEEE Trans. Microwave Theory Tech., vol. 52, pp. 1719–1723, Jul. 2004.
[22]	C. L. Wang, and R. B. Wu, “Modeling and design for electrical performance of wideband flip-chip transition,” IEEE Trans. Advanced Packaging, vol. 26, no. 4, pp. 385–391, Nov. 2003.

會議論文

[1]	S.-S. Li and C.-L. Wang, “Far-end crosstalk suppression of serpentine delay line using high-impedance line,” 2023 IEEE 5th Eurasia Conference on IoT, Communication and Engineering (ECICE), Oct. 2023.
[2]	C.-Y. Liao and C.-L. Wang, “Compact right-angled coplanar waveguide using central short-circuited slotline,” International Conference on Electrical Engineering and Electronics (EEE), Jul. 2022.
[3]	Y.-C. Lee and C.-L. Wang, “Ultra-wideband microstrip-fed antenna using magnetic loop,” International Conference on Electrical Engineering and Electronics (EEE), Aug. 2021.
[4]	C.-C. Yeh, W.-J. Chen, and C.-L. Wang, “Bended differential stripline using timing-offset differential signal,” International Symposium on Intelligent Signal Processing and Communication Systems (ISPACS), Dec. 2019.
[5]	C.-C. Yeh, Y.-H. Lu, and C.-L. Wang, “Differential serpentine delay line using strongly-coupled turns with timing-offset differential signal,” IEEE Electrical Design of Advanced Packaging and Systems (EDAPS) Symposium, Dec. 2019.
[6]	C.-F. Liu, Y.-H. Lu, and C.-L. Wang, “GCPW-to-SIW transition using tapered slot,” International Conference on Electrical Engineering and Electronics (EEE), Aug. 2019.
[7]	C.-H. Chang, W.-J. Chen, and C.-L. Wang, “Right-angled differential transmission line using un-chamfered inductive layout,” International Conference on Electrical Engineering and Electronics (EEE), Aug. 2019.
[8]	W.-C. Lu, C.-H. Wu, L. A. Wang, and C.-L. Wang, “Improved responsivity and bandwidth of Schottky photodetector made on silicon cored fiber by using D-shaped polishing method,” IEEE International Conference on Optical MEMS and Nanophotonics (OMN), Jul. 2019.
[9]	S.-H. Wang and C.-L. Wang, “Compact and broadband 50-ohms CPW-to-RWG transition,” 40th Photonics and Electromagnetics Research Symposium (PIERS), Aug. 2018.
[10]	C.-Y. Liao, Y.-H. Cheng, and C.-L. Wang, “Power loss reduction on right-angled CPW bend using finger slots,” IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting, 2017, pp. 81–82.
[11]	J.-K. Chuang, Y.-H. Cheng, and C.-L. Wang, “Compact and broadband microstrip-fed antenna using antisymmetric tapered probe with triangular element,” IEEE International Symposium on Radio-Frequency Integration Technology (RFIT) 2016.
[12]	C.-C. Yeh and C.-L. Wang, “Common-mode noise reduction of right-angled coupled stripline using timing-offset differential signal,” 20th IEEE Workshop on Signal and Power Integrity, May 2016.
[13]	C.-Y. Lin, B.-R. Huang, K.-C. Chen, and C. L. Wang, “Common-mode noise suppression using decoupling capacitor,” IEEE 4th International Symposium on Next-Generation Electronics, May 2015.
[14]	B.-R. Huang, C.-H. Chang, R.-Y. Fang, and C. L. Wang, “Bended differential transmission line using compensation inductance and capacitance,” 19th IEEE Workshop on Signal and Power Integrity, May 2015.
[15]	C.-Y. Lin, B.-R. Huang, Z.-S. Yan, and C. L. Wang, “Differential-mode noise suppression using L-shaped pad,” 2015 Asia-Pacific International Symposium on Electromagnetic Compatibility, May 2015.
[16]	Y. C. Lee and C. L. Wang, “Compact and UWB microstrip-fed monopoles antenna,” IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting, 2014, pp. 1827–1828.
[17]	C. C. Yeh, B. R. Huang, R. Y. Fang, and C. L. Wang, “Differential transmission line using timing-offset differential signal,” 37th International Spring Seminar on Electronics Technology (ISSE) 2014.
[18]	C. Y. Lin, B. R. Huang, and C. L. Wang, “Common-mode noise suppression using SMD capacitor with grounded via,” IEEE International Symposium for Design and Technology in Electronic Packaging (SIITME) 2013.
[19]	R. Y. Fang, C. F. Liu, C. Y. Liao, and C. L. Wang, “High-low impedance transformer using transmission line method,” IEEE International Symposium for Design and Technology in Electronic Packaging (SIITME) 2013, pp. 185–189.
[20]	C. Y. Lin, Y. C. Lee, C. Y. Liao, and C. L. Wang, “Reflection noise elimination using bondwire-free balanced CPW,” Asia-Pacific Radio Science Conference 2013, E1b-1.
[21]	C. H. Chang, R. Y. Fang, and C. L. Wang, “Bended differential transmission line using balanced model for common-mode noise suppression,” IEEE Electrical Design of Advanced Packaging and Systems Symposium 2012, pp. 37–40.
[22]	R. Y. Fang, J. K. Chuang, and C. L. Wang, “Coplanar waveguide-to-rectangular waveguide transition using meander slotline,” Asia-Pacific Microwave Conference 2011, pp. 399–402.
[23]	J. K. Chuang, C. J. Hsiao, R. Y. Fang, C. L. Wang, and K. Y. Lee, “Broadband patch absorber using multi-walled carbon nanotubes,” 24th International Microprocesses and Nanotechnology Conference 2011, pp. 27P-11-30.
[24]	C. H. Chang, R. Y. Fang, and C. L. Wang, “Bended differential transmission line using short-circuited coupled line for common-node noise suppression,” IEEE 20th Conference on Electrical Performance of Electronic Packaging and Systems 2011, pp. 291–294.
[25]	R. Y. Fang, C. F. Liu, and C. L. Wang, “Compact stepped-impedance resonator transformer,” IEEE 20th Conference on Electrical Performance of Electronic Packaging and Systems 2011, pp. 303–306.
[26]	R. Y. Fang, C. T. Wang, and C. L. Wang, “A direct CPW-to-rectangular waveguide transition using a dipole slot antenna,” European Microwave Conference 2009, pp. 157–160.
[27]	R. Y. Fang and C. L. Wang, “A coplanar waveguide to rectangular waveguide transition using a truncated bow-tie antenna,” European Microwave Conference 2008, pp. 468–471.
[28]	R. Y. Fang and C. L. Wang, “Wideband slotline-to-rectangular waveguide transition using truncated bow-tie antenna,” Asia-Pacific Microwave Conference 2006, pp. 1399–1402.
[29]	T. H. Yang, C. F. Chen, T. Y. Huang, C. L. Wang, R. B. Wu, “A 60GHz LTCC transition between microstrip line and substrate integrated waveguide,” Asia-Pacific Microwave Conference 2005, p1.41.
[30]	C. F. Hung, A. S. Liu, C. L. Wang, and R. B. Wu, “A broadband conductor backed CPW to waveguide transition realized on high dielectric constant substrate,” Asia-Pacific Microwave Conference 2003, pp. 1038–1041.
[31]	S. W. Wang, C. L. Wang, and R. B. Wu, “A novel uniplanar bandpass filter with CPW-fed step-perturbed slot ring resonator,” Asia-Pacific Microwave Conference 2003, pp. 669–672.
[32]	C. L. Wang, and R. B. Wu, “Wideband coplanar waveguide flip-chip transition,” Proceedings of the 2002 National Symposium on Telecommunications, RF-4-1.
[33]	C. J. Tsai, C. L. Wang, and R. B. Wu, “A simple idea for realizing a sharp bandpass filter with two types of microstrip ring resonators,” Asia-Pacific Microwave Conference 2002, pp. 867–869.
[34]	C. L. Wang, and R. B. Wu, “A locally matching technique for broadband flip-chip transition design,” IEEE MTT-Symp. Dig., 2002, pp. 1397–1400.
[35]	C. L. Wang, and R. B. Wu, “Locally matching design for flip-chip transition,” Asia-Pacific Microwave Conference 2001, pp. 547–549.
[36]	W. H. Tu, C. L. Wang, and R. B. Wu, “Hermetic housing design for TR module in LMDS system,” Asia-Pacific Microwave Conference 2001, pp. 153 –156.

專利

著作

其他

[1]	2024年，於「邑昇實業股份有限公司」，教授產業界人士「高速PCB電路設計簡介」之課程。
[2]	2013~2023年，參與「電磁聯盟工業局智慧電子人才培訓課程」，教授產業界人士「訊號完整度原理與量測實務應用」之課程。
[3]	2018年，參與「欣興電子高速高頻產品相關問題課程」，教授產業界人士「串音耦合的原理、遠端串音與近端串音的生成與防制以及印刷電路板串音干擾防制」之課程。

研究成果

研究計畫

計畫名稱	計畫總額	執行始於	執行結束	委託單位
小型化且寬頻的導通孔雜訊抑制架構	805,000	202308	202407	國科會
立端公司產學合作計畫		202208	202305
直角差動傳輸線的模轉換與共模雜訊抑制	789,000	202108	202207	科技部
小型化且寬頻的矩形波導轉接及圓形波導極化器	950,000	202008	202107	科技部
地面電路在微型且寬頻的天線、轉接、功率分配器之應用	904,000	201908	202007	科技部
不需使用磅線及介電質補償的九十度彎角共面波導結構	921,000	201808	201907	科技部
不受輸入阻抗限制的小型化且寬頻的共面波導至矩形波導轉接	642,000	201708	201807	科技部
使用去耦合電容來降低遠端串擾雜訊	818,000	201608	201707	科技部
使用位移時間差動訊號來降低共模及差模雜訊	738,000	201508	201607	科技部
使用非對稱耦合線結合SMD電容來降低差動傳輸線的共模雜訊及差模反射	612,000	201408	201507	科技部
非對稱探針在微型且寬頻的天線、轉接、功率分配器之應用	702,000	201308	201407	國科會
微型且寬頻的平面傳輸線至矩形波導轉接	739,000	201208	201307	國科會
使用補償電感消除直角差動傳輸線的共模雜訊	607,000	201108	201207	國科會
寬頻共面波導至矩形波導功率分配器	580,000	201008	201107	國科會
縮小化之寬頻共面波導至基板合成波導轉接	791,000	200908	201007	國科會
射頻辨識(RFID)系統關鍵技術之研發與應用-分項計畫A: RFID射頻關鍵技術之研發	4,257,200	200907	201006	經濟部技術處學界科專專案辦公室
截斷式領結天線於共面波導至矩形波導轉接之應用	649,000	200808	200907	國科會
低頻電台廣播所產生電波干擾之模擬分析	970,000	200801	200901	中華電信研究所
寬頻共面波導到基板合成波導之轉接	485,000	200608	200707	國科會

指導學生

博士生

學年	論文題目	學生
96	縮小化平面傳輸線至矩形波導轉接	方瑞穎

碩士生

學年	論文題目	學生
103	單層佈線之週期性共模濾波器	陳冠中
102	微小且寬頻的多極天線及多共振轉接	李元鈞
102	使用無鎊線技術消除彎角共面波導雜訊	廖婕宇
101	耦合微帶線之遠端雜訊消除	黃保仁
101	寬頻微小化共面波導至矩形波導轉接	王思翰
100	寬頻漸變探針轉接及其在矩形波導功率分配器之應用	莊竣凱
100	使用位移時間差動訊號消除共模雜訊	葉治成
99	彎曲共平面傳輸線的共模雜訊抑制	林哲宇
98	蛇線與直線間的遠端串音消除	李式賢
97	彎曲差動傳輸線的共模雜訊抑制	張加翰
96	使用多階傳輸線設計小型化之加地面的共面波導至基板整合波導轉接	劉佳芬
96	使用槽型天線之共面波導至矩形波導轉接	王晟澤
95	運用領結天線之平面電路至矩形波導轉接	方瑞穎

指導專題

學年	專題題目	學生
111	耦合微帶線之共模濾波器	羅兆富
106	印刷電路板佈線干擾之防制	李冠謀
103	印刷電路板佈線干擾之防制	鄭又豪
103	平面傳輸線至矩形波導轉接	黃勇綸
102	平面傳輸線至矩形波導轉接	王泓崴
102	印刷電路板佈線干擾之防制	黃鉦原
101	微帶線餽入之寬頻天線	張雅婷
101	印刷電路板佈線干擾之防制	施昀晴
99	微帶線到矩形波導之轉接	李元鈞
98	印刷電路板佈線的耦合干擾防制	李子傑
97	傳輸線補償電路之設計	羅堯文
96	平面電路到基板合成波導之轉接	朱國廷、黃超元

特殊榮譽

年份	事蹟
0	無