Zobrazeno 1 - 10
of 196
pro vyhledávání: '"Xiaobang Shang"'
Autor:
Sang-Hee Shin, Roshan Payapulli, Liyan Zhu, Manoj Stanley, Xiaobang Shang, Nick M. Ridler, Stepan Lucyszyn
Publikováno v:
IEEE Access, Vol 10, Pp 41708-41719 (2022)
Polymer-based additive manufacturing using 3-D printing for upper-millimeter-wave (ca. 100 to 300 GHz) frequency applications is now emerging. Building on our previous work, with metal-pipe rectangular waveguides and free-space quasi-optical componen
Externí odkaz:
https://doaj.org/article/374cde5f5bfc4695a68e3fc8978d1103
Publikováno v:
Electronics Letters, Vol 59, Iss 1, Pp n/a-n/a (2023)
Abstract In this letter, the authors present a novel compact waveguide filtering twist that can be readily fabricated from metal using the computer numerical control (CNC) machining process. This filtering twist comprises four coupled resonators that
Externí odkaz:
https://doaj.org/article/d54d756ed36f46898ae57aca728ef9b0
Publikováno v:
IEEE Access, Vol 9, Pp 28020-28038 (2021)
Few examples of individual polymer-based 3-D printed quasi-optical component types have been previously demonstrated above ca. 100 GHz. This paper presents the characterization of polymer-based 3-D printed components and complete subsystems for quasi
Externí odkaz:
https://doaj.org/article/566c8cb951ea46708332f76c97d48adb
Autor:
Fan Zhang, Sufang Gao, Jin Li, Yang Yu, Cheng Guo, Sheng Li, Moataz Attallah, Xiaobang Shang, Yi Wang, Michael J. Lancaster, Jun Xu
Publikováno v:
IEEE Access, Vol 7, Pp 128026-128034 (2019)
In this paper, a third-order waveguide bandpass filter (BPF) based on slotted spherical resonators with a wide spurious-free stopband is presented. The resonator consists of a spherical cavity with slots opened at the top and bottom. Compared with a
Externí odkaz:
https://doaj.org/article/f726386d0b8441529ca21d1f460bd9d5
Publikováno v:
Microwave and Optical Technology Letters. 65:2378-2383
Publikováno v:
IEEE Microwave and Wireless Technology Letters. 33:153-156
Publikováno v:
IEEE Microwave and Wireless Technology Letters. 33:35-38
Publikováno v:
Sensors, Vol 22, Iss 5, p 1764 (2022)
This paper reports on a sensor based on multi-element complementary split-ring resonator for the measurement of liquid materials. The resonator consists of three split rings for improved measurement sensitivity. A hole is fabricated at the centre of
Externí odkaz:
https://doaj.org/article/cd667f8be5ba47639638b91024f17c56
Autor:
Yang Yu, Yi Wang, Talal Skaik, Thomas Starke, Xiaobang Shang, Michael J. Lancaster, Peter Hunyor, Peter G. Huggard, Hui Wang, Michael Harris, Mat Beardsley, Qingsha S. Cheng
Publikováno v:
IEEE Transactions on Components, Packaging and Manufacturing Technology. 12:1446-1457
Autor:
Alfred Leitenstorfer, Andrey S Moskalenko, Tobias Kampfrath, Junichiro Kono, Enrique Castro-Camus, Kun Peng, Naser Qureshi, Dmitry Turchinovich, Koichiro Tanaka, Andrea G Markelz, Martina Havenith, Cameron Hough, Hannah J Joyce, Willie J Padilla, Binbin Zhou, Ki-Yong Kim, Xi-Cheng Zhang, Peter Uhd Jepsen, Sukhdeep Dhillon, Miriam Vitiello, Edmund Linfield, A Giles Davies, Matthias C Hoffmann, Roger Lewis, Masayoshi Tonouchi, Pernille Klarskov, Tom S Seifert, Yaroslav A Gerasimenko, Dragan Mihailovic, Rupert Huber, Jessica L Boland, Oleg Mitrofanov, Paul Dean, Brian N Ellison, Peter G Huggard, Simon P Rea, Christopher Walker, David T Leisawitz, Jian Rong Gao, Chong Li, Qin Chen, Gintaras Valušis, Vincent P Wallace, Emma Pickwell-MacPherson, Xiaobang Shang, Jeffrey Hesler, Nick Ridler, Cyril C Renaud, Ingmar Kallfass, Tadao Nagatsuma, J Axel Zeitler, Don Arnone, Michael B Johnston, John Cunningham
Publikováno v:
Journal of Physics D: Applied Physics
Leitenstorfer, A, Moskalenko, A S, Kampfrath, T, Kono, J, Castro-Camus, E, Peng, K, Qureshi, N, Turchinovich, D, Tanaka, K, Markelz, A, Havenith, M, Hough, C, Joyce, H, Padilla, W, Zhou, B, Kim, K-Y, Zhang, X-C, Jepsen, P U, Dhillon, S, MIRIAM, SERENA VITIELLO, Linfield, E H, Hoffmann, M, Lewis, R, Tonouchi, M, Klarskov, P, Seifert, T, Gerasimenko, Y, Mihailovic, D D, Huber, R, Boland, J, Mitrofanov, O, Dean, P, Ellison, B, Huggard, P, Rea, S, Walker, C, Leisawitz, D, Gao, J R, Li, C, Chen, Q, Valusis, G, Wallace, V P, He, Y, Shang, X, Hesler, J, Ridler, N, Renaud, C, Kallfass, I, Nagatsuma, T, Zeitler, A, Arnone, D, Johnston, M B & Cunningham, J 2023, ' The 2023 Terahertz Science and Technology Roadmap ', Journal of Physics D: Applied Physics, vol. 56, no. 22, 223001 . https://doi.org/10.1088/1361-6463/acbe4c
Leitenstorfer, A, Moskalenko, A S, Kampfrath, T, Kono, J, Castro-Camus, E, Peng, K, Qureshi, N, Turchinovich, D, Tanaka, K, Markelz, A G, Havenith, M, Hough, C, Joyce, H J, Padilla, W J, Zhou, B, Kim, K Y, Zhang, X C, Jepsen, P U, Dhillon, S, Vitiello, M, Linfield, E, Davies, A G, Hoffmann, M C, Lewis, R, Tonouchi, M, Klarskov, P, Seifert, T S, Gerasimenko, Y A, Mihailovic, D, Huber, R, Boland, J L, Mitrofanov, O, Dean, P, Ellison, B N, Huggard, P G, Rea, S P, Walker, C, Leisawitz, D T, Gao, J R, Li, C, Chen, Q, Valušis, G, Wallace, V P, Pickwell-MacPherson, E, Shang, X, Hesler, J, Ridler, N, Renaud, C C, Kallfass, I, Nagatsuma, T, Zeitler, J A, Arnone, D, Johnston, M B & Cunningham, J 2023, ' The 2023 terahertz science and technology roadmap ', Journal of Physics D: Applied Physics, vol. 56, no. 22, 223001 . https://doi.org/10.1088/1361-6463/acbe4c
Leitenstorfer, A, Moskalenko, A S, Kampfrath, T, Kono, J, Castro-Camus, E, Peng, K, Qureshi, N, Turchinovich, D, Tanaka, K, Markelz, A, Havenith, M, Hough, C, Joyce, H, Padilla, W, Zhou, B, Kim, K-Y, Zhang, X-C, Jepsen, P U, Dhillon, S, MIRIAM, SERENA VITIELLO, Linfield, E H, Hoffmann, M, Lewis, R, Tonouchi, M, Klarskov, P, Seifert, T, Gerasimenko, Y, Mihailovic, D D, Huber, R, Boland, J, Mitrofanov, O, Dean, P, Ellison, B, Huggard, P, Rea, S, Walker, C, Leisawitz, D, Gao, J R, Li, C, Chen, Q, Valusis, G, Wallace, V P, He, Y, Shang, X, Hesler, J, Ridler, N, Renaud, C, Kallfass, I, Nagatsuma, T, Zeitler, A, Arnone, D, Johnston, M B & Cunningham, J 2023, ' The 2023 Terahertz Science and Technology Roadmap ', Journal of Physics D: Applied Physics, vol. 56, no. 22, 223001 . https://doi.org/10.1088/1361-6463/acbe4c
Leitenstorfer, A, Moskalenko, A S, Kampfrath, T, Kono, J, Castro-Camus, E, Peng, K, Qureshi, N, Turchinovich, D, Tanaka, K, Markelz, A G, Havenith, M, Hough, C, Joyce, H J, Padilla, W J, Zhou, B, Kim, K Y, Zhang, X C, Jepsen, P U, Dhillon, S, Vitiello, M, Linfield, E, Davies, A G, Hoffmann, M C, Lewis, R, Tonouchi, M, Klarskov, P, Seifert, T S, Gerasimenko, Y A, Mihailovic, D, Huber, R, Boland, J L, Mitrofanov, O, Dean, P, Ellison, B N, Huggard, P G, Rea, S P, Walker, C, Leisawitz, D T, Gao, J R, Li, C, Chen, Q, Valušis, G, Wallace, V P, Pickwell-MacPherson, E, Shang, X, Hesler, J, Ridler, N, Renaud, C C, Kallfass, I, Nagatsuma, T, Zeitler, J A, Arnone, D, Johnston, M B & Cunningham, J 2023, ' The 2023 terahertz science and technology roadmap ', Journal of Physics D: Applied Physics, vol. 56, no. 22, 223001 . https://doi.org/10.1088/1361-6463/acbe4c
Funder: Alexander von Humboldt Foundation
Funder: Experienced Researcher Fellowship
Funder: DFG Collaborative
Funder: PAPIIT
Funder: Danish National Research Foundation
Funder: JSPS
Funder: STFC Centre for Instrumentatio
Funder: Experienced Researcher Fellowship
Funder: DFG Collaborative
Funder: PAPIIT
Funder: Danish National Research Foundation
Funder: JSPS
Funder: STFC Centre for Instrumentatio
Externí odkaz:
https://explore.openaire.eu/search/publication?articleId=doi_dedup___::8cf90c7e7a566bbf609cf51df7c44819
https://hdl.handle.net/21.11116/0000-000C-C5A7-921.11116/0000-000C-F82C-C
https://hdl.handle.net/21.11116/0000-000C-C5A7-921.11116/0000-000C-F82C-C