{"type":"dissertation","date_updated":"2022-02-17T12:24:05Z","series_title":"Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn","language":[{"iso":"eng"}],"date_created":"2021-09-14T07:06:42Z","user_id":"15931","related_material":{"link":[{"url":"https://digital.ub.uni-paderborn.de/urn/urn:nbn:de:hbz:466:2-15420","relation":"confirmation"}]},"citation":{"apa":"Wang, R. (2015). <i>Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications</i> (Vol. 338). Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn.","short":"R. Wang, Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications, Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn, 2015.","chicago":"Wang, Ruoyu. <i>Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications</i>. Vol. 338. Verlagsschriftenreihe Des Heinz Nixdorf Instituts, Paderborn. Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn, 2015.","ieee":"R. Wang, <i>Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications</i>, vol. 338. Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn, 2015.","bibtex":"@book{Wang_2015, series={Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn}, title={Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications}, volume={338}, publisher={Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn}, author={Wang, Ruoyu}, year={2015}, collection={Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn} }","ama":"Wang R. <i>Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications</i>. Vol 338. Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn; 2015.","mla":"Wang, Ruoyu. <i>Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications</i>. Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn, 2015."},"volume":338,"_id":"24298","title":"Integrated Planar Antenna Designs and Technologies for Millimeter-Wave Applications","department":[{"_id":"58"}],"author":[{"full_name":"Wang, Ruoyu","last_name":"Wang","first_name":"Ruoyu"}],"abstract":[{"text":"This thesis investigates the design and realization of integrated planar antennas for \r\nmillimeter-wave applications. The state-of-the-art antenna integration and packaging \r\ntechnologies are extensively studied, and an antenna design flow is proposed. \r\n \r\nA  number  of  integrated  antenna  designs  by  applying  different  integration  approaches  and \r\ntechnologies,  i.e.  on  printed  circuit  board  (PCB),  on-chip  and  in  Benzocyclobutene  (BCB) \r\nabove-wafer process, are presented. The designs target not only high performance, but also \r\nthe practical considerations of low-cost, feasibility, better reliability, and  good reproducibility. \r\nThey cover the industrial, medical, and scientific (ISM) bands of 60 GHz, 122 GHz, and 245 \r\nGHz  in  the  millimeter-wave  range  with  outstanding  performance  in  a  low-cost  fashion  by \r\napplying  innovative,  appropriate  integration  methods  and  sophisticated  design.  By  applying \r\nthe  localized  backside  etching  (LBE)  process  the  presented  on-chip  antennas  achieve \r\nmeasured peak gains of 6–8.4 dBi for above 100 GHz applications with simulated efficiencies \r\nof 54–75%. These figures are comparable to that of on-board or in-package antennas. To the \r\nbest of my knowledge, the achieved gain of 7.5–8.4 dBi in the band of 124–134 GHz for the \r\n130 GHz on-chip double folded dipole antenna is the highest reported result to date for planar \r\non-chip antennas based on low-resistivity silicon technologies. \r\n \r\nSystem  demonstrators  with  integrated  antennas  are  realized  and  measured.  The  60  GHz \r\ndemonstrator with on-PCB differential bunny-ear antenna and a novel bond-wire \r\ncompensation  scheme  achieves  a  data  rate  of  3.6  Gbit/s  over  a  15-meter  distance,  which \r\nwas  the  best  reported  analog  front-end  without  beamforming  function  in  silicon  technology \r\nregarding  both  the  data  rate  and  transmission  distance  at  the  time  of  its  publication.  A  245 \r\nGHz single-channel transmitter and a single-channel receiver with integrated on-chip \r\nantennas are also demonstrated. An effective isotropic radiated power (EIRP) of 7–8 dBm is \r\nachieved  for  the  transmitter,  which  is  the  highest  reported  value  at  245  GHz  for  a  SiGe \r\ntransmitter  with  a  single  antenna  so  far.  Furthermore,  the  receiver  has  the  highest  reported \r\nintegration level for any 245 GHz SiGe receiver. A 245 GHz 4-channel-transmitter array with \r\nintegrated  on-chip  antenna  array  is  also  realized  to  achieve  spatial  power  combining,  which \r\noffers 11 dB higher EIRP than a single-channel transmitter. \r\n \r\nFrom the presented results of the thesis it is feasible to realize high performance integrated \r\nplanar antennas in the entire millimeter-wave range and beyond in a cost-effective fashion. ","lang":"eng"}],"publisher":"Verlagsschriftenreihe des Heinz Nixdorf Instituts, Paderborn","year":"2015","status":"public","intvolume":"       338"}