[1] JANUSZ G,BERND H,ULLRICH R P. Solid-state terahertz superresolution imaging device in 130-nm SiGe BiCMOS technology[J]. IEEE Transactions on Microwave Theory and Techniques, 2017,65(11):4357–4372.
JANUSZ G,BERND H,ULLRICH R P. Solid-state terahertz superresolution imaging device in 130-nm SiGe BiCMOS technology[J]. IEEE Transactions on Microwave Theory and Techniques, 2017,65(11):4357–4372.
[2] AL-IBADI A,CASSAR Q,ZIMMER T,et al. THz spectroscopy and imaging for breast cancer detection in the 300–500 GHz range[C]// 42nd International Conference on Infrared,Millimeter,and Terahertz Waves(IRMMW-THz). Cancun,Mexico: [s.n.], 2017:1.
AL-IBADI A,CASSAR Q,ZIMMER T,et al. THz spectroscopy and imaging for breast cancer detection in the 300–500 GHz range[C]// 42nd International Conference on Infrared,Millimeter,and Terahertz Waves(IRMMW-THz). Cancun,Mexico: [s.n.], 2017:1.
[3] GRZYB J,STATNIKOV K,SARMAH N,et al. 3-D high-resolution imaging at 240 GHz with a single-chip FMCW monostatic radar in SiGe HBT technology[C]// 41st International Conference on Infrared,Millimeter, and Terahertz waves (IRMMW-THz). Copenhagen,Denmark:[s.n.], 2016:1-2.
GRZYB J,STATNIKOV K,SARMAH N,et al. 3-D high-resolution imaging at 240 GHz with a single-chip FMCW monostatic radar in SiGe HBT technology[C]// 41st International Conference on Infrared,Millimeter, and Terahertz waves (IRMMW-THz). Copenhagen,Denmark:[s.n.], 2016:1-2.
[4] WEIDE D W,MURAKOWSKI J,KEILMANN F. Gas-absorption spectroscopy with electronic terahertz techniques[J]. IEEE Transactions on Microwave Theory & Techniques, 2000,48(4):740–743.
WEIDE D W,MURAKOWSKI J,KEILMANN F. Gas-absorption spectroscopy with electronic terahertz techniques[J]. IEEE Transactions on Microwave Theory & Techniques, 2000,48(4):740–743.
[5] NICK R,KLAUS S,JOHANNES B,et al. Towards breath gas detection with a 245 GHz gas sensor based on SiGe BiCMOS technology[C]// IEEE SENSORS. Glasgow,UK:IEEE, 2017:1-3.
NICK R,KLAUS S,JOHANNES B,et al. Towards breath gas detection with a 245 GHz gas sensor based on SiGe BiCMOS technology[C]// IEEE SENSORS. Glasgow,UK:IEEE, 2017:1-3.
[6] KLAUS S,JOHANNES B,PHILIPP N,et al. Gas spectroscopy system at 245 and 500 GHz using transmitters and receivers in SiGe BiCMOS[C]// 2016 Global Symposium on Millimeter Waves(GSMM) & ESA Workshop on Millimetre-Wave Technology and Applications. Espoo,Finland:[s.n.], 2016:1-4.
KLAUS S,JOHANNES B,PHILIPP N,et al. Gas spectroscopy system at 245 and 500 GHz using transmitters and receivers in SiGe BiCMOS[C]// 2016 Global Symposium on Millimeter Waves(GSMM) & ESA Workshop on Millimetre-Wave Technology and Applications. Espoo,Finland:[s.n.], 2016:1-4.
[7] KATSUHIRO A,YUKO U. THz chemical imaging for biological applications[J]. IEEE Transactions on Terahertz Science and Technology, 2011,1(1):293-300.
KATSUHIRO A,YUKO U. THz chemical imaging for biological applications[J]. IEEE Transactions on Terahertz Science and Technology, 2011,1(1):293-300.
[8] KEMP M C. Explosives detection by terahertz spectroscopy—a bridge too far?[J]. IEEE Transactions on Terahertz Science & Technology, 2011,1(1):282–292.
KEMP M C. Explosives detection by terahertz spectroscopy—a bridge too far?[J]. IEEE Transactions on Terahertz Science & Technology, 2011,1(1):282–292.
[9] HIROSHI H,TOSHIHIKO K,SONG H J,et al. 300-GHz band 20-Gbps ASK transmitter module based on InP-HEMT MMICs[C]// 2015 IEEE Compound Semiconductor Integrated Circuit Symposium(CSICS). New Orleans,USA:IEEE, 2015:1-4.
HIROSHI H,TOSHIHIKO K,SONG H J,et al. 300-GHz band 20-Gbps ASK transmitter module based on InP-HEMT MMICs[C]// 2015 IEEE Compound Semiconductor Integrated Circuit Symposium(CSICS). New Orleans,USA:IEEE, 2015:1-4.
[10] TAKURO T,SONG H J,MAAKOTO Y. Compact THz LTCC receiver modules for 300 GHz wireless communications[J]. IEEE Microwave and Wireless Components Letters, 2016,26(4):291-293.
TAKURO T,SONG H J,MAAKOTO Y. Compact THz LTCC receiver modules for 300 GHz wireless communications[J]. IEEE Microwave and Wireless Components Letters, 2016,26(4):291-293.
[11] KOSUKE K,KYOYA T,SHUHEI A,et al. CMOS 300-GHz 64-QAM transmitter[C]// 2016 IEEE MTT-S International Microwave Symposium(IMS). San Francisco,USA:IEEE, 2016:1-4.
KOSUKE K,KYOYA T,SHUHEI A,et al. CMOS 300-GHz 64-QAM transmitter[C]// 2016 IEEE MTT-S International Microwave Symposium(IMS). San Francisco,USA:IEEE, 2016:1-4.
[12] MAO Y,SCHMALZ K,BORNGRABER J,et al. 245 GHz subharmonic receiver in SiGe[C]// IEEE MTT-S International Microwave Symposium Digest(MTT). Seattle,WA,USA:IEEE, 2013:1-4.
MAO Y,SCHMALZ K,BORNGRABER J,et al. 245 GHz subharmonic receiver in SiGe[C]// IEEE MTT-S International Microwave Symposium Digest(MTT). Seattle,WA,USA:IEEE, 2013:1-4.
[13] MAO Y,SCHMALZ K,BORNGRABER J,et al. 245-GHz LNA, mixer, and subharmonic receiver in SiGe technology[J]. IEEE Transactions on Microwave Theory and Techniques, 2012,60(12):3823-3833.
MAO Y,SCHMALZ K,BORNGRABER J,et al. 245-GHz LNA, mixer, and subharmonic receiver in SiGe technology[J]. IEEE Transactions on Microwave Theory and Techniques, 2012,60(12):3823-3833.
[14] SCHMALZ K,BORNGRABER J,WANG R,et al. Subharmonic 245 GHz SiGe receiver with antenna[C]// European Microwave Integrated Circuit Conference. Nuremberg,Germany:IEEE, 2013:121-124.
SCHMALZ K,BORNGRABER J,WANG R,et al. Subharmonic 245 GHz SiGe receiver with antenna[C]// European Microwave Integrated Circuit Conference. Nuremberg,Germany:IEEE, 2013:121-124.
[15] SCHMALZ K,WANG R,MAO Y,et al. 245 GHz SiGe sensor system for gas spectroscopy[C]// IEEE SENSORS. Glasgow, UK:IEEE, 2017:1-3.
SCHMALZ K,WANG R,MAO Y,et al. 245 GHz SiGe sensor system for gas spectroscopy[C]// IEEE SENSORS. Glasgow, UK:IEEE, 2017:1-3.
[16] .JEFORS E,HEINEMANN B,PFEIFFER U R. A 220 GHz subharmonic receiver front end in a SiGe HBT technology[C]// IEEE RFIC. Baltimore,MD,USA:IEEE, 2011:1-4.
.JEFORS E,HEINEMANN B,PFEIFFER U R. A 220 GHz subharmonic receiver front end in a SiGe HBT technology[C]// IEEE RFIC. Baltimore,MD,USA:IEEE, 2011:1-4.
[17] EISSAA M H,AWNY A,KO M,et al. A 220-275 GHz direct conversion receiver in 130 nm SiGe:C BiCMOS technology[J]. IEEE Microwave Component and Wireless Components Letters, 2017,27(7):675-677.
EISSAA M H,AWNY A,KO M,et al. A 220-275 GHz direct conversion receiver in 130 nm SiGe:C BiCMOS technology[J]. IEEE Microwave Component and Wireless Components Letters, 2017,27(7):675-677.
[18] VAZQUEZ P R,GRZYB J,SARMAH N,et al. A 219-266 GHz fully-integrated direct conversion IQ receiver module in a SiGe HBT technology[C]// IEEE EUMA. Nuremberg,Germany:IEEE, 2017:261-264.
VAZQUEZ P R,GRZYB J,SARMAH N,et al. A 219-266 GHz fully-integrated direct conversion IQ receiver module in a SiGe HBT technology[C]// IEEE EUMA. Nuremberg,Germany:IEEE, 2017:261-264.
[19] SARMAH N,GRZYB J,STATNIKOV K,et al. A fully integrated 240 GHz direct conversion quadrature transmitter and receiver chipset in SiGe technology[J]. IEEE Transactions on Microwave Theory and Techniques, 2016,64(2):562-574.
SARMAH N,GRZYB J,STATNIKOV K,et al. A fully integrated 240 GHz direct conversion quadrature transmitter and receiver chipset in SiGe technology[J]. IEEE Transactions on Microwave Theory and Techniques, 2016,64(2):562-574.
[20] NICK R,SCHMALZ K,BORNGRABER J,et al. Towards breath gas detection with a 245 GHz gas sensor based on SiGe BiCMOS technology[C]// IEEE Microwave Component and Wireless Components Letters, 2017,27(7):675-677.
NICK R,SCHMALZ K,BORNGRABER J,et al. Towards breath gas detection with a 245 GHz gas sensor based on SiGe BiCMOS technology[C]// IEEE Microwave Component and Wireless Components Letters, 2017,27(7):675-677.