연구동향 분석
박사

Microwave tunable filters with switched varactor, and millimeter-wave CMOS phase shifter and true-time delay using all-pass network

정민재 2020년

논문상세정보
인용/피인용
' Microwave tunable filters with switched varactor, and millimeter-wave CMOS phase shifter and true-time delay using all-pass network' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • Emerging wireless communication system
  • all-passnetwork
  • beam forming
  • constant absolute bandwidth
  • delay compensation
  • full duplex radio
  • group-delay deviation
  • mm-wave
  • novel delay elements
  • spectrum sensing
  • switch-type phase shifter
  • switchable resonator
  • switched varactor
  • switched-line
  • tunable filter
  • tunable resonator
  • wide bandwidth
  • wide tuning range
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
149 0

0.0%

' Microwave tunable filters with switched varactor, and millimeter-wave CMOS phase shifter and true-time delay using all-pass network' 의 참고문헌

  • ¡°Varactor-loaded transmissionline phase shifter atC-band using lumped elements ,
    vol . 51 , no . 4 , pp . 1135 ? 1140 [2003]
  • ¡°Using intrinsic zero to notch satellite signals in UWB filter
    vol . 9 , no . 5 , pp . 1009 ? 1015 [2017]
  • ¡°Ultrawideband Filter Technologies
    vol . 11 , pp . 56 ? 68
  • ¡°Ultra-wideband bandpass filters with improved out-of-band behaviour via embedded electromagnetic-bandgap multimode resonators ,
    vol . 2 , no . 8 , pp . 854 ? 862 , [2008]
  • ¡°Ultra-wideband bandpass filters using broadside-coupled microstrip-coplanar waveguide ,
    vol . 5 , no . 7 , pp . 764 ? 770 [2011]
  • ¡°Ultra-wideband ( UWB ) bandpass filters using multiple-mode resonator
    vol . 15 , no . 11 , pp . 796 ? 798 , [2005]
  • ¡°Tunable bandpass filter with two adjustable transmission poles andCompensableCoupling
    vol . 62 , no . 9 , pp .
  • ¡°Tunable 4-pole noncontiguous 0.7-2.1-GHz bandpass filters based on dual zero-valueCouplings
    vol . 63 , no . 5 , pp . 1579 ? 1586 [2015]
  • ¡°Tunable 1.25-2.1-GHz 4-pole bandpass fil106ter with intrinsic transmission zero tuning
    vol . 63 , no . 5 , pp . 1569 ? 1578 [2015]
  • ¡°Synthesis applied 4th-orderConstant absolute bandwidth frequency-agile bandpass filter withCross-coupling ,
    vol . 6 , pp . 72287 ? 72294 [2018]
  • ¡°Realization of wirelessCommunicationCard based on UWB for industrial internet of things
    vol . 216 , pp . 360 ? 363 [2011]
  • ¡°Planar ultra-wideband bandpass filter using edgeCoupled microstrip lines and stepped impedance open stub
    vol . 17 , no . 9 , pp . 649 ? 651 [2007]
  • ¡°Parallel-coupled stub-loaded resonator bandpass filter with ultra-wideband passband on multilayer liquidCrystal polymer substrates ,
    vol . 8 , no . 8 , pp . 1183 ? 1186 [2016]
  • ¡°NovelCompact UWB Bandpass Filters Design WithCross-Coupling Between ¥ë/4 Short-Circuited Stubs ,
    vol . 24 , no . 1 , pp . 23 ? 25 , [2014]
  • ¡°Novel UWB bandpass filter using stub-loaded multiple-mode resonator
    vol . 23 , no . 8 , pp . 403 ? 405 , [2011]
  • ¡°Multilayer planar tunable filter with very wide tuning bandwidth ,
    vol . 59 , no . 11 , pp . 2864 ? 2871 [2011]
  • ¡°Millimeter-waveradar sensor based on a transceiver array for automotive applications
    vol . 56 , no . 2 , pp . 261 ? 269 [2008]
  • ¡°Microstrip switchable and fully tunable bandpass filter withContinuous frequency tuning range
    vol . 28 , no . 6 , pp . 500 ? 502 [2018]
  • ¡°Microstrip bandpass filter for ultra-wideband ( UWB ) wirelessCommunications , ¡± in IEEE/MTT-S international microwave symposium
    pp . 679 ? 682 [2005]
  • ¡°Lowloss highly linear integrated passive phase shifters for 5G front ends on bulkCMOS
    vol . 66 , no . 10 , pp . 4563 ? 4575 [2018]
  • ¡°Low-loss two-pole tunable filters with three different predefined bandwidthCharacteristics
    vol . 56 , no . 5 , pp . 1137 ? 1148
  • ¡°Ka-band inductor-shared SPnT DPnT switches and their applications to TTD phase shifter ,
    vol . 67 , no . 7 , pp . 2546 ? 2554 [2019]
  • ¡°High-Q 4-6-GHz suspended stripline RF MEMS tunable filter with bandwidthControl
    vol . 59 , no . 10 , pp . 2469 ? 2476 [2011]
  • ¡°Geometrical structures and fundamentalCharacteristics of microwave stepped-impedance resonators
    vol . 45 , no . 7 , pp . 1078 ? 1085 [1997]
  • ¡°FMCW MIMO radar system for frequency-division multiple TX-beamforming
    vol . 61 , no . 12 , pp . 4262 ? 4274 [2013]
  • ¡°Design and analysis of UWB bandpass filter with ring filter
    [2004]
  • ¡°CompactCascadable gm-C all-pass true time delayCell with reduced delay variation over frequency ,
    vol . 50 , no . 3 , pp . 693 ? 703 , [2015]
  • ¡°Compact tunable bandpass filter with wide tuning range ofCentre frequency and bandwidth using shortCoupled lines
    vol . 6 , pp . 2962 ? 2969 [2017]
  • ¡°Compact UWB bandpass filter using ring open stub loaded multiple-mode resonator ,
    vol . 45 , no . 11 , pp . 554 ? 556
  • ¡°Compact UWB Bandpass Filter Using Stub-Loaded Multiple-Mode Resonator
    vol . 17 , no . 1 , pp . 40 ? 42 , [2007]
  • ¡°Center frequency and bandwidthControllable microstrip bandpass filter design using loop-shaped dual-mode resonator
    vol . 61 , no . 10 , pp . 3590 ? 3600 [2013]
  • ¡°CMOS-based bi-directional T/RChipsets for phased array antenna
    pp . 1 ? 3 . [2012]
  • ¡°CMOS passive phase shifter with group-delay deviation of 6.3 ps at K-band
    vol . 59 , no . 7 , pp . 1778 ? 1786 [2011]
  • ¡°Broadband microstrip bandpass filters using triple-mode resonator
    vol . 4 , no . 9 , pp . 1275 ? 1282 [2010]
  • ¡°Application of electromagnetic bandgaps to the design of ultra-wide bandpass filters with good outof-band performance
    vol . 54 , no . 12 , pp . 4136 ? 4140 [2006]
  • ¡°Analysis of magneticallyCoupled all-pass network for phase-shifter design
    vol . 62 , no . 9 , pp . 2025 ? 2037 [2014]
  • ¡°An integrated ultra-wideband timed array receiver in 0.13 ¥ìmCMOS using a path-sharing true time delay architecture ,
    vol . 42 , no . 12 , pp . 2834 ? 2850 [2007]
  • ¡°An improved wideband all-pass I/Q network for millimeter-wave phase shifters ,
    vol . 60 , no . 11 , pp . 3431 ? 3439 [2012]
  • ¡°An X/Ku-band bi-directional true time delay T/RChipset in 0.13 ¥ìmCMOS technology ,
    pp . 1 ? 3 . [2014]
  • ¡°An UWB Bandpass Filter Based on a Novel Type of Multi-Mode Resonator
    vol . 22 , no . 10 , pp . 506 ? 508 [2012]
  • ¡°ACompact tunable bandpass filter using switchable varactor-tuned dual-mode resonator
    pp . 1374 ? 1377 [2018]
  • ¡°A widely tunableCompact bandpass filter based on a switched varactor-tuned resonator
    vol . 7 , pp . 95178 ? 95185 [2019]
  • ¡°A tunableCombline bandpass filter loaded with series resonator
    vol . 60 , no . 6 , pp . 1569 ? 1576 [2012]
  • ¡°A novelCompact ultra-wideband ( UWB ) bandpass filter with triple-notched bands , ¡± J. Electromagn .
    vol . 29 , no . 9 , pp . 1174 ? 1180 [2015]
  • ¡°A novel ultra-wideband ( UWB ) bandpass filter ( BPF ) with pairs of transmission zeros ,
    vol . 17 , no . 2 , pp . 121 ? 123 [2007]
  • ¡°A microstrip ultra-wideband bandpass filter withCascaded broadband bandpass and bandstop filters ,
    vol . 55 , no . 11 , pp . 2412 ? 2418 [2007]
  • ¡°A highly selective UWB bandpass filter using stepped impedance short and radial open stub
    vol . 10 , no . 4 , pp . 301 ? 307 [2017]
  • ¡°A fully packaged true time delay module for a K-band phased array antenna system demonstration
    vol . 14 , no . 8 , pp . 1175 ? 1177 [2002]
  • ¡°A Tunable dual-band bandpass-tobandstop filter using p-i-n diodes and varactors ,
    vol . 6 , pp . 46058 ? 46065 [2018]
  • ¡°A Low-Cost Scalable 32Element 28-GHz Phased Array Transceiver for 5GCommunication Links Based on a 2¡¿2 Beamformer Flip-Chip UnitCell
    vol . 53 , no . 5 , pp . 1260 ? 1274 [2018]
  • ¡°A Ka-band 3-bit RF MEMS true-time-delay network
    vol . 51 , no . 1 , pp . 305 ? 308 , [2003]
  • ¡°A High-performanceContinuously tunable MEMS bandpass filter at 1 GHz
    vol . 60 , no . 8 , pp . 2439 ? 2447 [2012]
  • ¡°A 15 ? 40 GHzCMOS true-time delayCircuit for UWB multi-antenna systems ,
    vol . 23 , no . 3 , pp . 149 ? 151 [2013]
  • ¡°A 10 ? 50 GHz true-time-delay phase shifter with max 3.9 delay variation ,
    pp . 83 ? 86 . [2014]
  • ¡°A 1 ? 20 GHz 400 ps true-time delay with small delay error in 0.13 ¥ìmCMOS for broadband phased array antennas
    pp . 1 ? 3 . [2015]
  • ¡°60GHz low-lossCompact phase shifters using a transformer-based hybrid in 65nmCMOS
    pp . 1 ? 4 , [2011]
  • ¡°60-GHz 5-bit phase shifter with integrated VGA phaseerrorCompensation ,
    vol . 61 , no . 3 , pp . 1224 ? 1235 [2013]
  • [8] P. Sepidband and K. Entesari, ¡°A CMOS wideband receiver resilient to out-of-band blockers using blocker detection and rejection,¡± IEEE Trans. Microw. Theory Tech., vol. 66, no. 5, pp. 2340?2355, Jan. 2018.
  • [78] D. M. Pozar, ¡°Microwave Engineering,¡± 4th ed., John Wiley, New Jersey, 2011.
  • [56] Q. Ma, D. Leenaerts, and P. M. Baltus, ¡®Silicon-based true-time-delay phased-array front-ends at Ka-Band,¡± IEEE Trans. Microw. Theory Tech., vol. 63, no. 9, pp. 2942?2952, Sep. 2015.
  • [54] M. H. Ghazizadeh, and A. Medi, ¡°A 125-ps 8?18-GHz CMOS integrated delay circuit,¡± IEEE Trans. Microw. Theory Tech., vol. 67, no. 1, pp. 162? 173, Jan. 2019.
  • [50] J. -C. Jeong, I. -B. Yom, J. -D. Kim, W. -Y. Lee, and C. -H. Lee, ¡°A 6?18-GHz GaAs multifuction chip with 8-bit true time delay and 7-bit amplitude control,¡± IEEE Trans. Microw. Theory Tech., vol. 66, no. 5, pp. 2220?2230, May. 2018.
  • [43] K. -J. Koh, and G. M. Rebeiz, ¡°0.13-¥ìm CMOS phase shifters for X-, Ku-, and K-band phased arrays,¡± IEEE J. Solid-State Circuits, vol. 42, no. 11, pp. 2535?2546, Nov. 2007.
  • [42] U. Kodak, and G. M. Rebeiz, ¡°A 5G 28-GHz common-leg T/R front-end in 45-nm CMOS SOI with 3.7-dB NF and ?30-dBc EVM with 64-QAM/500- MBaud modulation,¡± IEEE Trans. Microw. Theory Tech., vol. 67, no. 1, pp. 318?331, Jan. 2019.
  • [40] B. -W. Min and G. M. Rebeiz, ¡°Single-ended and differential ka-band BiCMOS phased array front-ends,¡± IEEE J. Solid-State Circuits, vol. 43, no. 10, pp. 2239?2250, Oct. 2008.
  • [3] D. Bharadia, E. McMilin, S. Katti, ¡°Full Duplex Radio,¡± in Proc. ACM SIGCOMMConf. SIGCOMM (SIGCOMM), pp. 375?386, Aug. 2013.
    pp . 375 ? 386 [2013]
  • [39] R. Grag, and A. S. Natarajan, ¡°A 28-GHz low-power phased-array receiver front-end with 360? RTPS phase shift range,¡± IEEE Trans. Microw. Theory Tech., vol. 65, no. 11, pp. 4703?4714, Nov. 2017.
  • [35] S. -Y. Kim and G. M. Rebeiz, ¡°A low-power BiCMOS 4-element phased array receiver for 76?84 GHz radars and communications systems,¡± IEEE Trans. Microw. Theory Tech., vol. 47, no. 2, pp. 359?367, Feb. 2012.
  • [34] B. Sadhu et al., ¡°A 28-GHz 32-element TRX phased-array IC with concurrent dual-polarized operation and orthogonal phase and gain control for 5G communications,¡± IEEE J. Solid-State Circuits, vol. 52, no. 12, pp. 3373?3391, Dec. 2017.
  • [32] J. -H. Tsai, F. -M. Lin, and H. Xiao ¡°Low RMS phase error 28 GHz 5-bit switch type phase shifter for 5G application,¡± Electron. Lett., vol. 54, no. 20, pp. 1184?1185, Oct. 2018.
  • [2] F. K. Jondral, ¡°Cognitive Radio: A Communications Engineering View,¡± IEEE Wireless Communications, vol. 14, no. 4, pp. 28?33, Aug. 2007.
  • [29] M. Hangai et al., ¡°S-and C-band ultra-compact phase shifters based on all-pass networks,¡± IEEE Trans. Microw. Theory Tech., vol. 58, no. 1, pp. 41?47, Jan. 2010.
  • [27] B.-W. Min and G. M. Rebeiz, ¡°Single-ended and differential ka-band BiCMOS phased array front-ends,¡± IEEE J. Solid-State Circuits, vol. 43, no. 10, pp. 2239?2250, Oct. 2008.
  • [26] B.-W. Min and G. M. Rebeiz, ¡°Ka-band low-loss and high-isolation switch design in 0.13-¥ìm CMOS,¡± IEEE Trans. Microw. Theory Tech., vol. 56, no. 6, pp. 1364?1371, Jun. 2008.
  • [24] A. C. Guyette, ¡°Intrinsically switched varactor-tuned filters and filter banks,¡± IEEE Trans. Microw. Theory Tech., vol. 60, no. 4, pp. 1044?1056, Apr. 2012.
  • [1] A. Puglielli et al., ¡°FDesign of energy- and cost-efficient massive MIMO array,¡± Proc. IEEE, vol. 104, no. 3, pp. 586?606, Mar. 2016.
  • [15] Y.-C. Chiou and G. M. Rebeiz, ¡°A tunable three-pole 1.5-2.2-GHz bandpass filter with bandwidth and transmission zero control,¡± IEEE Trans. Microw. Theory Tech., vol. 59, no. 11, pp. 2872?2878, Nov. 2011.
  • [12] M. El-Tanani and G. M. Rebeiz, ¡°Corrugated microstrip coupled lines for constant absolute bandwidth tunable filters,¡± IEEE Trans. Microw. Theory Tech., vol. 58, no. 4, pp. 956?963, Apr. 2010.
  • [11] F. Lin and M. Rais-Zadeh, ¡°Continuously tunable 0.55-1.9-GHz bandpass filter with a constant bandwidth using switchable varactor-tuned resonators,¡± IEEE Trans. Microw. Theory Tech., vol. 65, no. 3, pp. 792?803, Mar. 2017.
  • R. Jakoby and H. Maune , ¡°Performance analysis of reconfigurable bandpass filters withContinuously tunableCenter frequency and bandwidth
    vol . 65 , no . 11 , pp . 4572 ? 4583 [2017]
  • 1.7 ns truetime-delay element using a variable-order all-pass filter architecture in 0.13 ¥ìm CMOS
    vol . 52 , no . 8 , pp . 2180 ? 2193 [2017]