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Publication search results
found 29 matches
- 2023
- Juan Muñoz, David Mancipe, Herman Fernández, Lorenzo Rubio, Vicent M. Rodrigo-Peñarrocha, Juan Reig:
Path Loss Characterization in an Outdoor Corridor Environment for IoT-5G in a Smart Campus University at 850 MHz and 3.5 GHz Frequency Bands. Sensors 23(22): 9237 (2023) - Alexander Pastukh, Valery Tikhvinskiy, Evgeny Devyatkin, Artyom Kostin:
Interference Analysis of 5G NR Base Stations to Fixed Satellite Service Bent-Pipe Transponders in the 6425-7125 MHz Frequency Band. Sensors 23(1): 172 (2023) - Angxiao Yan, Wei Deng, Haikun Jia, Shiyan Sun, Chao Tang, Bufan Zhu, Yu Fu, Hongzhuo Liu, Baoyong Chi:
An 11.4-to-16.4GHz FMCW Digital PLL with Cycle-slipping Compensation and Back-tracking DPD Achieving 0.034% RMS Frequency Error under 3.4-GHz Chirp Bandwidth and 960-MHz/μs Chirp Slope. VLSI Technology and Circuits 2023: 1-2 - 2022
- Zhengkun Shen, Haoyun Jiang, Fan Yang, Yixiao Wang, Zherui Zhang, Junhua Liu, Huailin Liao:
A 24 GHz Self-Calibrated All-Digital FMCW Synthesizer With 0.01% RMS Frequency Error Under 3.2 GHz Chirp Bandwidth and 320 MHz/µs Chirp Slope. IEEE J. Solid State Circuits 57(7): 2167-2180 (2022) - Alexander Pastukh, Valery Tikhvinskiy, Evgeny Devyatkin:
Compatibility Analysis Between 5G NR and Ultra-Wideband Devices in the 6425-7125 MHz Frequency Band. NEW2AN 2022: 506-516 - Masayuki Makino, Yuta Kaihori, Tsuyoshi Konishi:
Timing jitter suppression below 100 fs in photonic frequency band migration from MHz to GHz for Millimeter-wave Band Arbitrary Waveform Generation. OECC/PSC 2022: 1-3 - 2021
- Takaaki Yoshioka, Kenji Harauchi, Takumi Sugitani, Hiroaki Maehara, Takashi Yamasaki, Hiroaki Ichinohe, Miyo Miyashita, Kazuya Yamamoto, Seiki Goto:
Ku-Band 70-/30-W-Class Internally Matched GaN Power Amplifiers With Low IMD3 Over a Wide Offset Frequency Range of Up To 400 MHz. IEEE J. Solid State Circuits 56(9): 2635-2646 (2021) - Xiaoke Tang, Xu Zhao, Ang Hu, Dongsheng Liu, Zirui Jin:
A 433/2400 MHz dual-band frequency synthesizer with glitch-free phase-interpolated frequency divider and hybrid post-synthesizer. Microelectron. J. 116: 105158 (2021) - Boyi Zheng, Lu Jie, Michael P. Flynn:
TaNS-DDRF: A 160-MHz Bandwidth 6-GHz Carrier Frequency Digital-Direct RF Transmitter for Wi-Fi 6E with Targeted Noise-Shaping. ESSCIRC 2021: 511-514 - 2020
- Pratap Tumkur Renukaswamy, Nereo Markulic, Piet Wambacq, Jan Craninckx:
A 12-mW 10-GHz FMCW PLL Based on an Integrating DAC With 28-kHz RMS-Frequency-Error for 23-MHz/μs Slope and 1.2-GHz Chirp-Bandwidth. IEEE J. Solid State Circuits 55(12): 3294-3307 (2020) - Manmeet Singh, Ayman A. Fayed:
A 2-A 6-MHz Hysteretic Buck Converter with an 8-Bit Digital Jitter-Insensitive Frequency Correction Loop using Dual-Sided Hysteretic Band Modulation. MWSCAS 2020: 754-757 - 2019
- Aisah, Rudy Yuwono, Fabian Adna Suryanto:
Rectenna Design of GSM Frequency Band 900 MHz for Electromagnetic Energy Harvesting. J. Commun. 14(4): 281-286 (2019) - Yu Wu, Dai Jiang, Andy Bardill, Richard H. Bayford, Andreas Demosthenous:
A 122 fps, 1 MHz Bandwidth Multi-Frequency Wearable EIT Belt Featuring Novel Active Electrode Architecture for Neonatal Thorax Vital Sign Monitoring. IEEE Trans. Biomed. Circuits Syst. 13(5): 927-937 (2019) - Nei Kato, Yoshihiro Kamisawa, Akifumi Kitashima, Yuichi Kawamoto, Akira Aneha, Yuichi Yaguchi, Ryu Miura, Hideki Nakamura, Michihiro Kobayashi, Toshihiko Henmi, Osamu Akimoto:
Location Awareness System for Drones Flying Beyond Visual Line of Sight Exploiting the 400 MHz Frequency Band. IEEE Wirel. Commun. 26(6): 149-155 (2019) - Robin Benarrouch, Arno Thielens, Andreia Cathelin, Antoine Frappé, Andreas Kaiser, Jan M. Rabaey:
Capacitive Body-Coupled Communication in the 400-500 MHz Frequency Band. BODYNETS 2019: 218-235 - Carolina Miozzi, Giovanni Saggio, Emanuele Gruppioni, Gaetano Marrocco:
Performance Comparison of Patch and Loop Antennas for the Wireless Power Transfer and Transcutaneous Telemetry in the 860-960 MHz Frequency Band. BSN 2019: 1-4 - 2018
- Wang Zhengchen, Wu Zhaobo, Xinghua Wang:
A -86.88 dBc/Hz @1 MHz K-band fractional-N frequency synthesizer in 90-nm CMOS technology. IEICE Electron. Express 15(2): 20171063 (2018) - Yanli Wang, Wei Ke, Jun Lu, Haoran Zuo, Mengling Chen, Jie Jin:
A Non-Invasive Respiration Rate Monitoring Method Using 915 MHz Frequency Band. CISP-BMEI 2018: 1-6 - 2017
- Ruben Martinez-Sandoval, Antonio-Javier García-Sánchez, Felipe García-Sánchez, Joan García-Haro:
Evaluating the More Suitable ISM Frequency Band for IoT-Based Smart Grids: A Quantitative Study of 915 MHz vs. 2400 MHz. Sensors 17(1): 76 (2017) - Jessica Acevedo Flores, Daniel Robalo, Fernando J. Velez:
Transmitted Power Formulation for the Optimization of Spectrum Aggregation in LTE-A over 800 MHz and 2 GHz Frequency Bands. Wirel. Pers. Commun. 93(3): 833-852 (2017) - 2016
- Mumtaz Yilmaz, Damla Gurkan Kuntalp, Akan Fidan:
Determination of spectrum utilization profiles for 30 MHz-3 GHz frequency band. COMM 2016: 499-502 - Abhishek Srivastava, Nithin Sankar, K. K. Rakesh, Baibhab Chatterjee, Devarshi Das, Maryam Shojaei Baghini:
Design and measurement techniques for a low noise amplifier in a receiver chain for MedRadio spectrum of 401-406 MHz frequency band. VDAT 2016: 1-6 - 2015
- Kalaivani Ramanathan, N. J. R. Muniraj:
DWT-IDWT-based MB-OFDM UWB with digital down converter and digital up converter for power line communication in the frequency band of 50 to 578 MHz. Ann. des Télécommunications 70(5-6): 181-196 (2015) - 2013
- Philip M. Chopp, Anas A. Hamoui:
A 1-V 13-mW Single-Path Frequency-Translating ΔΣ Modulator With 55-dB SNDR and 4-MHz Bandwidth at 225 MHz. IEEE J. Solid State Circuits 48(2): 473-486 (2013) - Jessica Acevedo Flores, Daniel Robalo, Fernando J. Velez:
Transmitted power formulation for the implementation of spectrum aggregation in LTE-A over 800 MHz and 2 GHz frequency bands. WPMC 2013: 1-5 - 2012
- Roger Oliva, Elena Daganzo-Eusebio, Yann H. Kerr, Susanne Mecklenburg, Sara Nieto, Philippe Richaume, Claire Gruhier:
SMOS Radio Frequency Interference Scenario: Status and Actions Taken to Improve the RFI Environment in the 1400-1427-MHz Passive Band. IEEE Trans. Geosci. Remote. Sens. 50(5-1): 1427-1439 (2012) - Mehmet Unlu, H. Mopidevi, A. Zohur, Bedri A. Cetiner:
Frequency reconfigurable, 220-5000 MHz, five-band RF MEMS PIFA. MWSCAS 2012: 65-68 - 2011
- Kenji Suzuki, Mamoru Ugajin, Mitsuru Harada:
A 1-Mbps 1.6-µA Active-RFID CMOS LSI for the 300-MHz Frequency Band with an All-Digital RF Transmitting Scheme. IEICE Trans. Electron. 94-C(6): 1084-1090 (2011) - 2007
- Himanshu Arora, Nikolaus Klemmer, Patrick D. Wolf:
A 900 MHz ISM band mash-12 fractional-n frequency synthesizer for 5-Mbps data transmission. ACM Great Lakes Symposium on VLSI 2007: 381-386
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