Experimental analysis of different measurement techniques for characterization of millimeter‐wave mixers

Maestrojuán, I.; Rea, Simon; Ederra, I.; Gonzalo, R.

doi:10.1002/mop.28364

Cited by 11 publications

(7 citation statements)

References 12 publications

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“…The DSB noise temperature and conversion gain of the receiver (including the SHM and IF chain) can be calculated through Y-factor measurement. Since the noise figure and gain of the IF chain were already known, the DSB noise temperature and conversion loss could be extracted according to methods detailed in [36]. Eventually, the measured performances of the SHM.…”

Section: 34 Thz Mixers' Performancesmentioning

confidence: 99%

Development of 340-GHz Transceiver Front End Based on GaAs Monolithic Integration Technology for THz Active Imaging Array

et al. 2020

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Frequency multipliers and mixers based on Schottky barrier diodes (SBDs) are widely used in terahertz (THz) imaging applications. However, they still face obstacles, such as poor performance consistency caused by discrete flip-chip diodes, as well as low efficiency and large receiving noise temperature. It is very hard to meet the requirement of multiple channels in THz imaging array. In order to solve this problem, 12-μm-thick gallium arsenide (GaAs) monolithic integrated technology was adopted. In the process, the diode chip shared the same GaAs substrate with the transmission line, and the diode’s pads were seamlessly connected to the transmission line without using silver glue. A three-dimensional (3D) electromagnetic (EM) model of the diode chip was established in Ansys High Frequency Structure Simulator (HFSS) to accurately characterize the parasitic parameters. Based on the model, by quantitatively analyzing the influence of the surface channel width and the diode anode junction area on the best efficiency, the final parameters and dimensions of the diode were further optimized and determined. Finally, three 0.34 THz triplers and subharmonic mixers (SHMs) were manufactured, assembled, and measured for demonstration, all of which comprised a waveguide housing, a GaAs circuit integrated with diodes, and other external connectors. Experimental results show that all the triplers and SHMs had great performance consistency. Typically, when the input power was 100 mW, the output power of the THz tripler was greater than 1 mW in the frequency range of 324 GHz to 352 GHz, and a peak efficiency of 6.8% was achieved at 338 GHz. The THz SHM exhibited quite a low double sideband (DSB) noise temperature of 900~1500 K and a DSB conversion loss of 6.9~9 dB over the frequency range of 325~352 GHz. It is indicated that the GaAs monolithic integrated process, diodes modeling, and circuits simulation method in this paper provide an effective way to design THz frequency multiplier and mixer circuits.

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Section: 34 Thz Mixers' Performancesmentioning

confidence: 99%

Development of 340-GHz Transceiver Front End Based on GaAs Monolithic Integration Technology for THz Active Imaging Array

et al. 2020

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“…The RF power was calibrated with VDI's PM4 power meter, while the IF power was measured with spectrum analyzer (N9030A from Agilent). Meanwhile, the Y factor method and gain procedure introduced in Reference are applied to obtain the noise temperature of the mixer. In Figure , the measured DSB noise temperature and SSB conversion loss are presented together with the simulated results.…”

Section: Circuit Designmentioning

confidence: 99%

220 GHz wideband integrated receiver front end based on planar Schottky diodes

Yang

Zhang

Zhao

et al. 2020

Micro & Optical Tech Letters

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In this article, a 220 GHz wideband receiver front end is proposed, featuring a 220 GHz subharmonic mixer and a 110 GHz wideband tripler integrated in one single block. The 220 GHz subharmonic mixer and 110 GHz tripler are firstly developed separately with proper planar Schottky diodes. According to the simulated and experimental results, the direct combination of independent mixer and tripler will lead to deterioration of the front end's performances, especially for wideband receivers. This indicates the necessity of building matching network between the cascade circuits in wideband submillimeter receivers. To improve the integral performances of the receiver front end and reduce its size, the combination of the subharmonic mixer and the tripler was optimized with load‐pull techniques and realized in one block. Measured results reveal that the single sideband (SSB) conversion loss of the integrated receiver front end is 7.5‐11 dB from 185 to 250 GHz, while the double sideband (DSB) noise temperature is 750‐1600 K within this frequency range. The integrated front end features half size of the combination of independent modules and better performances. Good agreement between the simulated and measured results shows that the integration and optimization techniques can be applied to realize compact terahertz systems in the future.

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“…The SHM's noise performance is characterized using the standard Y-factor measurement routine at RAL [20]. The test setup is shown in Fig.…”

Section: Schottky Diode Subharmonic Mixer At 220 Ghzmentioning

confidence: 99%

“…The IF output is amplified by the IF chain before power detected by the spectrum analyzer. The double side band (DSB) noise temperature and DSB conversion loss can therefore be extracted from the Y-factor measurements [20], which are plotted in Fig. 4.…”

Section: Schottky Diode Subharmonic Mixer At 220 Ghzmentioning

confidence: 99%

220 GHz outdoor wireless communication system based on a Schottky-diode transceiver

Chen

Zhang

et al. 2016

IEICE Electron. Express

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In this paper, an all-electronic outdoor wireless communication system based on a Schottky-diode transceiver at 220 GHz is reported. The transceiver is implemented by the use of in-house designed 220 GHz lownoise Schottky diode-based subharmonic mixers (SHMs), which simplifies the system setup and demonstrates the feasibility of Schottky technology for terahertz (THz) communication. The system setup, performance of critical components and link budget calculation are presented. The wireless link quality is evaluated in terms of the error vector magnitude (EVM). 3.52 Gbit/s real-time three-dimension (3D) glass-free video transmission is achieved over an outdoor distance of 200 m by the use of quadrature phase shift keying (QPSK) modulation.

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Experimental analysis of different measurement techniques for characterization of millimeter‐wave mixers

Cited by 11 publications

References 12 publications

Development of 340-GHz Transceiver Front End Based on GaAs Monolithic Integration Technology for THz Active Imaging Array

Development of 340-GHz Transceiver Front End Based on GaAs Monolithic Integration Technology for THz Active Imaging Array

220 GHz wideband integrated receiver front end based on planar Schottky diodes

220 GHz outdoor wireless communication system based on a Schottky-diode transceiver

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