This paper reports for the first time a drain-pumped (DP) mixer using Gallium Nitride (GaN) HEMT technology. Specifically, it describes a method aimed to predict the optimum bias conditions for active DP-mixers, leading to high conversion gain (CG) and linearity, along with the efficient use of the local oscillator drive level. A mixer prototype was designed and fabricated according to the discussed design principles; it exhibited a CG and an input third-order intercept point (IIP3) of (Formula presented.) dB and (Formula presented.) dBm, respectively, with a local oscillator power level of 20 dBm at about (Formula presented.) GHz. In terms of gain and linearity, both figures exceed the documented limitations for the class of mixers considered in this work. To the authors’ best knowledge, this is the first DP mixer operating in the S-band. The prototype was also tested in a radar-like setup operating in the S-band frequency-modulated continuous-wave (FMCW) mode. Measurements carried out in the radar setup resulted in (Formula presented.) dB and (Formula presented.) dB of IF signal-to-noise-ratio (SNR) for the DP and the resistive mixers, respectively. For comparison purposes, a resistive mixer was designed and fabricated using the same GaN HEMT technology; a detailed comparison between the two topologies is discussed in the paper, thus further highlighting the capability of the DP-mixer for system applications.
A GaN-HEMT Active Drain-Pumped Mixer for S-Band FMCW Radar Front-End Applications / Pagnini L.; Collodi G.; Cidronali A.. - In: SENSORS. - ISSN 1424-8220. - ELETTRONICO. - 23:(2023), pp. 4479.4479-4479.4493. [10.3390/s23094479]
A GaN-HEMT Active Drain-Pumped Mixer for S-Band FMCW Radar Front-End Applications
Pagnini L.;Collodi G.;Cidronali A.
2023
Abstract
This paper reports for the first time a drain-pumped (DP) mixer using Gallium Nitride (GaN) HEMT technology. Specifically, it describes a method aimed to predict the optimum bias conditions for active DP-mixers, leading to high conversion gain (CG) and linearity, along with the efficient use of the local oscillator drive level. A mixer prototype was designed and fabricated according to the discussed design principles; it exhibited a CG and an input third-order intercept point (IIP3) of (Formula presented.) dB and (Formula presented.) dBm, respectively, with a local oscillator power level of 20 dBm at about (Formula presented.) GHz. In terms of gain and linearity, both figures exceed the documented limitations for the class of mixers considered in this work. To the authors’ best knowledge, this is the first DP mixer operating in the S-band. The prototype was also tested in a radar-like setup operating in the S-band frequency-modulated continuous-wave (FMCW) mode. Measurements carried out in the radar setup resulted in (Formula presented.) dB and (Formula presented.) dB of IF signal-to-noise-ratio (SNR) for the DP and the resistive mixers, respectively. For comparison purposes, a resistive mixer was designed and fabricated using the same GaN HEMT technology; a detailed comparison between the two topologies is discussed in the paper, thus further highlighting the capability of the DP-mixer for system applications.File | Dimensione | Formato | |
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