Saisai Jin scite author profile

Saisai Jin

2Publications

1Citation Statement Received

43Citation Statements Given

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A 28 GHz fully integrated GaN enhanced single‐sideband time‐modulated MMIC for phased array system

Cao

Guo

et al. 2023

Micro & Optical Tech Letters

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This paper presents a 28 GHz GaN enhanced single‐sideband time‐modulated phased array (ESTMPA), based on a monolithic microwave integrated circuit (MMIC), including both a time‐modulated circuit and an RF front‐end module (FEM). The time‐modulated circuit mainly consists of a numerically controlled attenuator to balance the amplitude, compact phase shifters to generate balanced signals, a reconfigurable power divider, and a quadrature power divider. The FEM mainly consists of a low noise amplifier and a power amplifier, featuring codesign of input/output networks. Based on the in‐phase/quadrature (I/Q) composite modulation technique, a stepped modulation waveform, realized by the time‐modulated circuit, is used to enable a weighted array of phases. This helps generate a scanned beam at the first positive sideband and eliminate the undesired sidebands. The final MMIC‐based four‐element ESTMPA shows a relative suppression level of −16 dB at the positive fifth sideband and −13 dB at the zeroth sideband, and a much higher level at the other undesired sidebands. As a result, a wider signal bandwidth and a higher harmonic efficiency are achieved. In addition, the ESTMPA shows a beam sweeping angle from −30° to 30° in far‐field measurement.

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A self-biased GaN LNA with 30 dB gain and 21 dBm P_1dB for 5G communications

Wang

Huang

Jin³

et al. 2022

Int. J. Microw. Wireless Technol.

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We present a self-biased three-stage GaN-based monolithic microwave integrated circuit low-noise amplifier (LNA) operating between 26 and 29 GHz for 5G mobile communications. The self-biasing circuit, common-source topology with inductive source feedback, and RLC negative feedback loops between gate and drain of the third transistor were implemented to achieve low noise, good port match, high stability, high gain, and compact size. Measurement results show that the LNA has a high and flat gain of 30.5 ± 0.4 dB with noise figure (NF) of 1.65–1.8 dB across the band. The three-stage topology also achieves high linearity, providing the 1 dB compression point output power (P1dB) of 21 dBm in the band. To our knowledge, this combination of NF, gain, and linearity performance represents the state of art of self-biased LNA in this frequency band.

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Saisai Jin

A 28 GHz fully integrated GaN enhanced single‐sideband time‐modulated MMIC for phased array system

A self-biased GaN LNA with 30 dB gain and 21 dBm P_1dB for 5G communications

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Saisai Jin

A 28 GHz fully integrated GaN enhanced single‐sideband time‐modulated MMIC for phased array system

A self-biased GaN LNA with 30 dB gain and 21 dBm P1dB for 5G communications

Contact Info

Product

Resources

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A self-biased GaN LNA with 30 dB gain and 21 dBm P_1dB for 5G communications