High Efficiency and Wide Bandwidth Quasi-Load Insensitive Class-E Operation Utilizing Package Integration

Qureshi, Abdul Raheem; Acar, Mustafa; Pires, Sergio; Vreede, L.C.N. de

doi:10.1109/tmtt.2018.2868876

Cited by 5 publications

(1 citation statement)

References 37 publications

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“…The total drain capacitance (C D , including the transistors and interconnect parasitics) is tuned for class-E operation at ACW M (ACW P ) = ACW M P,M ax . Therefore, when the main (peak) DPA is fully on, it operates in class-E. As the number of switching transistors in the main (peak) DPA decreases (at PBO), the fundamental impedances become complex with positive reactances, and the second harmonic impedances become mostly negative reactances (capacitive), thus operating similar to a class-J PA [43]- [45]. For small ACW M (ACW P ) ( < 30), the voltage swing on drain of the main (peak) DPA is small, therefore operating similar to a current source with an almost linear behavior [17].…”

Section: Digitally-controlled Class-e Doherty Pamentioning

confidence: 99%

A Highly Linear Wideband Polar Class-E CMOS Digital Doherty Power Amplifier

Hashemi

Zhou²,

Shen

et al. 2019

IEEE Trans. Microwave Theory Techn.

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This paper presents the first application of a digital-intensive intrinsically linear digitally-controlled class-E technique in a Doherty configuration. By careful nonlinear segmentation and multiphase RF-clocking along with overdrive-voltage control and automatic duty-cycle correction, it is shown that even the nonlinearities related to Doherty operation can be fully handled by the underlying design such that digital predistorion DPD can be in principle omitted. The nonlinearity behaviour of the whole digital Doherty PA is analyzed and closed-form equations are given to predict the AM-AM and AM-PM curves. In addition, time/phase mismatch between the Peak and Main branches and the AM and PM signals are accurately compensated. In order to achieve maximum intrinsic linearity, two separate chips with the same architecture, but different design parameters, are fabricated as the Main and Peak amplifiers in 40nm bulk CMOS. To achieve a large RF bandwidth and high passive combiner efficiency, a differential low-loss, wideband Marchand balun-based Doherty power combiner, implemented using re-entrant coupled lines with independent 2 nd harmonic control is proposed, and together with the matching network is fabricated on a two-layer PCB. The measured peak / 6 dB power-back-off P OUT , drain efficiency / power-added efficiency at 2.4 GHz are 17.5 / 12.2 dBm, 57 / 52 % and 36 / 25 % with VDD Main / Peak = 0.6 / 0.7 V. Measured results without using DPD show-41 dBc ACPR and-36 dB EVM for a 16 MHz OFDM signal at 2.5GHz. By using DPD, the measured ACPR and EVM of a 16 / 32 MHz OFDM signals are-52 /-48 dBc and-50 /-48 dB respectively.

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Section: Digitally-controlled Class-e Doherty Pamentioning

confidence: 99%

A Highly Linear Wideband Polar Class-E CMOS Digital Doherty Power Amplifier

Hashemi

Zhou²,

Shen

et al. 2019

IEEE Trans. Microwave Theory Techn.

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Analysis and Design of Outphasing Transmitter Using Class-E Power Amplifiers With Shunt Capacitances and Shunt Filters

et al. 2020

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In this paper, a novel outphasing power amplifier (PA) based on class-E amplifiers with shunt capacitances and shunt filters is proposed. The new design provides high drain efficiency for both peak and back-off power levels. A mathematical model for the class-E power amplifier with shunt capacitance and shunt filter is presented. The proposed model enables derivation of load circuit parameters that provide optimum drain efficiency for the peak and back-off power levels using closed form mathematical expressions. Based on this model, an outphasing power amplifier is designed and subsequently implemented using microstrip transmission lines and a GaN HEMT devices. The fabricated power amplifier prototype is optimized for 2.14 GHz and provides drain efficiency of over 60% for back-off power levels up to 8.5 dB. The amplifier demonstrates a 44.3% drain efficiency for 64QAM OFDM modulated signal with 20 MHz bandwidth. Adjacent channel leakage ratio (ACLR) of-39.5 dB and error vector magnitude (EVM) of 0.9 % were achieved after the application of a memory polynomial linearization algorithm.

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Continuous Quasi-Load Insensitive Class-E Mode for Wideband Doherty Power Amplifiers

Nghiem¹,

Gajadharsing²

2023

2023 IEEE/MTT-S International Microwave Symposium - IMS 2023

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High Efficiency and Wide Bandwidth Quasi-Load Insensitive Class-E Operation Utilizing Package Integration

Cited by 5 publications

References 37 publications

A Highly Linear Wideband Polar Class-E CMOS Digital Doherty Power Amplifier

A Highly Linear Wideband Polar Class-E CMOS Digital Doherty Power Amplifier

Analysis and Design of Outphasing Transmitter Using Class-E Power Amplifiers With Shunt Capacitances and Shunt Filters

Continuous Quasi-Load Insensitive Class-E Mode for Wideband Doherty Power Amplifiers

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