Design of Highly Linear Broadband Continuous Mode GaN MMIC Power Amplifiers for 5G

Nikandish, Gholamreza; Staszewski, Robert Bogdan; Zhu, Anding

doi:10.1109/access.2019.2914563

Cited by 31 publications

(32 citation statements)

References 27 publications

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“…Using (24), the required turn-on power level of the auxiliary sub PA can be derived. The input-output power characteristic of the unbalanced PA can be derived using ( 4), (22), and (23).…”

Section: B Back-off Efficiency Enhancementmentioning

confidence: 99%

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Unbalanced Power Amplifier: An Architecture for Broadband Back-Off Efficiency Enhancement

Nikandish

Staszewski

Zhu

2021

IEEE J. Solid-State Circuits

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In this article, we present a new broadband power amplifier (PA) architecture with a back-off efficiency enhancement which supports very wide modulation bandwidths. Named unbalanced PA, it is composed of two cooperating sub PAs using Lange couplers as input power splitter and output power combiner. The PA operation is controlled by the transistors' width ratio and coupling coefficients of the Lange couplers. The output power back-off (OPBO) level is given by the transistors' width ratio and coupling coefficient of the output coupler, while the maximum efficiency is achieved at the back-off point. These features provide more design flexibility compared to the conventional Doherty PA, where the OPBO can be set only by the transistors' width ratio and the maximum efficiency is achieved at the peak power. Using broadband harmonic matching networks, the main and auxiliary sub PAs operate in the continuous mode, to improve efficiency over a broad bandwidth. A fully integrated unbalanced PA, implemented in a 250-nm GaN-on-SiC process, achieves 32.2-34.3 dBm output power, 27-37% efficiency at peak power and 27-40% at 5-6-dB back-off, across 4.5-6.5 GHz. The PA provides 3.7/4.5% (−28.6/−26.9 dB) rms error vector magnitude (EVMrms) and 30% average efficiency for a 256-QAM signal with 100/200-MHz bandwidth, 7.2 dB PAPR and 25.5 dBm average output power, without using any predistortion.

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“…Using (24), the required turn-on power level of the auxiliary sub PA can be derived. The input-output power characteristic of the unbalanced PA can be derived using ( 4), (22), and (23).…”

Section: B Back-off Efficiency Enhancementmentioning

confidence: 99%

“…The gain of the unbalanced PA can be derived using the models developed for the output combiner (4), input splitter (20), (21), and sub PAs ( 22), (23). Specifically, the gain at output back-off and peak power, using ( 13), ( 14), (24), and (25), can be derived as…”

Section: B Back-off Efficiency Enhancementmentioning

confidence: 99%

Unbalanced Power Amplifier: An Architecture for Broadband Back-Off Efficiency Enhancement

Nikandish

Staszewski

Zhu

2021

IEEE J. Solid-State Circuits

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“…The purpose of phase linearizer is to ensure linearity specification is achieved across 700 to 800 MHz which encapsulates LTE Band 12,13,14,17,20,27,28,29,44,67,68 and 85 and 5G Band which is n28. As quantified in [53], an AM-PM distortion of 5 • or more results in gain compression degradation of 1 dB or more.…”

Section: Linearizer Circuit Designmentioning

confidence: 99%

A 0.8 mm² Sub-GHz GaAs HBT Power Amplifier for 5G Application Achieving 57.5% PAE and 28.5 dBm Maximum Linear Output Power

et al. 2019

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This paper presents a comprehensive design of a fully integrated multistage GaAs HBT power amplifier that achieves both linearity and high efficiency within a chip area of 0.855 mm 2 for 4G and 5G applications covering the lower frequency band of 700-800 MHz. A novel linearizer circuit is integrated to a dual stage class-AB PA to minimize the AM-PM (Amplitude Modulation-Phase Modulation) distortion generated by the parasitic capacitance at the PN-junction under low bias current condition. The linearized power amplifier is able to operate within a 100 MHz linear operating bandwidth (700-800 MHz) while meeting the adjacent channel leakage ratio (ACLR) specification for 4G and 5G application. The fully integrated PA achieves a wideband efficiency of 57.5% at 28.5 dBm output power. Observing a respective input and output return losses of less than 13 dB and 10 dB, the PA delivers a power gain within the range of 34.0-37.0 dB across the operating bandwidth while exhibiting an unconditional stability characteristic from DC up to 5 GHz. The proposed linearization method paves the way of reducing the complexity of linear and high efficiency PA design which is associated with complicated and high-power consumption linearization schemes.

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“…However, these process technologies suffer from low output power levels, low efficiency, and high crosstalk between channels as a result of lossy substrate. GaN monolithic microwave integrated circuit (MMIC) technology is an attractive solution for 5G systems, especially for basestation PAs [6], [7], [8], where it can provide high output power levels in a compact chip area. Furthermore, the lower losses of its SiC substrate help to reduce crosstalk in a multi-channel PA, which has been shown to have the most detrimental effect on the performance of MIMO systems [5].…”

Section: Introductionmentioning

confidence: 99%

A Fully Integrated GaN Dual-Channel Power Amplifier With Crosstalk Suppression for 5G Massive MIMO Transmitters

Nikandish

Staszewski

Zhu

2021

IEEE Trans. Circuits Syst. II

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We present a broadband dual-channel power amplifier (PA) with crosstalk suppression for multi-input multioutput (MIMO) communications. Operation of MIMO system with crosstalk is theoretically evaluated for two popular coding schemes including the space-time coding and linear precoding. Design challenges of a multi-channel PA on a single chip are investigated and circuit techniques, including second-harmonic trapping integrated into the output matching network and the use of back-via lines to isolate the channels, are proposed to mitigate the inter-channel crosstalk. A fully integrated dualchannel PA prototype, implemented using a 250-nm GaN-on-SiC process, provides 34.9-36.3 dBm output power, 44-49% poweradded efficiency (PAE), 11.3-12.3 dB power gain, 31.0-34.2 dB second-harmonic rejection, and −28.1 dB to −25.7 dB interchannel crosstalk across 4.5-6.5 GHz. For a 100-MHz 256-QAM signal with 7.2 dB peak-to-average power ratio (PAPR), the PA achieves 29.9 dBm average output power, 30% average PAE, −38.2/−39.1 dBc adjacent channel leakage ratio (ACLR), and −28.2 dB (3.9%) rms error vector magnitude (EVM), without using digital predistortion (DPD). Effect of crosstalk on linearity of the dual-channel PA is also measured and it is shown that for a 256-QAM signal EVM can increase by 3-8 dB, depending on relative power levels of the two channels.

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Design of Highly Linear Broadband Continuous Mode GaN MMIC Power Amplifiers for 5G

Cited by 31 publications

References 27 publications

Unbalanced Power Amplifier: An Architecture for Broadband Back-Off Efficiency Enhancement

Unbalanced Power Amplifier: An Architecture for Broadband Back-Off Efficiency Enhancement

A 0.8 mm² Sub-GHz GaAs HBT Power Amplifier for 5G Application Achieving 57.5% PAE and 28.5 dBm Maximum Linear Output Power

A Fully Integrated GaN Dual-Channel Power Amplifier With Crosstalk Suppression for 5G Massive MIMO Transmitters

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Design of Highly Linear Broadband Continuous Mode GaN MMIC Power Amplifiers for 5G

Cited by 31 publications

References 27 publications

Unbalanced Power Amplifier: An Architecture for Broadband Back-Off Efficiency Enhancement

Unbalanced Power Amplifier: An Architecture for Broadband Back-Off Efficiency Enhancement

A 0.8 mm2 Sub-GHz GaAs HBT Power Amplifier for 5G Application Achieving 57.5% PAE and 28.5 dBm Maximum Linear Output Power

A Fully Integrated GaN Dual-Channel Power Amplifier With Crosstalk Suppression for 5G Massive MIMO Transmitters

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Resources

About

A 0.8 mm² Sub-GHz GaAs HBT Power Amplifier for 5G Application Achieving 57.5% PAE and 28.5 dBm Maximum Linear Output Power