Efficient and Wideband Load Modulated Power Amplifiers for Wireless Communication
Doctoral thesis, 2023

The increasing demand for mobile data traffic has resulted in new challenges and requirements for the development of the wireless communication infrastructure. With the transition to higher frequencies and multi-antenna systems, radio frequency (RF) hardware performance, especially the power amplifier (PA), becomes increasingly important. Enhancing PA energy efficiency and bandwidth is vital for maximizing channel capacity, reducing operational costs, and facilitating integration.

In the first part of the thesis, the bandwidth limitations of the standard two-way Doherty PA are discussed. A comprehensive analysis is provided, and the frequency responses of different Doherty combiner networks are presented. Furthermore, a Doherty combiner network is proposed, notable for its inherent broadband frequency and its capacity to account for the influence of output parasitics and packaged components from the active devices. The introduced Doherty combiner network is experimentally verified by a wideband gallium nitride (GaN) Doherty PA operating over 1.6-2.7 GHz.

In the second part of the thesis, an analytically based combiner synthesis approach for the three-stage Doherty PA is proposed and presented. A compact output combiner network, together with the input phase delays, is derived directly from transistor load-pull data and the PA design requirements. The technique opens up new design space for three-stage Doherty PAs with reconfigurable high-efficiency power back-off levels. The utility of the proposed technique is demonstrated by the implementation of a 30-W GaN three-stage Doherty PA prototype at 2.14 GHz. Measurements show that a drain efficiency of 68% and 55% is exhibited at 6- and 10-dB back-off power, respectively.

In the third part, a new PA architecture named the circulator load modulated amplifier (CLMA), is proposed. This architecture utilizes active load modulation for achieving enhanced back-off efficiency. Two active devices are incorporated in this innovative architecture, and a non-reciprocal circulator-based combiner is leveraged. Following this, the sequential CLMA (SCLMA) is introduced, characterized by its ability to enhance back-off efficiency without the necessity of load modulation. GaN demonstrator circuits for both CLMA and SCLMA architectures, whether with dual-input or RF single-input, are designed and fabricated, with excellent performance being measured. 

The thesis contributes novel design techniques and architectures to enhance PA efficiency and bandwidth. These findings pave the way for energy-efficient and adaptable RF transmitters in future wireless communication systems.

GaN

energy efficiency

load modulation

Combiner synthesis

RF

wideband

Doherty

power amplifier

CLMA

SCLMA

microwave

Kollektorn at MC2 department, Chalmers University of Technology
Opponent: Prof. Kenle Chen, University of Southern Florida, USA

Author

Han Zhou

Chalmers, Microtechnology and Nanoscience (MC2), Microwave Electronics

A Generic Theory for Design of Efficient Three-stage Doherty Power Amplifiers

IEEE Transactions on Microwave Theory and Techniques,;Vol. 70(2022)p. 1242-1253

Journal article

A Wideband and Highly Efficient Circulator Load Modulated Power Amplifier Architecture

IEEE Transactions on Circuits and Systems I: Regular Papers,;Vol. 70(2023)p. 3117 -3129

Journal article

Design of a Compact GaN Power Amplifier with High Efficiency and Beyond Decade Bandwidth

IEEE Microwave and Wireless Components Letters,;Vol. 32(2022)p. 1439-1442

Journal article

Wideband Sequential Circulator Load Modulated Amplifier with Back-off Efficiency Enhancement

2022 52nd European Microwave Conference, EuMC 2022,;(2022)p. 214-217

Paper in proceeding

Circulator Load Modulated Amplifier: A Non-Reciprocal Wideband and Efficient PA Architecture

IEEE MTT-S International Microwave Symposium Digest,;Vol. 2021-June(2021)p. 603-605

Paper in proceeding

H. Zhou, H. Chang, and C. Fager, Doherty Power Amplifier Combiner Network for Improved Bandwidth and Efficiency

H. Zhou, H. Chang, and C. Fager, Design and Analysis of a RF-input Doherty-like Circulator Load Modulated Amplifier

H. Zhou, H. Chang, and C. Fager, RF-input Sequential Circulator Load Modulated Amplifier with Extended Efficiency Range

Wireless communication has profoundly transformed our daily lives. Before this evolution, our interactions were limited by physical distances. Today, a simple click bridges immense gaps, making the world seem much smaller. The recent pandemic, an unexpected global challenge, reshaped our socio-economic dynamics. It disrupted established norms, redefining how individuals, communities, and nations interact and operate. Ever since the pandemic, many traditional physical activities transitioned to online platforms. Whether it was attending international conferences, engaging in academic workshops, or simply catching up with friends, the virtual realm became the new norm.

With the surge in mobile data traffic demand, evolving wireless communication infrastructure presents multiple challenges. At the heart of this evolution are microwave transmitters, foundational to any radio base station and link equipment. The power amplifier is their crucial component, amplifying signal power to guarantee required signal coverage. Importantly, power amplifiers are the primary energy consumers in radio base stations. Energy efficiency is therefore one of the most important properties of power amplifiers because it corresponds to a large part of the overall mobile network operational cost and environmental impact. 

The thesis contributes novel design techniques and architectures to enhance the efficiency and bandwidth of the power amplifier. These findings pave the way for energy-efficient and adaptable RF transmitters in future wireless communication systems.

Areas of Advance

Information and Communication Technology

Infrastructure

Kollberg Laboratory

Driving Forces

Sustainable development

Innovation and entrepreneurship

Subject Categories

Telecommunications

Communication Systems

Other Electrical Engineering, Electronic Engineering, Information Engineering

Roots

Basic sciences

Learning and teaching

Pedagogical work

ISBN

978-91-7905-941-5

Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5407

Publisher

Chalmers

Kollektorn at MC2 department, Chalmers University of Technology

Online

Opponent: Prof. Kenle Chen, University of Southern Florida, USA

More information

Latest update

1/13/2024