Wideband Watt-Level Spatial Power-Combined Power Amplifier in SiGe BiCMOS Technology for Efficient mm-Wave Array Transmitters
Doktorsavhandling, 2021
This work presents a non-conventional design approach for mm-Wave Si-based Watt-level power amplifiers that is based on novel power-combining architecture, where an array of parallel custom PA-cells suited on the same chip is interfaced to a single substrate integrated waveguide (to be a part of an antenna element). This allows one to directly excite TEm0 waveguide modes with high power through spatial power combining functionality, obviating the need for intermediate and potentially lossy on-chip power combiners. The proposed solution offers wide impedance bandwidth (50%) and low insertion losses (0.4 dB), which are virtually independent from the number of interfaced PA-cells. The work evaluates the scalability bounds of the architecture as well as discusses the critical effects of coupled non-identical PA-cells, which are efficiently reduced by employing on-chip isolation load resistors.
The proposed architecture has been demonstrated through an example of the combined PA with four differential cascode PA-cells suited on the same chip, which is flip-chip interconnected to the combiner placed on a laminate. This design is implemented in a 0.25 um SiGe BiCMOS technology. The PA-cell has a wideband performance (38.6%) with both high peak efficiency (30%) and high saturated output power (24.9 dBm), which is the highest reported output power level obtained without the use of circuit-level power combining in Si-based technologies at Ka-band. In order to achieve the optimal system-level performance of the combined PA, an EM-circuit-thermal optimization flow has been proposed, which accounts for various multiphysics effects occurring in the joint structure. The final PA achieves the peak PAE of 26.7% in combination with 30.8 dBm maximum saturated output power, which is the highest achievable output power in practical applications, where the 50-Ohms load is placed on a laminate. The high efficiency (>20%) and output power (>29.8 dBm) over a wide frequency range (30%) exceed the state-of-the-art in Si-based PAs.
integration
spatial power combining
substrate integrated waveguide
array amplifiers
RFIC
Författare
Artem Roev
Chalmers, Elektroteknik, Kommunikation, Antenner och Optiska Nätverk
Wide-Band Spatially Distributed TE10 Substrate Integrated Waveguide Transition for High-Power Generation at mm-Wave Frequencies
International Symposium on Antennas and Propagation (ISAP2017), Phuket, Thailand, 30 Oct. - 2 Nov., 2017,;(2017)
Paper i proceeding
Efficient Millimeter-Wave High Power Generation with Spatial Power-Combined Feeding Element
IET Conference Publications,;(2018)
Paper i proceeding
Wideband mm-Wave Transition Between a Coupled Microstrip Line Array and SIW for High-Power Generation MMICs
IEEE Microwave and Wireless Components Letters,;Vol. 28(2018)p. 867-869
Artikel i vetenskaplig tidskrift
N-way spatial power combining in SIW for high power generation MMICs-scalability bounds
2019 IEEE International Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting, APSURSI 2019 - Proceedings,;Vol. July 2019(2019)p. 1789-1790
Paper i proceeding
High power mm-wave spatial power combiner employing on-chip isolation resistors
14th European Conference on Antennas and Propagation, EuCAP 2020,;(2020)
Paper i proceeding
A Wideband and Low-Loss Spatial Power Combining Module for mm-Wave High-Power Amplifiers
IEEE Access,;Vol. 8(2020)p. 194858-194867
Artikel i vetenskaplig tidskrift
A Wideband mm-Wave Watt-Level Spatial Power-Combined Power Amplifier With 26% PAE in SiGe BiCMOS Technology
IEEE Transactions on Microwave Theory and Techniques,;Vol. In Press(2022)
Artikel i vetenskaplig tidskrift
A. Roev, R. Maaskant, M. Ivashina Transition Arrangement between an SIW Structure and a Transmission Line Arrangement
The evolution of wireless communications is driven by advances in radio hardware technologies, which need to offer us high-performance, energy-efficient, compact, and cost-effective solutions. The above targets are feasible at an individual metric level but are very challenging in combination. This thesis presents a non-conventional design approach for efficient and high-performance millimeter-wave power amplifiers (PAs), which are critical components of modern wireless systems. The focus of this work is on silicon-based technologies allowing a high level of integration at a reasonable cost but traditionally providing insufficient output power and energy efficiency limited by conventional power-combining approaches. The latter problems have been partly overcome by the proposed PA architecture based on a new efficient power-combining solution. This work evaluates the performance and scalability bounds of the architecture as well as presents its optimization flow for achieving optimal system-level performance by accounting for various multiphysics effects. Moreover, the proposed architecture has been demonstrated through an example of the combined PA implemented in an advanced high-speed SiGe process from NXP Semiconductors, which is one of the main industrial partners of this work. The developed PA has a wideband performance with both high efficiency and high output power, which outperforms the state-of-the-art silicon-based PAs.
I believe that the techniques and ideas proposed in this thesis will play an important role in sustainable wireless systems where high-performance, low energy consumption, and cost-efficiency are essential requirements.
Silicon-based Ka-band massive MIMO antenna systems for new telecommunication services (SILIKA)
Europeiska kommissionen (EU) (EC/H2020/721732), 2016-09-01 -- 2020-08-31.
Styrkeområden
Informations- och kommunikationsteknik
Drivkrafter
Hållbar utveckling
Innovation och entreprenörskap
Ämneskategorier
Telekommunikation
Kommunikationssystem
Annan elektroteknik och elektronik
Utgivare
Chalmers
Room 7430 Landahlsrummet, Hörsalsvägen 11
Opponent: Prof. Zoya Popovic, Department of Electrical, Computer and Energy Engineering, University of Colorado at Boulder, USA