Highly efficient linear CMOS power amplifiers for wireless communications

Jeon, Ham Hee

20 February 2012

The rapidly expanding wireless market requires low cost, high integration and high performance of wireless communication systems. CMOS technology provides benefits of cost effectiveness and higher levels of integration. However, the design of highly efficient linear CMOS power amplifier that meets the requirement of advanced communication standards is a challenging task because of the inherent difficulties in CMOS technology. The objective of this research is to realize PAs for wireless communication systems that overcoming the drawbacks of CMOS process, and to develop design approaches that satisfying the demands of the industry. In this dissertation, a cascode bias technique is proposed for improving linearity and reliability of the multi-stage cascode CMOS PA. In addition, to achieve load variation immunity characteristic and to enhance matching and stability, a fully-integrated balanced PA is implemented in a 0.18-m CMOS process. A triple-mode balanced PA using switched quadrature coupler is also proposed, and this work saved a large amount of quiescent current and further improved the efficiency in the back-off power. For the low losses and a high quality factor of passive output combining, a transformer-based quadrature coupler was implemented using integrated passive device (IPD) process. Various practical approaches for linear CMOS PA are suggested with the verified results, and they demonstrate the potential PA design approach for WCDMA applications using a standard CMOS technology.

Power amplifier

Quadrature coupler

Switch

Efficiency

Load immunity

IPD

CMOS

Cascode

Balanced topology

AM-PM

Reliability

Linearity

Multi-mode

Feedback

WCDMA

Amplifiers (Electronics)

Power amplifiers

Wireless communication systems

Semiconductors

Conception et caractérisation de circuits intégrés en technologie BiCMOS SiGe pour application de télécommunication en bande X

Coustou, Anthony

21 December 2001

Les progrès de la technologie silicium germanium (SiGe) suscitent sa possible utilisation dans les applications à haute fréquence. Les travaux décrit dans ce mémoire visent à étudier les potentialités de cette technologie pour la réalisation de circuits intégrés monolithiques (MMIC) faibles bruit dans la bande de 10 GHz. Ce mémoire est articulé autour de trois chapitres. Le premier rappelle les contraintes auxquelles doit répondre un transistor bipolaire afin d'être utilisable dans les circuits RF millimétriques. La technologie qu'à développé STMicroelectronics pour ce domaine d'application est ensuite présentée. Enfin, le travail de caractérisation qui a été réalisé afin de valider le comportement des modèles que nous allons utiliser pour concevoir des circuits RF est présenté. Le second chapitre est consacré à la conception de circuits amplificateurs à faible bruit. La méthode de travail ainsi que les topologies de circuits sont présentées. Le résultat des caractérisations effectuées est ensuite présenté. Nous terminons en concluant au sujet des performances en terme de consommation, linéarité, gain et facteur de bruit des différents circuits. Le troisième chapitre aborde la conception de sources radiofréquence à faible bruit de phase. Les différentes topologies de circuits que nous avons étudiés sont présentées, ce qui nous a permis de mettre en évidence les topologies offrant les meilleures performances. Enfin, une technique basée sur le principe de dégénérescence de bruit, est également présentée. Ce travail nous a permis d'intégrer sur un circuit MMIC, autour d'un circuit oscillateur de type Colpitts, un dispositif réducteur de bruit. Les résultats théoriques de cette étude ont montré l'efficacité de cette méthode.

BiCMOS SiGe

BANDE X

LNA

OSCILLATEURS A FAIBLE BRUIT DE PHASE

AMPLIFICATEURS FAIBLES BRUIT

CASCODE

THB SiGe

ADAPTATION EN BRUIT

DEGENERESCENCE DE BRUIT

BRUIT EN 1/f

FACTEUR DE QUALITE

A SiGe BiCMOS LNA for mm-wave applications

Janse van Rensburg, Christo

01 February 2012

A 5 GHz continuous unlicensed bandwidth is available at millimeter-wave (mm-wave) frequencies around 60 GHz and offers the prospect for multi gigabit wireless applications. The inherent atmospheric attenuation at 60 GHz due to oxygen absorption makes the frequency range ideal for short distance communication networks. For these mm-wave wireless networks, the low noise amplifier (LNA) is a critical subsystem determining the receiver performance i.e., the noise figure (NF) and receiver sensitivity. It however proves challenging to realise high performance mm-wave LNAs in a silicon (Si) complementary metal-oxide semiconductor (CMOS) technology. The mm-wave passive devices, specifically on-chip inductors, experience high propagation loss due to the conductivity of the Si substrate at mm-wave frequencies, degrading the performance of the LNA and subsequently the performance of the receiver architecture. The research is aimed at realising a high performance mm-wave LNA in a Si BiCMOS technology. The focal points are firstly, the fundamental understanding of the various forms of losses passive inductors experience and the techniques to address these issues, and secondly, whether the performance of mm-wave passive inductors can be improved by means of geometry optimising. An associated hypothesis is formulated, where the research outcome results in a preferred passive inductor and formulates an optimised passive inductor for mm-wave applications. The performance of the mm-wave inductor is evaluated using the quality factor (Q-factor) as a figure of merit. An increased inductor Q-factor translates to improved LNA input and output matching performance and contributes to the lowering of the LNA NF. The passive inductors are designed and simulated in a 2.5D electromagnetic (EM) simulator. The electrical characteristics of the passive structures are exported to a SPICE netlist which is included in a circuit simulator to evaluate and investigate the LNA performance. Two LNAs are designed and prototyped using the 13μ-m SiGe BiCMOS process from IBM as part of the experimental process to validate the hypothesis. One LNA implements the preferred inductor structures as a benchmark, while the second LNA, identical to the first, replaces one inductor with the optimised inductor. Experimental verification allows complete characterization of the passive inductors and the performance of the LNAs to prove the hypothesis. According to the author's knowledge, the slow-wave coplanar waveguide (S-CPW) achieves a higher Q-factor than microstrip and coplanar waveguide (CPW) transmission lines at mm-wave frequencies implemented for the 130 nm SiGe BiCMOS technology node. In literature, specific S-CPW transmission line geometry parameters have previously been investigated, but this work optimises the signal-to-ground spacing of the S-CPW transmission lines without changing the characteristic impedance of the lines. Optimising the S-CPW transmission line for 60 GHz increases the Q-factor from 38 to 50 in simulation, a 32 % improvement, and from 8 to 10 in measurements. Furthermore, replacing only one inductor in the output matching network of the LNA with the higher Q-factor inductor, improves the input and output matching performance of the LNA, resulting in a 5 dB input and output reflection coefficient improvement. Although a 5 dB improvement in matching performance is obtained, the resultant noise and gain performance show no significant improvement. The single stage LNAs achieve a simulated gain and NF of 13 dB and 5.3 dB respectively, and dissipate 6 mW from the 1.5 V supply. The LNA focused to attain high gain and a low NF, trading off linearity and as a result obtained poor 1 dB compression of -21.7 dBm. The LNA results are not state of the art but are comparable to SiGe BiCMOS LNAs presented in literature, achieving similar gain, NF and power dissipation figures. / Dissertation (MEng)--University of Pretoria, 2012. / Electrical, Electronic and Computer Engineering / unrestricted

Slow-wave cpw (S-CPW)

Electromagnetic (EM) analysis

Transmission line

Coplanar waveguide (CPW)

Low-noise amplifier (LNA)

Bipolar cmos (BICMOS)

Millimeter-wave (mm-wave)

Silicon germanium (SIGE)

Cascode amplifier

Impedance matching network (IMN)

Heterojunction bipolar transistor (HBT)

Integrated circuit (IC)

UCTD