Advances in Solid State Circuit Technologies

This book brings together contributions from experts in the fields to describe the current status of important topics in solid-state circuit technologies. It consists of 20 chapters which are grouped under the following categories: general information, circuits and devices, materials, and characterization techniques. These chapters have been written by renowned experts in the respective fields making this book valuable to the integrated circuits and materials science communities. It is intended for a diverse readership including electrical engineers and material scientists in the industry and academic institutions. Readers will be able to familiarize themselves with the latest technologies in the various fields

Design and characterization of monolithic millimeter-wave active and passive components, low-noise and power amplifiers, resistive mixers, and radio front-ends

This thesis focuses on the design and characterization of monolithic active and passive components, low-noise and power amplifiers, resistive mixers, and radio front-ends for millimeter-wave applications. The thesis consists of 11 publications and an overview of the research area, which also summarizes the main results of the work. In the design of millimeter-wave active and passive components the main focus is on realized CMOS components and techniques for pushing nanoscale CMOS circuits beyond 100 GHz. Test structures for measuring and analyzing these components are shown. Topologies for a coplanar waveguide, microstrip line, and slow-wave coplanar waveguide that are suitable for implementing transmission lines in nanoscale CMOS are presented. It is demonstrated that the proposed slow-wave coplanar waveguide improves the performance of the transistor-matching networks when compared to a conventional coplanar waveguide and the floating slow-wave shield reduces losses and simplifies modeling when extended below other passives, such as DC decoupling and RF short-circuiting capacitors. Furthermore, wideband spiral transmission line baluns in CMOS at millimeter-wave frequencies are demonstrated. The design of amplifiers and a wideband resistive mixer utilizing the developed components in 65-nm CMOS are shown. A 40-GHz amplifier achieved a +6-dBm 1-dB output compression point and a saturated output power of 9.6 dBm with a miniature chip size of 0.286 mm². The measured noise figure and gain of the 60-GHz amplifier were 5.6 dB and 11.5 dB, respectively. The V-band balanced resistive mixer achieved a 13.5-dB upconversion loss and 34-dB LO-to-RF isolation with a chip area of 0.47 mm². In downconversion, the measured conversion loss and 1-dB input compression point were 12.5 dB and +5 dBm, respectively. The design and experimental results of low-noise and power amplifiers are presented. Two wideband low-noise amplifiers were implemented in a 100-nm metamorphic high electron mobility transistor (HEMT) technology. The amplifiers achieved a 22.5-dB gain and a 3.3-dB noise figure at 94 GHz and a 18-19-dB gain and a 5.5-7.0-dB noise figure from 130 to 154 GHz. A 60-GHz power amplifier implemented in a 150-nm pseudomorphic HEMT technology exhibited a +17-dBm 1-dB output compression point with a 13.4-dB linear gain. In this thesis, the main system-level aspects of millimeter-wave transmitters and receivers are discussed and the experimental circuits of a 60-GHz transmitter front-end and a 60-GHz receiver with an on-chip analog-to-digital converter implemented in 65-nm CMOS are shown. The receiver exhibited a 7-dB noise figure, while the saturated output power of the transmitter front-end was +2 dBm. Furthermore, a wideband W-band transmitter front-end with an output power of +6.6 dBm suitable for both image-rejecting superheterodyne and direct-conversion transmission is demonstrated in 65-nm CMOS

Innovative Design and Realization of Microwave and Millimeter-Wave Integrated circuits

Ph.DDOCTOR OF PHILOSOPH

High Efficiency Class E Microwave Frequency Multipliers

A novel design methodology for the successful implementation of high efficiency class E frequency multipliers is presented in this work. An innovative class E configuration is proposed for a frequency tripler that provides an advantage over the conventional designs, by allowing a 50 %duty cycle drive with a realisable load for 100 %DC-to-RF efficiency operation. A novel quantitative analysis of class E networks is developed that aids in the rapid yet accurate assessment of circuit performance. The first-order analysis provides an intuitive evaluation of class E operation and harmonic content of the switch waveforms. The analysis is shown to be applicable to both class E amplifiers and multipliers, providing closed-form equations for an intelligent first design. The proposed class E tripler configuration is evaluated using this technique and is shown to be a practically viable solution for achieving high DC-to-RF efficiency. Techniques involved in the design and implementation of the novel frequency tripler are investigated, and three microstrip circuits are presented that provide high drain efficiency, high unwanted harmonic rejection and low DC power consumption. Innovative design of the input matching circuit that exploits the nonlinear input capacitance of the device, and the output matching circuit that simultaneously provides appropriate harmonic terminations and unwanted harmonic rejection, ensure a simultaneously high achievable conversion gain and DC-to-RF efficiency. Practical demonstration of the three novel circuits display the highest reported DC-to-RF efficiency and conversion gain for m~crowave frequency triplers to date. Trade-oITs between circ.uit complexity,size and simultaneously achievable high efficiency and high conversion gain are identified and elucidated with the three novel designs

A robust 2.4 GHz time-of-arrival based ranging system with sub-meter accuracy: feasibility study and realization of low power CMOS receiver

Draadloze sensornetwerken worden meer en meer aangewend om verschillende soorten informatie te verzamelen. De locatie, waar deze informatie verzameld is, is een belangerijke eigenschap en voor sommige toepassingen, zoals het volgen van personen of goederen, zelfs de meest belangrijke en mogelijkmakende factor. Om de positie van een sensor te bepalen, is een technologie nodig die de afstand tot een gekend referentiepunt schat. Door verschillende afstandsmetingen te combineren, is het mogelijk de absolute locatie van de node te berekenen

Extension of 0.18µm standard CMOS technology operating range to the microwave and millimetre-wave regime

There is an increasing interest in building millimetre-wave circuits on standard digital complementary metal oxide semiconductor (CMOS) technology for applications such as wireless local area networks (WLAN), automotive radar and remote sensing. This stems from the existing low cost, well-developed, high yield infrastructure for mass production. The overall aim of this thesis is to extend the operating range of 0.18um standard logic CMOS technology to millimetre-wave regime. To this end, microwave and millimetre-wave design, optimisation and modelling methodologies for active and passive devices and low noise circuit implementation are described. As part of the evaluation, new systematic and modular ways of making high performance passive and active devices such as spiral inductors, slow-wave coplanar waveguide (CPW) transmission lines, comb capacitors and NMOS transistors are proposed, designed, simulated, fabricated, modelled and analysed. Small-signal and noise de-embedding techniques are developed and verified up to 110 GHz, providing an increased accuracy in the device model, leading to a robust design at millimetre-wave frequencies. Reduced substrate losses resulting in increased quality factor are presented for optimised spiral inductor designs, featuring patterned floating shield (PFS), enabling improved matching network and a reduced chip area. Based on the proposed shielded slow-wave CPW, both the line attenuation and structure length are decreased, resulting in a more compact and simplified circuit design. An optimised transistor design, aimed at reducing the layout parasitic effects, was realised. The optimisation led to a significant improvement in the gain and noise performance of the transistor, extending its operation beyond the cut-off frequency (ft). By combining all the optimised components, low noise amplifiers (LNAs) operating at 25 GHz and 40 GHz were implemented and compared. These LNAs demonstrate state-of-the-art performance, with the 40 GHz LNA exhibiting the highest gain and lowest noise performance of any LNA reported using 0.18um CMOS technology. On the other hand, the 25 GHz LNA showed a comparable performance to other reported results in literature using several topologies implemented in CMOS technology. These findings will provide a framework for expansion to smaller CMOS technology nodes with the view of extending to sub millimetre-wave frequencies

NEW APPROACHES TO WIDEBAND RF SWITCHING IN SILICON-GERMANIUM TECHNOLOGY

The objective of this research is to develop and investigate radio frequency (RF) switches utilizing silicon-germanium (SiGe) heterojunction bipolar transistors (HBTs) to provide a novel design approach for next-generation wideband circuits and systems. SiGe HBTs offer relatively small parasitic capacitance, making them suitable for wideband RF switching transistors with low insertion loss. Despite the available performance, the effective utilization of SiGe HBTs as RF series switches remains largely unexplored. The research presented in this dissertation introduces a novel RF series switch architecture, namely an anti-parallel (AP) SiGe HBT pair, as a potential wideband switching element for next-generation systems. The benefits of this novel RF series switch architecture are investigated, as well as insightful optimization techniques and an analysis of its operational principles. The dissertation then provides implemented design examples and develops design techniques leveraging properties possessed by the AP SiGe HBT pair.Ph.D