Ultra high data rate CMOS front ends

The availability of numerous mm-wave frequency bands for wireless communication has motivated the exploration of multi-band and multi-mode integrated components and systems in the main stream CMOS technology. This opportunity has faced the RF designer with the transition between schematic and layout. Modeling the performance of circuits after layout and taking into account the parasitic effects resulting from the layout are two issues that are more important and influential at high frequency design. Performing measurements using on-wafer probing at 60 GHz has its own complexities. The very short wave-length of the signals at mm-wave frequencies makes the measurements very sensitive to the effective length and bending of the interfaces. This paper presents different 60 GHz corner blocks, e.g. Low Noise Amplifier, Zero IF mixer, Phase-Locked Loop, a Dual-Mode Mm-Wave Injection-Locked Frequency Divider and an active transformed power amplifiers implemented in CMOS technologies. These results emphasize the feasibility of the realization 60 GHZ integrated components and systems in the main stream CMOS technology

Analog Baseband Filters and Mixed Signal Circuits for Broadband Receiver Systems

Data transfer rates of communication systems continue to rise fueled by aggressive demand for voice, video and Internet data. Device scaling enabled by modern lithography has paved way for System-on-Chip solutions integrating compute intensive digital signal processing. This trend coupled with demand for low power, battery-operated consumer devices offers extensive research opportunities in analog and mixed-signal designs that enable modern communication systems. The first part of the research deals with broadband wireless receivers. With an objective to gain insight, we quantify the impact of undesired out-band blockers on analog baseband in a broadband radio. We present a systematic evaluation of the dynamic range requirements at the baseband and A/D conversion boundary. A prototype UHF receiver designed using RFCMOS 0.18[mu]m technology to support this research integrates a hybrid continuous- and discrete-time analog baseband along with the RF front-end. The chip consumes 120mW from a 1.8V/2.5V dual supply and achieves a noise figure of 7.9dB, an IIP3 of -8dBm (+2dbm) at maximum gain (at 9dB RF attenuation). High linearity active RC filters are indispensable in wireless radios. A novel feed-forward OTA applicable to active RC filters in analog baseband is presented. Simulation results from the chip prototype designed in RFCMOS 0.18[mu]m technology show an improvement in the out-band linearity performance that translates to increased dynamic range in the presence of strong adjacent blockers. The second part of the research presents an adaptive clock-recovery system suitable for high-speed wireline transceivers. The main objective is to improve the jitter-tracking and jitter-filtering trade-off in serial link clock-recovery applications. A digital state-machine that enables the proposed mixed-signal adaptation solution to achieve this objective is presented. The advantages of the proposed mixed-signal solution operating at 10Gb/s are supported by experimental results from the prototype in RFCMOS 0.18[mu]m technology

A reconfigurable 60GHz receiver : providing robustness to process variations

The problems associated with process-induced variability and other challenges of 60GHz circuit design and measurement are treated in this thesis. A system-level analysis is performed on a generic RF receiver. For doing that, first, bit error rate (BER) is considered as a figure of merit representing the overall performance of the Receiver. Then, each stage of the receiver is described by three parameters: voltage gain, noise, and nonlinearity which are prone to variation due to process spread. The variation of these parameters represents all lower-level sources of variability. Since bit error rate (BER), as a major performance measure of the receiver, is a direct function of the noise and distortion, the contribution of each block to the overall noise plus distortion (NPD) is analyzed, which opens the way for minimization of the sensitivity of the NPD to the performance variation of individual stages. It is shown that the first order sensitivities of NPD to the individual gains of the building blocks can all be made zero. Its second order sensitivity to the gains of the building blocks can be reduced. Its sensitivity to noise and nonlinearity of an individual building block can be reduced, but at the cost of that of other blocks; its sensitivity to noise and nonlinearity cannot be reduced over the whole system. Three design approaches are proposed, analyzed and compared. Statistical and corner simulations are performed to confirm the validity of the proposed guidelines showing significant improvement in the yield of the designs. Applying the analysis to a zero-IF three-stage 60 GHz receiver shows a significant improvement in the design yield, by nullifying the first order sensitivities of the overall performance to the individual gains of the blocks. Reduction of the second order sensitivity of the NPD to the gain of individual stages, by keeping the contribution factor of all the stages below one, results in further improvements in the design yield. The conventional optimum-power design methodology has been modified in a way that it nullifies the first order sensitivities of NPD to the individual gains of all the stages. It is shown that for simultaneous power optimization and reduced second-order sensitivity to the gains of the blocks less power hungry building blocks must be in the rear stages of the receiver and more power hungry ones in the front. After identifying the limitations of a pure system-level approach, i.e., inability to suppress the sensitivity of the overall performance to the noise and nonlinearity of all the blocks, the focus is shifted towards circuit-level methods by providing re-configurability to some RF circuits. A receiver is designed with good noise and nonlinearity performance and with accumulated noise and nonlinearity distortion contribution in its last stage (mixer). As a result, the overall performance of the receiver is more sensitive to the performance variations of the mixer. Simulations show that it is possible to correct the overall receiver performance degradations resulting from process variations by just tuning the performance of the mixer. Furthermore, a tunable mixer is presented for minimizing the IMD2 across a wide IF bandwidth. It is demonstrated both in theory and measurement that a presented three-dimensional tuning method is beneficial for wideband cancellation of second order intermodulation distortions (IMD2) in a zero-IF downconverter. A 60GHz zero-IF mixer is designed and measured on-wafer to show that the proposed tuning mechanism can simultaneously suppress IMD2 tones across the whole 1GHz IF band. To address the challenges of 60GHz circuit design, a design methodology is utilized which serves to properly model the parasitic effects and improve the predictability of the performance. The parasitic effects due to layout, which are more influential at high frequencies, are taken into account by performing automatic RC extraction and manual L extraction. The long signal lines are modeled with distributed RLC networks. The problem of substrate losses is addressed by using patterned ground shields in inductors and transmission lines. The cross-talk issue is treated by using distributed meshed ground lines, decoupled DC lines, and grounded substrate contacts around sensitive RF components. However, in practice, it is observed that accurate simulation of all the effects is sometimes very time consuming or even infeasible. For instance electromagnetic simulation of a transformer in the presence of all the dummy metals is beyond the computational capability of existing EM-simulators. Three 60GHz receiver components are analyzed, designed, and measured with good performance. A two-stage fully integrated 60 GHz differential low noise amplifier is implemented in a CMOS 65 nm bulk technology with superior noise figure compared to state-of-the-art mm-wave LNAs. A doublebalanced 60 GHz mixer with ac-coupled RF input is designed and measured with a series capacitor in the input RF path to suppress the low frequency second order intermodulation distortions generated in the previous stage. A quadrature 60 GHz VCO is presented which exhibits a comparable level of performance, in particular very good phase noise, to state-of-the-art single-phase VCOs, despite the additional challenges and limitations imposed by the quadrature topology. The on-wafer measurements on the 60GHz circuits designed in this work are performed using a waveguide-based measurement setup. The fixed waveguide structures, specially provided for the probe station, serve for the robustness of the setup as they circumvent the need for cables, which are by nature difficult to rigidify, in the vicinity of the probes. Taking advantage of magic- Ts, it is possible to measure differential mm-wave circuits with a two-port network analyzer rather than using a much more expensive four-port one. Noise, s-parameter, and phase noise measurements are performed using the mentioned setups

Distributed Circuit Analysis and Design for Ultra-wideband Communication and sub-mm Wave Applications

This thesis explores research into new distributed circuit design techniques and topologies, developed to extend the bandwidth of amplifiers operating in the mm and sub-mm wave regimes, and in optical and visible light communication systems. Theoretical, mathematical modelling and simulation-based studies are presented, with detailed designs of new circuits based on distributed amplifier (DA) principles, and constructed using a double heterojunction bipolar transistor (DHBT) indium phosphide (InP) process with fT =fmax of 350/600 GHz. A single stage DA (SSDA) with bandwidth of 345 GHz and 8 dB gain, based on novel techniques developed in this work, shows 140% bandwidth improvement over the conventional DA design. Furthermore, the matrix-single stage DA (M-SSDA) is proposed for higher gain than both the conventional DA and matrix amplifier. A two-tier M-SSDA with 14 dB gain at 300 GHz bandwidth, and a three-tier M-SSDA with a gain of 20 dB at 324 GHz bandwidth, based on a cascode gain cell and optimized for bandwidth and gain flatness, are presented based on full foundry simulation tests. Analytical and simulation-based studies of the noise performance peculiarities of the SSDA and its multiplicative derivatives are also presented. The newly proposed circuits are fabricated as monolithic microwave integrated circuits (MMICs), with measurements showing 7.1 dB gain and 200 GHz bandwidth for the SSDA and 12 dB gain at 170 GHz bandwidth for the three-tier M-SSDA. Details of layout, fabrication and testing; and discussion of performance limiting factors and layout optimization considerations are presented. Drawing on the concept of artificial transmission line synthesis in distributed amplification, a new technique to achieve up to three-fold improvement in the modulation bandwidth of light emitting diodes (LEDs) for visible light communication (VLC) is introduced. The thesis also describes the design and application of analogue pre-emphasis to improve signal-to-noise ratio in bandwidth limited optical transceivers