4 research outputs found
Integrated RF oscillators and LO signal generation circuits
This thesis deals with fully integrated LC oscillators and local oscillator (LO) signal generation circuits. In communication systems a good-quality LO signal for up- and down-conversion in transmitters is needed. The LO signal needs to span the required frequency range and have good frequency stability and low phase noise. Furthermore, most modern systems require accurate quadrature (IQ) LO signals. This thesis tackles these challenges by presenting a detailed study of LC oscillators, monolithic elements for good-quality LC resonators, and circuits for IQ-signal generation and for frequency conversion, as well as many experimental circuits. Monolithic coils and variable capacitors are essential, and this thesis deals with good structures of these devices and their proper modeling. As experimental test devices, over forty monolithic inductors and thirty varactors have been implemented, measured and modeled. Actively synthesized reactive elements were studied as replacements for these passive devices. At first glance these circuits show promising characteristics, but closer noise and nonlinearity analysis reveals that these circuits suffer from high noise levels and a small dynamic range. Nine circuit implementations with various actively synthesized variable capacitors were done. Quadrature signal generation can be performed with three different methods, and these are analyzed in the thesis. Frequency conversion circuits are used for alleviating coupling problems or to expand the number of frequency bands covered. The thesis includes an analysis of single-sideband mixing, frequency dividers, and frequency multipliers, which are used to perform the four basic arithmetical operations for the frequency tone. Two design cases are presented. The first one is a single-sideband mixing method for the generation of WiMedia UWB LO-signals, and the second one is a frequency conversion unit for a digital period synthesizer. The last part of the thesis presents five research projects. In the first one a temperature-compensated GaAs MESFET VCO was developed. The second one deals with circuit and device development for an experimental-level BiCMOS process. A cable-modem RF tuner IC using a SiGe process was developed in the third project, and a CMOS flip-chip VCO module in the fourth one. Finally, two frequency synthesizers for UWB radios are presented
Frequency Synthesis in Wireless and Wireline Systems
First, a frequency synthesizer for IEEE 802.15.4 / ZigBee transceiver applications that employs dynamic True Single Phase Clocking (TSPC) circuits in its frequency dividers is presented and through the analysis and measurement results of this synthesizer, the need for low power circuit techniques in frequency dividers is discussed.
Next, Differential Cascode Voltage-Switch-Logic (DCVSL) based delay cells are explored for implementing radio-frequency (RF) frequency dividers of low power frequency
synthesizers. DCVSL ip- ops offer small input and clock capacitance which makes the power consumption of these circuits and their driving stages, very low. We perform a delay analysis of DCVSL circuits and propose a closed-form delay model that predicts the speed of DCVSL circuits with 8 percent worst case accuracy. The proposed
delay model also demonstrates that DCVSL circuits suffer from a large low-to-high propagation delay ( PLH) which limits their speed and results in asymmetrical output
waveforms. Our proposed enhanced DCVSL, which we call DCVSL-R, solves this delay bottleneck, reducing PLH and achieving faster operation.
We implement two ring-oscillator-based voltage controlled oscillators (VCOs) in 0.13 mu m technology with DCVSL and DCVSL-R delay cells. In measurements, for the same oscillation frequency (2.4GHz) and same phase noise (-113dBc/Hz at 10MHz), DCVSL-R VCO consumes 30 percent less power than the DCVSL VCO. We also use the
proposed DCVSL-R circuit to implement the 2.4GHz dual-modulus prescaler of a low power frequency synthesizer in 0.18 mu m technology. In measurements, the synthesizer exhibits -135dBc/Hz phase noise at 10MHz offset and 58 mu m settling time with 8.3mW power consumption, only 1.07mWof which is consumed by the dual modulus prescaler and the buffer that drives it. When compared to other dual modulus prescalers with similar division ratios and operating frequencies in literature, DCVSL-R dual modulus prescaler demonstrates the lowest power consumption.
An all digital phase locked loop (ADPLL) that operates for a wide range of frequencies to serve as a multi-protocol compatible PLL for microprocessor and serial
link applications, is presented. The proposed ADPLL is truly digital and is implemented in a standard complementary metal-oxide-semiconductor (CMOS) technology
without any analog/RF or non-scalable components. It addresses the challenges that come along with continuous wide range of operation such as stability and phase frequency detection for a large frequency error range. A proposed multi-bit bidirectional smart shifter serves as the digitally controlled oscillator (DCO) control and tunes the DCO frequency by turning on/off inverter units in a large row/column matrix that constitute the ring oscillator. The smart shifter block is completely digital, consisting of standard cell logic gates, and is capable of tracking the row/column unit availability
of the DCO and shifting multiple bits per single update cycle. This enables fast frequency acquisition times without necessitating dual loop fi lter or gear shifting
mechanisms.
The proposed ADPLL loop architecture does not employ costly, cumbersome DACs or binary to thermometer converters and minimizes loop filter and DCO control
complexity. The wide range ADPLL is implemented in 90nm digital CMOS technology and has a 9-bit TDC, the output of which is processed by a 10-bit digital loop filter
and a 5-bit smart shifter. In measurements, the synthesizer achieves 2.5GHz-7.3GHz operation while consuming 10mW/GHz power, with an active area of 0.23 mm2
PROCESS AWARE ANALOG-CENTRIC SINGLE LEAD ECG ACQUISITION AND CLASSIFICATION CMOS FRONTEND
The primary objective of this research work is the development of a low power single-lead ECG
analog front-end (AFE) architecture which includes acquisition, digitization, process aware efficient
gain and frequency control mechanism and a low complexity classifier for the detecting asystole,
extreme bardycardia and tachycardia. Recent research on ECG recording systems focuses on the
design of a compact single-lead wearable/portable devices with ultra-low-power consumption and
in-built hardware for diagnosis and prognosis. Since, the amplitude of the ECG signal varies from
hundreds of µV to a few mV, and has a bandwidth of DC to 250 Hz, conventional front-ends use
an instrument amplifier followed by a programmable gain amplifier (PGA) to amplify the input
ECG signal appropriately. This work presents an mixed signal ECG fronted with an ultra-low
power two-stage capacitive-coupled signal conditioning circuit (or an AFE), providing programmable
amplification along with tunable 2nd order high pass and lowpass filter characteristics. In the
contemporary state-of-the-art ECG recording systems, the gain of the amplifier is controlled by
external digital control pins which are in turn dynamically controlled through a DSP. Therefore, an
efficient automatic gain control mechanism with minimal area overhead and consuming power in the
order of nano watts only. The AGC turns the subsequent ADC on only after output of the PGA (or
input of the ADC) reaches a level for which the ADC achieves maximum signal-to-noise-ratio (SNR),
hence saving considerable startup power and avoiding the use of DSP. Further, in any practical filter
design, the low pass cut-off frequency is prone to deviate from its nominal value across process
and temperature variations. Therefore, post-fabrication calibration is essential, before the signal
is fed to an ADC, to minimize this deviation, prevent signal degradation due to aliasing of higher
frequencies into the bandwidth
for classification of ECG signals, to switch to low resolution processing, hence saving power and
enhances battery lifetime. Another short-coming noticed in the literature published so far is that
the classification algorithm is implemented in digital domain, which turns out to be a power hungry
approach. Moreover, Although analog domain implementations of QRS complexes detection schemes
have been reported, they employ an external micro-controller to determine the threshold voltage. In
this regard, finally a power-efficient low complexity CMOS fully analog classifier architecture and a
heart rate estimator is added to the above scheme. It reduces the overall system power consumption
by reducing the computational burden on the DSP. The complete proposed scheme consists of (i)
an ultra-low power QRS complex detection circuit using an autonomous dynamic threshold voltage,
hence discarding the need of any external microcontroller/DSP and calibration (ii) a power efficient
analog classifier for the detection of three critical alarm types viz. asystole, extreme bradycardia
and tachycardia. Additionally, a heart rate estimator that provides the number of QRS complexes
within a period of one minute for cardiac rhythm (CR) and heart rate variability (HRV) analysis.
The complete proposed architecture is implemented in UMC 0.18 µm CMOS technology with 1.8 V
supply. The functionality of each of the individual blocks are successfully validated using postextraction
process corner simulations and through real ECG test signals taken from the PhysioNet
database. The capacitive feedback amplifier, Σ∆ ADC, AGC and the AFT are fabricated, and the
measurement results are discussed here. The analog classification scheme is successfully validated
using embed NXP LPC1768 board, discrete peak detector prototype and FPGA software interfac
Analysis and Design of Robust Multi-Gb/s Clock and Data Recovery Circuits
The bandwidth demands of modern computing systems have been continually increasing and the recent focus on parallel processing will only increase the demands placed on data communication circuits. As data rates enter the multi-Gb/s range, serial data communication architectures become attractive as compared to parallel architectures. Serial architectures have long been used in fibre optic systems for long-haul applications, however, in the past decade there has been a trend towards multi-Gb/s backplane interconnects. The integration of clock and data recovery (CDR) circuits into monolithic integrated circuits (ICs) is attractive as it improves performance and reduces the system cost, however it also introduces new challenges, one of which is robustness. In serial data communication systems the CDR circuit is responsible for recovering the data from an incoming data stream. In recent years there has been a great deal of research into integrating CDR circuits into monolithic ICs. Most research has focused on increasing the bandwidth of the circuits, however in order to integrate multi-Gb/s CDR circuits robustness, as well as performance, must be considered. In this thesis CDR circuits are analyzed with respect to their robustness. The phase detector is a critical block in a CDR circuit and its robustness will play a significant role in determining the overall performance in the presence of process non-idealities. Several phase detector architectures are analyzed to determine the effects of process non-idealities. Static phase offsets are introduced as a figure of merit for phase detectors and a mathematical framework is described to characterize the negative effects of static phase offsets on CDR circuits. Two approaches are taken to improve the robustness of CDR circuits. First, calibration circuits are introduced which correct for static phase offsets in CDR circuits. Secondly, phase detector circuits are introduced which have been designed to optimize both performance and robustness. Several prototype chips which implement these schemes will be described and measured results will be presented. These results show that while CDR circuits are vulnerable to the effects of process non-idealities, there are circuit techniques which can mitigate many of these concerns