3 research outputs found
LOW POWER AND HIGH SIGNAL TO NOISE RATIO BIO-MEDICAL AFE DESIGN TECHNIQUES
The research work described in this thesis was focused on finding novel techniques to
implement a low-power and noise Bio-Medical Analog Front End (BMEF) circuit
technique to enable high-quality Electrocardiography (ECG) sensing. Usually, an ECG
signal and several bio-medical signals are sensed from the human body through a pair
of electrodes. The electrical characteristics of the very small amplitude (1u-10mV)
signals are corrupted by random noise and have a significant dc offset. 50/60Hz power
supply coupling noise is one of the biggest cross-talk signals compared to the thermally
generated random noise. These signals are even AFE composed of an Instrumentation
Amplifier (IA), which will have a better Common Mode rejection ratio (CMRR). The main
function of the AFE is to convert the weak electrical Signal into large signals whose
amplitude is large enough for an Analog Digital Converter (ADC) to detect without having
any errors. A Variable Gain Amplifier (VGA) is sometimes required to adjust signal
amplitude to maintain the dynamic range of the ADC. Also, the Bio-medical transceiver
needs an accurate and temperature-independent reference voltage and current for the
ADC, commonly known as Bandgap Reference Circuit (BGR). These circuits need to
consume as low power as possible to enable these circuits to be powered from the
battery.
The work started with analysing the existing circuit techniques for the circuits
mentioned above and finding the key important improvements required to reach the
target specifications. Previously proposed IA is generated based on voltage mode signal
processing. To improve the CMRR (119dB), we proposed a current mode-based IA with
an embedded DC cancellation technique. State-of-the-art VGA circuits were built based
on the degeneration principle of the differential pair, which will enable the variable gain
purpose, but none of these techniques discussed linearity improvement, which is very
important in modern CMOS technologies. This work enhances the total Harmonic
distortion (THD) by 21dB in the worst case by exploiting the feedback techniques around
the differential pair. Also, this work proposes a low power curvature compensated
bandgap with 2ppm/0C temperature sensitivity while consuming 12.5uW power from a
1.2V dc power supply. All circuits were built in 45nm TSMC-CMOS technology and
simulated with all the performance metrics with Cadence (spectre) simulator. The circuit
layout was carried out to study post-layout parasitic effect sensitivity
Design Techniques for High Speed Low Voltage and Low Power Non-Calibrated Pipeline Analog to Digital Converters
The profound digitization of modern microelectronic modules made Analog-to-
Digital converters (ADC) key components in many systems. With resolutions up to
14bits and sampling rates in the 100s of MHz, the pipeline ADC is a prime candidate for
a wide range of applications such as instrumentation, communications and consumer
electronics. However, while past work focused on enhancing the performance of the
pipeline ADC from an architectural standpoint, little has been done to individually
address its fundamental building blocks. This work aims to achieve the latter by
proposing design techniques to improve the performance of these blocks with minimal
power consumption in low voltage environments, such that collectively high
performance is achieved in the pipeline ADC.
Towards this goal, a Recycling Folded Cascode (RFC) amplifier is proposed as
an enhancement to the general performance of the conventional folded cascode. Tested
in Taiwan Semiconductor Manufacturing Company (TSMC) 0.18?m Complementary
Metal Oxide Semiconductor (CMOS) technology, the RFC provides twice the
bandwidth, 8-10dB additional gain, more than twice the slew rate and improved noise performance over the conventional folded cascode-all at no additional power or silicon
area. The direct auto-zeroing offset cancellation scheme is optimized for low voltage
environments using a dual level common mode feedback (CMFB) circuit, and amplifier
differential offsets up to 50mV are effectively cancelled. Together with the RFC, the
dual level CMFB was used to implement a sample and hold amplifier driving a singleended
load of 1.4pF and using only 2.6mA; at 200MS/s better than 9bit linearity is
achieved. Finally a power conscious technique is proposed to reduce the kickback noise
of dynamic comparators without resorting to the use of pre-amplifiers. When all
techniques are collectively used to implement a 1Vpp 10bit 160MS/s pipeline ADC in
Semiconductor Manufacturing International Corporation (SMIC) 0.18[mu]m CMOS, 9.2
effective number of bits (ENOB) is achieved with a near Nyquist-rate full scale signal.
The ADC uses an area of 1.1mm2 and consumes 42mW in its analog core. Compared to
recent state-of-the-art implementations in the 100-200MS/s range, the presented pipeline
ADC uses the least power per conversion rated at 0.45pJ/conversion-step
A 100dB SFDR 0.5V pk-pk band-pass DAC implemented on a low voltage CMOS process
Direct Digital Synthesis (DDS) systems generate fine frequency
resolution signals over a broad spectrum that are used in a wide variety of
applications such as multi-mode RF, communications, measurements and test.
A high performance DDS band-pass Digital to Analog Converter (DAC)
architecture and implementation is presented that delivers high spectral purity
over a narrow-band response. The low power D/A Converter is portable to
standard CMOS processes and designed to achieve over 100dB narrow-band
SFDR performance using Sigma-Delta (ΣΔ) modulation and multi-bit current
steering techniques. A 3rd order digital ΣΔ modulator is combined with a 4th
order digital Dynamic Element Matching (DEM) block to shape the noise while
calibrating for process mismatch variations. A low silicon area output stage is
used to deliver a high performance specification