Design and Implementation of a Signal Conditioning Operational Amplifier for a Reflective Object Sensor

Industrial systems often require the acquisition of real-world analog signals for several applications. Various physical phenomena such as displacement, pressure, temperature, light intensity, etc. are measured by sensors, which is a type of transducer, and then converted into a corresponding electrical signal. The electrical signal obtained from the sensor, usually a few tens mV in magnitude, is subsequently conditioned by means of amplification, filtering, range matching, isolation etc., so that the signal can be rendered for further processing and data extraction. This thesis presents the design and implementation of a general purpose op amp used to condition a reflective object sensor’s output. The op amp is used in a non-inverting configuration, as a current-to-voltage converter to transform a phototransistor current into a usable voltage. The op amp has been implemented using CMOS architecture and fabricated in AMI 0.5-µm CMOS process available through MOSIS. The thesis begins with an overview of the various circuits involving op amps used in signal conditioning circuits. Owing to the vast number of applications for sensor signal conditioning circuits, a brief discussion of an industrial sensor circuit is also illustrated. This is followed by the complete design of the op amp and its implementation in the data acquisition circuit. The op amp is then characterized using simulation results. Finally, the test setup and the measurement results are presented. The thesis concludes with an overview of some possible future work on the sensor-op amp data acquisition circuit

Design and characterization of low voltage operational amplifiers for smart sensors using low cost CMOS technology

This bachelor thesis brackets the use of different OTA topologies and compares them under the scope of their application as low power comparators and adders for a ΣΔ ADC. This was undertaken under the “Design and characterization of main building blocks for Medical instrumentation ADCs” research project and, more specifically, in the “Design of a Low-IF Sigma-Delta Modulator” section. The researched topologies include a folded cascode, telescopic cascode, class A Miller as well as a class AB Miller. The implementation was performed at transistor level of the for all topologies in a 0.18 μm with original 1.8 V, downscaled to 1.5 V with the goal of reducing power consumption.Ingeniería Biomédic

A 90 dB, 85 MHz operational transconductance amplifier (OTA) using gain boosting technique

Gain and speed are the two most important parameters of an amplifier. Optimizing an amplifier for both of these parameters leads to contradicting demands. Various architectures have been reported to obtain high gain from the circuits. Cascode circuits are widely used in circuit design at places where high gain and high output impedances are required. Different architectures like triple cascode topology, dynamic biasing and a positive feedback amplifier have been used to obtain high gains. These architectures have been compared in this thesis along with drawbacks and advantages of each

Zero DC offset active RC filter designs.

A class of RC active filters in which the DC offset of the operational amplifier (op-amp) is completely absent from the filter output [1]. Individual filter configurations (Low Pass, High Pass, Band Pass, Band Stop, All Pass) are discussed and corresponding transfer functions are defined. The effects of op-amp gain bandwidth product on filter responses are accounted for and presented in a table. In order to understand the upper limit of dynamic responses, maximum signal magnitude and corresponding frequency of maximum magnitude are calculated. The effects of noise generating components are defined and included, thus establishing the lower limit of dynamic responses for all filter configurations. Step-by-step design procedures are given for most common filter configurations. Sample filters are designed based on chosen values for critical frequency ù 0 and filter quality factor Q. Filter schematics are captured and their frequency responses are simulated using circuit simulation software. Sample filters are built and their frequency responses are confirmed using a network analyzer. Extension to higher order filters is discussed and demonstrated

Design of an Active Harmonic Rejection N-Path Filter for Highly Tunable RF Channel Selection

As the number of wireless devices in the world increases, so does the demand for flexible radio receiver architectures capable of operating over a wide range of frequencies and communication protocols. The resonance-based channel-select filters used in traditional radio architectures have a fixed frequency response, making them poorly suited for such a receiver. The N-path filter is based on 1960s technology that has received renewed interest in recent years for its application as a linear high Q filter at radio frequencies. N-path filters use passive mixers to apply a frequency transformation to a baseband low-pass filter in order to achieve a high-Q band-pass response at high frequencies. The clock frequency determines the center frequency of the band-pass filter, which makes the filter highly tunable over a broad frequency range. Issues with harmonic transfer and poor attenuation limit the feasibility of using N-path filters in practice. The goal of this thesis is to design an integrated active N-path filter that improves upon the passive N-path filter’s poor harmonic rejection and limited outof- band attenuation. The integrated circuit (IC) is implemented using the CMRF8SF 130nm CMOS process. The design uses a multi-phase clock generation circuit to implement a harmonic rejection mixer in order to suppress the 3rd and 5th harmonic. The completed active N-path filter has a tuning range of 200MHz to 1GHz and the out-ofband attenuation exceeds 60dB throughout this range. The frequency response exhibits a 14.7dB gain at the center frequency and a -3dB bandwidth of 6.8MHz

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

Pipelined multi-step interpolating A/D converter

Thesis (M.S.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1995.Includes bibliographical references (p. 97-98).by Edmond Patrick Coady.M.S

CMOS design of chaotic oscillators using state variables: a monolithic Chua's circuit

This paper presents design considerations for monolithic implementation of piecewise-linear (PWL) dynamic systems in CMOS technology. Starting from a review of available CMOS circuit primitives and their respective merits and drawbacks, the paper proposes a synthesis approach for PWL dynamic systems, based on state-variable methods, and identifies the associated analog operators. The GmC approach, combining quasi-linear VCCS's, PWL VCCS's, and capacitors is then explored regarding the implementation of these operators. CMOS basic building blocks for the realization of the quasi-linear VCCS's and PWL VCCS's are presented and applied to design a Chua's circuit IC. The influence of GmC parasitics on the performance of dynamic PWL systems is illustrated through this example. Measured chaotic attractors from a Chua's circuit prototype are given. The prototype has been fabricated in a 2.4- mu m double-poly n-well CMOS technology, and occupies 0.35 mm/sup 2/, with a power consumption of 1.6 mW for a +or-2.5-V symmetric supply. Measurements show bifurcation toward a double-scroll Chua's attractor by changing a bias current