Global ETD Search

11	A 2Gbps Optical Receiver with Integrated Photodiode in 90nm CMOS Rousson, Alain 20 December 2011 (has links) The objective of this work was to integrate an optical receiver in a modern standard technology in a form amenable to multiple lanes. To accomplish this goal, a photodiode was integrated with the receiver in a standard 90nm CMOS process and the nominal process voltage of 1.2V was not exceeded. Two optical lanes were integrated on chip with a pitch compatible with existing industry photodiode arrays. This work uses a non-SML photodiode to increase optical responsivity to 0.141A/W, almost 3 times higher than values typically reported for SML photodiodes. This receiver is the first integrated optical receiver reported in a standard CMOS technology with a feature size smaller than 0.13μm, which is necessary for the eventual integration of optical receivers with modern digital processing blocks on a single die. The traditional analog equalizer used in most integrated optical receivers is replaced with a high-pass filter and hysteresis latch for equalization. The receiver occupies a core area of 0.197mm2 and has an optical sensitivity of -3.7dBm at a 2Gbps data rate, while consuming 46.3mW. CMOS optical receiver photodiode integrated transimpedance amplifier SML 0544
12	Design of a 20MHz Transimpedance Low-pass Filter with an Adapted 3rd Order Inverse Chebyshev Response Boakye, Emmanuel 2012 August 1900 (has links) In Multi-Standard receivers, multiple radios co-exist in close proximity. A desired signal can be accompanied by significantly stronger out-of band interferers or blockers, which can severely degrade a receiver's sensitivity through gain compression of the blocks in the receiver chain. This work presents a new Transimpedance Amplifier (TIA) low-pass filter architecture which seeks to solve the out-of-band blocker problem of the existing architectures. A higher order filtering is embedded within the TIA in the form of an active feedback to provide more attenuation to out-of-band blockers. The active feedback circuitry feeds back an equivalent amount of current to the input node to cancel out incoming out-of-band blockers while maintaining an acceptable voltage swing at the output of the TIA. The proposed TIA filter has a channel bandwidth of 20MHz, and can processes interferers of +/- 10mA fully differential without saturating the opamps. The maximum single ended voltage swing at all the nodes is +/- 200mV. All the circuits were designed in IBM 180nm CMOS process with a supply voltage of 1.8V. Transimpedance Amplifer Analog Filter Direct conversion reciever Out-of-band blockers
13	Integrated receiver channel circuits and structures for a pulsed time-of-flight laser radar Ruotsalainen, T. (Tarmo) 14 April 1999 (has links) Abstract This thesis describes the development of integrated structures and circuit implementations for the receiver channel of portable pulsed time-of-flight laser rangefinders for industrial measurement applications where the measurement range is from ∼1 m to ∼100 m to noncooperative targets and the required measurement accuracy is from a few millimetres to a few centimetres. The receiver channel is used to convert the current pulse from a photodetector to a voltage pulse, amplify it, discriminate the timing point and produce an accurately timed logic-level pulse for a time-to-digital converter. Since the length of the laser pulse, typically 5 ns, is large compared to the required accuracy, a specific point in the pulses has to be discriminated. The amplitude of the input pulses varies widely as a function of measurement range and the reflectivity of the target, typically from 1 to 100 ... 1000, so that the gain of the amplifier channel needs to be controlled and the discrimination scheme should be insensitive to the amplitude variation of the input signal. Furthermore, the amplifier channel should have low noise in order to minimize timing jitter. Alternative circuit structures are discussed, the treatment concentrating on the preamplifier, gain control circuitry and timing discriminator, which are the key circuit blocks from the performance point of view. New circuit techniques and structures, such as a fully differential transimpedance preamplifier and a current mode gain control scheme, have been developed. Several circuit implementations for different applications are presented together with experimental results, one of them being a differential BiCMOS receiver channel with a bandwidth of 170 MHz, input referred noise of 6 pA/√Hz and maximum transimpedance of 260 kW. It has an accuracy of about +/- 7 mm (average of 10000 measurements), taking into account walk error with an input signal range of 1:624 and jitter (3s). The achievable performance level using integrated circuit technology is comparable or superior to that of the previously developed commercially available discrete component implementations, and the significantly reduced size and power consumption open up new application areas. gain control laser rangefinding timing discrimination transimpedance preamplifier
14	Senzor pro nízkorychlostní snímání pohybu kontinua / Sensor for low-speed continuous motion sensing Tomášek, Petr January 2019 (has links) Diploma thesis analyses low-speed flow measurement. Thesis consist of 4 chapters. First chapter is about liquids and its attributes, flow meters, especially induction flow meter, which is very important for designed sensor. In second chapter is detailed process of designing sensor. Description of realization and measurement of flow is in the third chapter. Result summary is in conclusion.
15	A 2.5 GHz Optoelectronic Amplifier in 0.18 m CMOS Calvo, Carlos Roberto 24 April 2003 (has links) The ever-growing need for high speed data transmission is driven by multimedia and telecommunication demands. Traditional metallic media, such as copper coaxial cable, prove to be a limiting factor for high speed communications. Fiber optic methods provide a feasible solution that lacks the limitations of metallic mediums, including low bandwidth, cross talk caused by magnetic induction, and susceptibility to static and RF interferences. The first scientists to work with fibers optics started in 1970. One of the early challenges they faced was to produce glass fiber that was pure enough to be equal in performance with copper based media. Since then, the technology has advanced tremendously in terms of performance, quality, and consistency. The advancement of fiber optic communication has met its limits, not in the purity of its fiber media used to guide the data-modulated light wave, but in the conversion back and forth between electric signals to light. A high speed optic receiver must be used to convert the incident light into electrical signals. This thesis describes the design of a 2.5 GHz Optoelectronic Amplifier, the front end of an optic receiver. The discussion includes a survey of feasible topologies and an assessment of circuit techniques to enhance performance. The amplifier was designed and realized in a TSMC 0.18 µm CMOS process. limiting amplifier optic receiver shunt peaking transimpedance amplifier Optoelectronic devices Optical communications
16	Data acquisition unit for low-noise, continuous glucose monitoring Cooley, Daniel Warren 01 May 2012 (has links) As the number of people with diabetes continues to increase, research efforts improving glucose testing methods and devices are under way to improve outcomes and quality of life for diabetic patients. This dissertation describes the design and testing of a Data Acquisition Unit (DAU) providing low noise photocurrent spectra for use in a continuous glucose monitoring system. The goal of this research is to improve the signal to noise ratio (SNR) of photocurrent measurements to increase glucose concentration measurement accuracy. The glucose monitoring system consists of a portable monitoring device and base station. The monitoring device measures near infrared (IR) absorption spectra from interstitial fluid obtained by microdialysis or ultrafiltration probe and transmits the spectra to a base station via USB or a ZigBee radio link. The base station utilizes chemometric calibration methods to calculate glucose concentration from the photocurrent spectra. Future efforts envisage credit card-sized monitoring devices. The glucose monitor system measures the optical absorbance spectrum of an interstitial fluid (ISF) sample pumped through a fluid chamber inside a glucose sensor. Infrared LEDs in the glucose sensor illuminate the ISF sample with IR light covering the 2.2 to 2.4 micron wavelength region where glucose has unique features in its absorption spectrum. Light that passes through the sample propagates through a linearly variable bandpass filter and impinges on a photodiode array. The center frequency of the variable filter is graded along its length such that the filter and photodiode array form a spectrometer. The data acquisition unit (DAU) conditions and samples photocurrent from each photodiode channel and sends the resulting photocurrent spectra to the Main Controller Unit (MCU). The MCU filters photocurrent samples providing low noise photocurrent spectra to a base station via USB or Zigbee radio link. The glucose monitoring system limit of detection (LOD) from a single glucose sensor wavelength is 5.8 mM with a system bandwidth of 0.00108 Hz. Further analysis utilizing multivariate calibration methods such as the net analyte signal method promise to reduce the glucose monitoring system LOD approaching a clinically useful level of approximately 2 mM. Glucose Monitoring Lock-In Amplifier Low Noise Electronics Transimpedance Amplifier Electrical and Computer Engineering
17	Design and Implementation of an Ion Beam Profiling System Stude, Joan January 2009 (has links) <p>The work describes the development of a reliable device for profiling anion beam in the intensity cross section. A sensor head consisting of a Faradaycup in combination with a Channel Electron Multiplier was designedand built together with electronics including power supply and front endelectronics. The design was chosen considering financial and long term lifeaspects. Testing, first calibration and error analysis were done using the ionbeam facilities where the unit is supposed to be installed permanently. Theprofiling system performed as designed and the profile of the ion beam couldbe measured reliably with an accuracy down to the femto ampere range.</p> ion beam profile Faraday cup channel electron multiplier transimpedance amplifier Electrophysics Elektrofysik
18	Design and Implementation of an Ion Beam Profiling System Stude, Joan January 2009 (has links) The work describes the development of a reliable device for profiling anion beam in the intensity cross section. A sensor head consisting of a Faradaycup in combination with a Channel Electron Multiplier was designedand built together with electronics including power supply and front endelectronics. The design was chosen considering financial and long term lifeaspects. Testing, first calibration and error analysis were done using the ionbeam facilities where the unit is supposed to be installed permanently. Theprofiling system performed as designed and the profile of the ion beam couldbe measured reliably with an accuracy down to the femto ampere range. ion beam profile Faraday cup channel electron multiplier transimpedance amplifier Electrophysics Elektrofysik
19	High performance multimode fiber systems: a comprehensive approach Polley, Arup 17 November 2008 (has links) Steady increases in the bandwidth requirements of access networks and local area networks have created a need for short-reach links supporting data rates of 10 Gb/s and larger. Server applications and data center applications too require such links. The primary challenge for these links lies in the reduction of the cost while retaining or improving the performance. Traditionally, multimode fiber (MMF) has satisfied these needs because of its low installation cost resulting from the alignment tolerance associated with the large core size. However, in view of the ever-increasing performance requirements, extraction of the best performance requires a holistic view of the channel that involves global optimization of transmitter, fiber, receiver performance and signaling strategies. The optimization results in a channel impairment mitigation technique that is a combination of optical, opto-electronic, and electronic methods. Both glass and plastic MMF links have been addressed in this work and many of the advances apply equally to both media. One example that applies strictly to glass MMF is the use of Raman amplification to not only combat attenuation but to reduce intersymbol interference (ISI). Raman amplification was demonstrated as an optical channel impairment mitigation technique enabling multi-km, multi-Gb/s transmission over glass-MMF. We demonstrated both numerically and experimentally that a power penalty reduction of 1.4 dBo can be achieved for 10 Gb/s transmission over 9 km of 62 micron glass MMF with a Raman pump power 250 mW. In recent years, plastic optical fiber (POF) has emerged as a potentially lower cost alternative to glass-MMF in enabling high performance links. The primary objective of this research is to explore the possibilities and develop low-cost, short-reach, high-data-rate POF-links. Using a comprehensive multimode fiber model, we showed that strong mode coupling, together with a reasonably accurate refractive index profile enables 40 Gb/s transmission over 200 m of graded-index POF. We experimentally demonstrated 40 Gb/s error-free transmission over 100 m of graded index perfluorinated POF (GI-PF-POF). We also demonstrated that even larger core (120 micron) GI-PF-POF can support >10 Gb/s over 100 m length. We numerically computed and experimentally measured the differential modal delay of GI-PF-POF to demonstrate that the available bandwidth is nearly independent of the launch conditions. Therefore, the alignment tolerance at the transmitter is increased resulting in a dramatically reduced packaging cost at the transmitter. However, the large-core POF increases the difficultly in capturing of the light efficiently onto a detector and results in optical power penalty and associated modal noise. To solve this, we have designed and developed a 10 Gb/s photoreceiver consisting of a large (100 micron diameter) GaAs PIN photodetector and a regulated cascade input based transimpedance amplifier (TIA) with low input impedance. Thus, a low-cost, alignment-tolerant, high-data-rate link is realized that uses a high-power, high-speed vertical cavity surface emitting laser (VCSEL) transmitter, large-core, high-speed GI-PF-POF, and the developed receiver. Plastic optical fiber Photoreceiver Transimpedance amplifier Plastic optical fibers Optical fibers Optical fiber communication
20	Analog Signal Processing for Optical Coherence Imaging Systems Xu, Wei January 2006 (has links) Optical coherence tomography (OCT) and optical coherence microscopy (OCM) are non-invasive optical coherence imaging techniques, which enable micron-scale resolution, depth resolved imaging capability. Both OCT and OCM are based on Michelson interferometer theory. They are widely used in ophthalmology, gastroenterology and dermatology, because of their high resolution, safety and low cost. OCT creates cross sectional images whereas OCM obtains en face images. In this dissertation, the design and development of three increasingly complicated analog signal processing (ASP) solutions for optical coherence imaging are presented.The first ASP solution was implemented for a time domain OCT system with a Rapid Scanning Optical Delay line (RSOD)-based optical signal modulation and logarithmic amplifier (Log amp) based demodulation. This OCT system can acquire up to 1600 A-scans per second. The measured dynamic range is 106dB at 200A-scan per second. This OCT signal processing electronics includes an off-the-shelf filter box with a Log amp circuit implemented on a PCB board.The second ASP solution was developed for an OCM system with synchronized modulation and demodulation and compensation for interferometer phase drift. This OCM acquired micron-scale resolution, high dynamic range images at acquisition speeds up to 45,000 pixels/second. This OCM ASP solution is fully custom designed on a perforated circuit board.The third ASP solution was implemented on a single 2.2 mm x 2.2 mm complementary metal oxide semiconductor (CMOS) chip. This design is expandable to a multiple channel OCT system. A single on-chip CMOS photodetector and ASP channel was used for coherent demodulation in a time domain OCT system. Cross-sectional images were acquired with a dynamic range of 76dB (limited by photodetector responsivity). When incorporated with a bump-bonded InGaAs photodiode with higher responsivity, the expected dynamic range is close to 100dB. optical coherence tomography optical coherence microscopy CMOS analog circuit transimpedance demodulation

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