49 research outputs found

    Investigation and design of key circuit blocks in a 10 bit SAR ADC at 100 MS/s

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    The work in this thesis is based on the investigation and design of key circuit blocks in a high speed, high resolution SAR ADC in TSMC’s 28nm technology. The research carried out analyses the circuit limitations of the switched capacitor DAC and the settling problems of the reference voltage associated with a switched capacitor scheme. The switched capacitor DAC is a critical block for overall ADC performance and various trade-offs are weighed up before discussing the layout of the split capacitor DAC implemented in the project, from unit capacitor up to top level routing. It also investigates the main sources of error using this topology and implements effective ways of mitigating these errors. The schematic design of DAC switches is also carried out and the results section discusses the top level linearity performance of the DAC. This work also focuses on detailed analysis and implementation of a reference buffer circuit solution that is capable of supplying a reference voltage that is highly accurate and can settle in enough time for the high speed and high resolution specifications required by the SAR ADC. Various solutions were comprehensively investigated for this problem and the design of the chosen flipped voltage follower topology was implemented in schematic and layout. It was subsequently simulated at schematic and extracted parasitics level to verify its functionality and determine its overall performance. Finally, the work done in each block is verified in the context of the whole ADC by top level schematic and extracted layout simulation

    Analog layout design automation: ILP-based analog routers

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    The shrinking design window and high parasitic sensitivity in the advanced technology have imposed special challenges on the analog and radio frequency (RF) integrated circuit design. In this thesis, we propose a new methodology to address such a deficiency based on integer linear programming (ILP) but without compromising the capability of handling any special constraints for the analog routing problems. Distinct from the conventional methods, our algorithm utilizes adaptive resolutions for various routing regions. For a more congested region, a routing grid with higher resolution is employed, whereas a lower-resolution grid is adopted to a less crowded routing region. Moreover, we strengthen its speciality in handling interconnect width control so as to route the electrical nets based on analog constraints while considering proper interconnect width to address the acute interconnect parasitics, mismatch minimization, and electromigration effects simultaneously. In addition, to tackle the performance degradation due to layout dependent effects (LDEs) and take advantage of optical proximity correction (OPC) for resolution enhancement of subwavelength lithography, in this thesis we have also proposed an innovative LDE-aware analog layout migration scheme, which is equipped with our special routing methodology. The LDE constraints are first identified with aid of a special sensitivity analysis and then satisfied during the layout migration process. Afterwards the electrical nets are routed by an extended OPC-inclusive ILP-based analog router to improve the final layout image fidelity while the routability and analog constraints are respected in the meantime. The experimental results demonstrate the effectiveness and efficiency of our proposed methods in terms of both circuit performance and image quality compared to the previous works

    Circuit Design and Routing For Field Programmable Analog Arrays

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    Accurate, low-cost, rapid-prototyping techniques for analog circuits have been a long awaited dream for analog designers. However, due to the inherent nature of analog system, design automation in analog domain is very difficult to realize, and field programmable analog arrays (FPAA) have not achieved the same success as FPGAs in the digital domain. This results from several factors, including the lack of supporting CAD tools, small circuit density, low speed and significant parasitic effect from the fixed routing wires. These factors are all related to each other, making the design of a high performance FPAA a multi-dimension problem. Among others, a critical reason behind these difficulties is the non-ideal programming technology, which contributes a large portion of parasitics into the sensitive analog system, thus degrades the system performance. This work is trying to attack these difficulties with development of a laser field programmable analog array (LFPAA). There are two parts of work involved, routing for FPAA and analog IC building block design. To facilitate the router development and provide a platform for FPAA application development, a generic arrayed based FPAA architecture and a flexible CAB topology were proposed. The routing algorithm was based on a modified and improved pathfinder negotiated routing algorithm, and was implemented in C for a prototype FPAA. The parasitic constraints for performance analog routing were also investigated and solutions were proposed. In the area of analog circuit design, a novel differential difference op amp was invented as the core building block. Two bandgap circuits including a low voltage version were developed to generate a stable reference voltage for the FPAA. Based on the proposed FPAA architecture, several application examples were demonstrated. The results show the flexible functionality of the FPAA. Moreover, various laser Makelink test structures were studied on different CMOS processes and BiCMOS copper process. Laser Makelink proves to be a powerful programming technology for analog IC design. A novel laser Makelink trimming method was invented to reduce the op amp offset. The application of using laser Makelink to reconfigure the analog circuit blocks was presented

    Low-power high-performance SAR ADC with redundancy and digital background calibration

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    Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2013.This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections.Cataloged from student-submitted PDF version of thesis.Includes bibliographical references (p. 195-199).As technology scales, the improved speed and energy eciency make the successive- approximation-register (SAR) architecture an attractive alternative for applications that require high-speed and high-accuracy analog-to-digital converters (ADCs). In SAR ADCs, the key linearity and speed limiting factors are capacitor mismatch and incomplete digital-to-analog converter (DAC)/reference voltage settling. In this the- sis, a sub-radix-2 SAR ADC is presented with several new contributions. The main contributions include investigation of using digital error correction (redundancy) in SAR ADCs for dynamic error correction and speed improvement, development of two new calibration algorithms to digitally correct for manufacturing mismatches, design of new architecture to incorporate redundancy within the architecture itself while achieving 94% better energy eciency compared to conventional switching algorithm, development of a new capacitor DAC structure to improve the SNR by four times with improved matching, joint design of the analog and digital circuits to create an asynchronous platform in order to reach the targeted performance, and analysis of key circuit blocks to enable the design to meet noise, power and timing requirements. The design is fabricated in standard 1P9M 65nm CMOS technology with 1.2V supply. The active die area is 0.083mmÂČ with full rail-to-rail input swing of 2.4V p-p . A 67.4dB SNDR, 78.1dB SFDR, +1.0/-0.9 LSB₁₂ INL and +0.5/-0.7 LSB₁₂ DNL are achieved at 50MS/s at Nyquist rate. The total power consumption, including the estimated calibration and reference power, is 2.1mW, corresponding to 21.9fJ/conv.- step FoM. This ADC achieves the best FoM of any ADCs with greater than 10b ENOB and 10MS/s sampling rate.by Albert Hsu Ting Chang.Ph.D

    LOW POWER AND HIGH SIGNAL TO NOISE RATIO BIO-MEDICAL AFE DESIGN TECHNIQUES

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    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

    RF DAC

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    Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2003.Includes bibliographical references (p. 124-126).Dynamic performance of high speed, high resolution digital-to-analog converters (DACs) is limited by distortion at the data switching instants. Inter-symbol interference (ISI), imperfect timing synchronization and clock jitter are all culprits. A DAC output current controlled by an oscillating waveform is proposed to mitigate the effects of the switching distortion. The oscillating waveform should be a multiple (k*fs) of the sampling frequency (f), where k>l. The waveforms can be aligned so that the data switching occurs in the zero regions of the oscillating output. This makes the DAC insensitive to switch dynamics and jitter. The architecture has the additional benefit of mixing the DAC impulse response energy to a higher frequency. An image of a low IF input signal can therefore be output directly at a high IF or RF frequency for transmit communications applications. A narrow-band sigma-delta DAC with eight unit elements is chosen to demonstrate the radio frequency digital-to-analog converter (RF DAC) concept. A sigma-delta architecture allows the current source transistors to be smaller since mismatch shaping is employed. Smaller current source transistors have a lower drain capacitance, allowing large high frequency output impedance to be achieved without an extra cascode transistor. Elimination of the cascode reduces transistor headroom requirements and allows the DAC to be built with a 1.8V supply. The RF DAC prototype is targeted to GSM transmit specifications and implemented in 0.1 8ptm CMOS technology. Measured single-tone SFDR is -75dBc, SNR is 52dB, and IMD3 is -70.8dBc over a 17.5MHz bandwidth centered at 942.5MHz. Measured SNR has the predicted dependence on the phase alignment of the data clock and oscillating pulse.by Susan Luschas.Ph.D

    Power Management Circuits for Front-End ASICs Employed in High Energy Physics Applications

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    The instrumentation of radiation detectors for high energy physics calls for the development of very low-noise application-specific integrated-circuits and demanding system-level design strategies, with a particular focus on the minimisation of inter-ference noise from power anagement circuitry. On the other hand, the aggressive pixelisation of sensors and associated front-end electronics, and the high radiation exposure at the innermost tracking and vertex detectors, requires radiation-aware design and radiation-tolerant deep sub-micron CMOS technologies. This thesis explores circuit design techniques towards radiation tolerant power management integrated circuits, targeting applications on particle detectors and monitoring of accelerator-based experiments, aerospace and nuclear applications. It addresses advantages and caveats of commonly used radiation-hard layout techniques, which often employ Enclosed Layout or H-shaped transistors, in respect to the use of linear transistors. Radiation tolerant designs for bandgap circuits are discussed, and two different topologies were explored. A low quiescent current bandgap for sub-1 V CMOS circuits is proposed, where the use of diode-connected MOSFETs in weak-inversion is explored in order to increase its radiation tolerance. An any-load stable LDO architecture is proposed, and three versions of the design using different layout techniques were implemented and characterised. In addition, a switched DC-DC Buck converter is also studied. For reasons concerning testability and silicon area, the controller of the Buck converter is on-chip, while the inductance and the power transistors are left on-board. A prototype test chip with power management IP blocks was fabricated, using a TSMC 65 nm CMOS technology. The chip features Linear, ELT and H-shape LDO designs, bandgap circuits and a Buck DC-DC converter. We discuss the design, layout and test results of the prototype. The specifications in terms of voltage range and output current capability are based on the requirements set for the integrated on-detector electronics of the new CGEM-IT tracker for the BESIII detector. The thesis discusses the fundamental aspects of the proposed on-detector electronics and provides an in-depth depiction of the front-end design for the readout ASIC

    DIGITALLY ASSISTED TECHNIQUES FOR NYQUIST RATE ANALOG-to-DIGITAL CONVERTERS

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    With the advance of technology and rapid growth of digital systems, low power high speed analog-to-digital converters with great accuracy are in demand. To achieve high effective number of bits Analog-to-Digital Converter(ADC) calibration as a time consuming process is a potential bottleneck for designs. This dissertation presentsa fully digital background calibration algorithm for a 7-bit redundant flash ADC using split structure and look-up table based correction. Redundant comparators are used in the flash ADC design of this work in order to tolerate large offset voltages while minimizing signal input capacitance. The split ADC structure helps by eliminating the unknown input signal from the calibration path. The flash ADC has been designed in 180nm IBM CMOS technology and fabricated through MOSIS. This work was supported by Analog Devices, Wilmington,MA. While much research on ADC design has concentrated on increasing resolution and sample rate, there are many applications (e.g. biomedical devices and sensor networks) that do not require high performance but do require low power energy efficient ADCs. This dissertation also explores on design of a low quiescent current 100kSps Successive Approximation (SAR) ADC that has been used as an error detection ADC for an automotive application in 350nm CD (CMOS-DMOS) technology. This work was supported by ON Semiconductor Corp, East Greenwich,RI

    Development of the readout electronics for the high luminosity upgrade of the CMS outer strip tracker

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    The High-luminosity upgrade of the LHC will deliver the dramatic increase in luminosity required for precision measurements and to probe Beyond the Standard Model theories. At the same time, it will present unprecedented challenges in terms of pileup and radiation degradation. The CMS experiment is set for an extensive upgrade campaign, which includes the replacement of the current Tracker with another all-silicon detector with improved performance and reduced mass. One of the most ambitious aspects of the future Tracker will be the ability to identify high transverse momentum track candidates at every bunch crossing and with very low latency, in order to include tracking information at the L1 hardware trigger stage, a critical and effective step to achieve triggers with high purity and low threshold. This thesis presents the development and the testing of the CMS Binary Chip 2 (CBC2), a prototype Application Specific Integrated Circuit (ASIC) for the binary front-end readout of silicon strip detectors modules in the Outer Tracker, which also integrates the logic necessary to identify high transverse momentum candidates by correlating hits from two silicon strip detectors, separated by a few millimetres. The design exploits the relation between the transverse momentum and the curvature in the trajectory of charged particles subject to the large magnetic field of CMS. The logic which follows the analogue amplification and binary conversion rejects clusters wider than a programmable maximum number of adjacent strips, compensates for the geometrical offset in the alignment of the module, and correlates the hits between the two sensor layers. Data are stored in a memory buffer before being transferred to an additional buffer stage and being serially read-out upon receipt of a Level 1 trigger. The CBC2 has been subject to extensive testing since its production in January 2013: this work reports the results of electrical characterization, of the total ionizing dose irradiation tests, and the performance of a prototype module instrumented with CBC2 in realistic conditions in a beam test. The latter is the first experimental demonstration of the Pt-selection principle central to the future of CMS. Several total-ionizing-dose tests highlighted no functional issue, but observed significant excess static current for doses <1 Mrad. The source of the excess was traced to static leakage current in the memory pipeline, and is believed to be a consequence of the high instantaneous dose delivered by the x-ray setup. Nevertheless, a new SRAM layout aimed at removing the leakage path was proposed for the CBC3. The results of single event upset testing of the chip are also reported, two of the three distinct memory circuits used in the chip were proven to meet the expected robustness, while the third will be replaced in the next iteration of the chip. Finally, the next version of the ASIC is presented, highlighting the additional features of the final prototype, such as half-strip resolution, additional trigger logic functionality, longer trigger latency and higher rate, and fully synchronous stub readout.Open Acces
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