A 1.67 pJ/Conversion-step 8-bit SAR-Flash ADC Architecture in 90-nm CMOS Technology

A novice advanced architecture of 8-bit analog todigital converter is introduced and analyzed in this work. Thestructure of proposed ADC is based on the sub-ranging ADCarchitecture in which a 4-bit resolution flash-ADC is utilized. Theproposed ADC architecture is designed by employing a comparatorwhich is equipped with common mode current feedback andgain boosting technique (CMFD-GB) and a residue amplifier. Theproposed 8 bits ADC structure can achieve the speed of 140 megasamplesper second. The proposed ADC architecture is designedat a resolution of 8 bits at 10 MHz sampling frequency. DNL andINL values of the proposed design are -0.94/1.22 and -1.19/1.19respectively. The ADC design dissipates a power of 1.24 mWwith the conversion speed of 0.98 ns. The magnitude of SFDRand SNR from the simulations at Nyquist input is 39.77 and 35.62decibel respectively. Simulations are performed on a SPICE basedtool in 90 nm CMOS technology. The comparison shows betterperformance for the proposed ADC design in comparison toother ADC architectures regarding speed, resolution and powerconsumption

A 1.67 pJ/Conversion-step 8-bit SAR-Flash ADC Architecture in 90-nm CMOS Technology

A novice advanced architecture of 8-bit analog todigital converter is introduced and analyzed in this work. Thestructure of proposed ADC is based on the sub-ranging ADCarchitecture in which a 4-bit resolution flash-ADC is utilized. Theproposed ADC architecture is designed by employing a comparatorwhich is equipped with common mode current feedback andgain boosting technique (CMFD-GB) and a residue amplifier. Theproposed 8 bits ADC structure can achieve the speed of 140 megasamplesper second. The proposed ADC architecture is designedat a resolution of 8 bits at 10 MHz sampling frequency. DNL andINL values of the proposed design are -0.94/1.22 and -1.19/1.19respectively. The ADC design dissipates a power of 1.24 mWwith the conversion speed of 0.98 ns. The magnitude of SFDRand SNR from the simulations at Nyquist input is 39.77 and 35.62decibel respectively. Simulations are performed on a SPICE basedtool in 90 nm CMOS technology. The comparison shows betterperformance for the proposed ADC design in comparison toother ADC architectures regarding speed, resolution and powerconsumption

Time-based, Low-power, Low-offset 5-bit 1 GS/s Flash ADC Design in 65nm CMOS Technology

Low-power, medium resolution, high-speed analog-to-digital converters (ADCs) have always been important block which have abundant applications such as digital signal processors (DSP), imaging sensors, environmental and biomedical monitoring devices. This study presents a low power Flash ADC designed in nanometer complementary metal-oxide semiconductors (CMOS) technology. Time analysis on the output delay of the comparators helps to generate one more bit. The proposed technique reduced the power consumption and chip area substantially in comparison to the previous state-of-the-art work. The proposed ADC was developed in TSMC 65nm CMOS technology. The offset cancellation technique was embedded in the proposed comparator to decrement the static offset of the comparator. Moreover, one more bit was generated without using extra comparators. The proposed ADC achieved 4.1 bits ENOB at input Nyquist frequency. The simulated differential and integral non-linearity static tests were equal to +0.26/-0.17 and +0.22/-0.15, respectively. The ADC consumed 7.7 mW at 1 GHz sampling frequency, achieving 415 fJ/Convstep Figure of Merit (FoM)

Design and Implementation of a Novel Flash ADC for Ultra Wide Band Applications

This dissertation presents a design and implementation of a novel flash ADC architecture for ultra wide band applications. The advancement in wireless technology takes us in to a world without wires. Most of the wireless communication systems use digital signal processing to transmit as well as receive the information. The real world signals are analog. Due to the processing complexity of the analog signal, it is converted to digital form so that processing becomes easier. The development in the digital signal processor field is rapid due to the advancement in the integrated circuit technology over the last decade. Therefore, analog-to -digital converter acts as an interface in between analog signal and digital signal processing systems. The continuous speed enhancement of the wireless communication systems brings out huge demands in speed and power specifications of high-speed low-resolution analog-to -digital converters. Even though wired technology is a primary mode of communication, the quality and efficiency of the wireless technology allows us to apply to biomedical applications, in home services and even to radar applications. These applications are highly relying on wireless technology to send and receive information at high speed with great accuracy. Ultra Wideband (UWB) technology is the best method to these applications. A UWB signal has a bandwidth of minimum 500MHz or a fractional bandwidth of 25 percentage of its centre frequency. The two different technology standards that are used in UWB are multiband orthogonal frequency division multiplexing ultra wideband technology (MB-OFDM) and carrier free direct sequence ultra wideband technology (DS-UWB). ADC is the core of any UWB receiver. Generally a high speed flash ADC is used in DS-UWB receiver. Two different flash ADC architectures are proposed in this thesis for DS-UWB applications. The first design is a high speed five bit flash ADC architecture with a sampling rate of 5 GS/s. The design is verified using CADENCE tool with CMOS 90 nm technology. The total power dissipation of the ADC is 8.381 mW from power supply of 1.2 V. The die area of the proposed flash ADC is 186 μm × 210 μm (0.039 mm2). The proposed flash ADC is analysed and compared with other papers in the literature having same resolution and it is concluded that it has the highest speed of operation with medium power dissipation. iii The second design is a reconfigurable five bit flash ADC architecture with a sampling rate of 1.25 GS/s. The design is verified using CADENCE tool with UMC 180 nm technology. The total power dissipation of the ADC is 11.71 mW from power supply of 1.8 V. The die area of the implementation is 432 μm × 720 μm (0.31104 mm2). The chip tape out of the proposed reconfigurable flash ADC is made for fabrication

Digital Background Self-Calibration Technique for Compensating Transition Offsets in Reference-less Flash ADCs

This Dissertation focusses on proving that background calibration using adaptive algorithms are low-cost, stable and effective methods for obtaining high accuracy in flash A/D converters. An integrated reference-less 3-bit flash ADC circuit has been successfully designed and taped out in UMC 180 nm CMOS technology in order to prove the efficiency of our proposed background calibration. References for ADC transitions have been virtually implemented built-in in the comparators dynamic-latch topology by a controlled mismatch added to each comparator input front-end. An external very simple DAC block (calibration bank) allows control the quantity of mismatch added in each comparator front-end and, therefore, compensate the offset of its effective transition with respect to the nominal value. In order to assist to the estimation of the offset of the prototype comparators, an auxiliary A/D converter with higher resolution and lower conversion speed than the flash ADC is used: a 6-bit capacitive-DAC SAR type. Special care in synchronization of analogue sampling instant in both ADCs has been taken into account. In this thesis, a criterion to identify the optimum parameters of the flash ADC design with adaptive background calibration has been set. With this criterion, the best choice for dynamic latch architecture, calibration bank resolution and flash ADC resolution are selected. The performance of the calibration algorithm have been tested, providing great programmability to the digital processor that implements the algorithm, allowing to choose the algorithm limits, accuracy and quantization errors in the arithmetic. Further, systematic controlled offset can be forced in the comparators of the flash ADC in order to have a more exhaustive test of calibration

Design of Energy-Efficient A/D Converters with Partial Embedded Equalization for High-Speed Wireline Receiver Applications

As the data rates of wireline communication links increases, channel impairments such as skin effect, dielectric loss, fiber dispersion, reflections and cross-talk become more pronounced. This warrants more interest in analog-to-digital converter (ADC)-based serial link receivers, as they allow for more complex and flexible back-end digital signal processing (DSP) relative to binary or mixed-signal receivers. Utilizing this back-end DSP allows for complex digital equalization and more bandwidth-efficient modulation schemes, while also displaying reduced process/voltage/temperature (PVT) sensitivity. Furthermore, these architectures offer straightforward design translation and can directly leverage the area and power scaling offered by new CMOS technology nodes. However, the power consumption of the ADC front-end and subsequent digital signal processing is a major issue. Embedding partial equalization inside the front-end ADC can potentially result in lowering the complexity of back-end DSP and/or decreasing the ADC resolution requirement, which results in a more energy-effcient receiver. This dissertation presents efficient implementations for multi-GS/s time-interleaved ADCs with partial embedded equalization. First prototype details a 6b 1.6GS/s ADC with a novel embedded redundant-cycle 1-tap DFE structure in 90nm CMOS. The other two prototypes explain more complex 6b 10GS/s ADCs with efficiently embedded feed-forward equalization (FFE) and decision feedback equalization (DFE) in 65nm CMOS. Leveraging a time-interleaved successive approximation ADC architecture, new structures for embedded DFE and FFE are proposed with low power/area overhead. Measurement results over FR4 channels verify the effectiveness of proposed embedded equalization schemes. The comparison of fabricated prototypes against state-of-the-art general-purpose ADCs at similar speed/resolution range shows comparable performances, while the proposed architectures include embedded equalization as well

Low power encoder and comparator design of 5-bit flash ADC

The present work of the thesis is divided into two parts, first is design of a low power encoder and second is low power latched comparator design. In this low power encoding scheme proposed for 4GS/s 5 bit flash analog to digital converter. The demanding issues in the design of a low power flash ADC is the design of thermometer code to binary code. An encoder in this thesis converts the thermo-meter code into binary code without any intermediate stage using dynamic CMOS logic. To decrease the power consumption of the Flash ADC, the implementation of encoder and comparator is done using dynamic CMOS logic. The proposed encoder in this thesis is designed using 90nm technology at 1.2V DC voltage source using CADENCE tool. The simulation results of 5-bit Flash ADC block is shown for a sampling frequency up to 4GHz and at 4GHz the encoder circuit showing the average power dissipation of the encoder block is 1.833 µW.The other part of the present work is the design of low power comparator for the 5-bit flash ADC. Dynamic latch comparator has been designed in order to reduce power dissipation, delays etc. The different parts of the dynamic latch comparator like: pre-amplifier, dynamic latch, and output buffer are implemented on CADENCE tool with 1.2 V power supply. The simulation results shown for a sampling frequency of 5 GHz and the average power dissipation of the proposed comparator is 69.09 µW. The physical layout of the encoder and comparator has been drawn using CADENCE VIRTUSO LAYOUT EDITOR. The DRC errors has been removed and the layout has been matched with the schematics

Design of High-Speed Power-Efficient A/D Converters for Wireline ADC-Based Receiver Applications

Serial input/output (I/O) data rates are increasing in order to support the explosion in network traffic driven by big data applications such as the Internet of Things (IoT), cloud computing and etc. As the high-speed data symbol times shrink, this results in an increased amount of inter-symbol interference (ISI) for transmission over both severe low-pass electrical channels and dispersive optical channels. This necessitates increased equalization complexity and consideration of advanced modulation schemes, such as four-level pulse amplitude modulation (PAM-4). Serial links which utilize an analog-to-digital converter (ADC) receiver front-end offer a potential solution, as they enable more powerful and flexible digital signal processing (DSP) for equalization and symbol detection and can easily support advanced modulation schemes. Moreover, the DSP back-end provides robustness to process, voltage, and temperature (PVT) variations, benefits from improved area and power with CMOS technology scaling and offers easy design transfer between different technology nodes and thus improved time-to-market. However, ADC-based receivers generally consume higher power relative to their mixed-signal counterparts because of the significant power consumed by conventional multi-GS/s ADC implementations. This motivates exploration of energy-efficient ADC designs with moderate resolution and very high sampling rates to support data rates at or above 50Gb/s. This dissertation presents two power-efficient designs of ≥25GS/s time-interleaved ADCs for ADC-based wireline receivers. The first prototype includes the implementation of a 6b 25GS/s time-interleaved multi-bit search ADC in 65nm CMOS with a soft-decision selection algorithm that provides redundancy for relaxed track-and-hold (T/H) settling and improved metastability tolerance, achieving a figure-of-merit (FoM) of 143fJ/conversion step and 1.76pJ/bit for a PAM-4 receiver design. The second prototype features the design of a 52Gb/s PAM-4 ADC-based receiver in 65nm CMOS, where the front-end consists of a 4-stage continuous-time linear equalizer (CTLE)/variable gain amplifier (VGA) and a 6b 26GS/s time-interleaved SAR ADC with a comparator-assisted 2b/stage structure for reduced digital-to-analog converter (DAC) complexity and a 3-tap embedded feed-forward equalizer (FFE) for relaxed ADC resolution requirement. The receiver front-end achieves an efficiency of 4.53bJ/bit, while compensating for up to 31dB loss with DSP and no transmitter (TX) equalization

Multi-gigabit CMOS analog-to-digital converter and mixed-signal demodulator for low-power millimeter-wave communication systems

The objective of the research is to develop high-speed ADCs and mixed-signal demodulator for multi-gigabit communication systems using millimeter-wave frequency bands in standard CMOS technology. With rapid advancements in semiconductor technologies, mobile communication devices have become more versatile, portable, and inexpensive over the last few decades. However, plagued by the short lifetime of batteries, low power consumption has become an extremely important specification in developing mobile communication devices. The ever-expanding demand of consumers to access and share information ubiquitously at faster speeds requires higher throughputs, increased signal-processing functionalities at lower power and lower costs. In today’s technology, high-speed signal processing and data converters are incorporated in almost all modern multi-gigabit communication systems. They are key enabling technologies for scalable digital design and implementation of baseband signal processors. Ultimately, the merits of a high performance mixed-signal receiver, such as data rate, sensitivity, signal dynamic range, bit-error rate, and power consumption, are directly related to the quality of the embedded ADCs. Therefore, this dissertation focuses on the analysis and design of high-speed ADCs and a novel broadband mixed-signal demodulator with a fully-integrated DSP composed of low-cost CMOS circuitry. The proposed system features a novel dual-mode solution to demodulate multi-gigabit BPSK and ASK signals. This approach reduces the resolution requirement of high-speed ADCs, while dramatically reducing its power consumption for multi-gigabit wireless communication systems.PhDGee-Kung Chang - Committee Chair; Chang-Ho Lee - Committee Member; Geoffrey Ye Li - Committee Member; Paul A. Kohl - Committee Member; Shyh-Chiang Shen - Committee Membe