Energy Efficient Pipeline ADCs Using Ring Amplifiers

Pipeline ADCs require accurate amplification. Traditionally, an operational transconductance amplifier (OTA) configured as a switched-capacitor (SC) amplifier performs such amplification. However, traditional OTAs limit the power efficiency of ADCs since they require high quiescent current for slewing and bandwidth. In addition, it is difficult to design low-voltage OTAs in modern, scaled CMOS. The ring amplifier is an energy efficient and high output swing alternative to an OTA for SC circuits which is basically a three-stage inverter amplifier stabilized in a feedback configuration. However, the conventional ring amplifier requires external biases, which makes the ring amplifier less practical when we consider process, supply voltage, and temperature (PVT) variation. In this dissertation, three types of innovative ring amplifiers are presented and verified with state-of-the-art energy efficient pipeline ADCs. These new ring amplifiers overcome the limitations of the conventional ring amplifier and further improve energy efficiency. The first topic of this dissertation is a self-biased ring amplifier that makes the ring amplifier more practical and power efficient, while maintaining the benefits of efficient slew-based charging and an almost rail-to-rail output swing. In addition, the ring amplifiers are also used as comparators in the 1.5b sub-ADCs by utilizing the unique characteristics of the ring amplifier. This removes the need for dedicated comparators in sub-ADCs, thus further reducing the power consumption of the ADC. The prototype 10.5b 100 MS/s comparator-less pipeline ADC with the self-biased ring amplifiers has measured SNDR, SNR and SFDR of 56.6 dB (9.11b), 57.5 dB and 64.7 dB, respectively, and consumes 2.46 mW, which results in Walden Figure-of-Merit (FoM) of 46.1 fJ/ conversion∙step. The second topic is a fully-differential ring amplifier, which solves the problems of single-ended ring amplifiers while maintaining the benefits of the single-ended ring amplifiers. This differential ring-amplifier is applied in a 13b 50 MS/s SAR-assisted pipeline ADC. Furthermore, an improved capacitive DAC switching method for the first stage SAR reduces the DAC linearity errors and switching energy. The prototype ADC achieves measured SNDR, SNR and SFDR of 70.9 dB (11.5b), 71.3 dB and 84.6 dB, respectively, and consumes 1 mW. This measured performance is equivalent to Walden and Schreier FoMs of 6.9 fJ/conversion∙step and 174.9 dB, respectively. Finally, a four-stage fully-differential ring amplifier improves the small-signal gain to over 90 dB without compromising speed. In addition, a new auto-zero noise filtering method reduces noise without consuming additional power. This is more area efficient than the conventional auto-zero noise folding reduction technique. A systematic mismatch free SAR CDAC layout method is also presented. The prototype 15b 100 MS/s calibration-free SAR-assisted pipeline ADC using the four-stage ring amplifier achieves 73.2 dB SNDR (11.9b) and 90.4 dB SFDR with a 1.1 V supply. It consumes 2.3 mW resulting in Schreier FoM of 176.6 dB.PHDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttps://deepblue.lib.umich.edu/bitstream/2027.42/138759/1/yonglim_1.pd

A 12b 250 MS/s Pipelined ADC With Virtual Ground Reference Buffers

The virtual ground reference buffer (VGRB) technique is introduced as a means to improve the performance of switched-capacitor circuits. The technique enhances the performance by improving the feedback factor of the op-amp without affecting the signal gain. The bootstrapping action of the level-shifting buffers relaxes key op-amp performance requirements including unity-gain bandwidth, noise, open-loop gain and offset compared with conventional circuits. This reduces the design complexity and the power consumption of op-amp based circuits. Based on this technique, a 12 b pipelined ADC is implemented in 65 nm CMOS that achieves 67.0 dB SNDR at 250 MS/s and consumes 49.7 mW of power from a 1.2 V power supply

Power efficient analog-to-digital converters using both voltage and time domain information

As advanced wired and wireless communication systems attempt to achieve higher performance, the demand for high resolution and wide signal bandwidth in their associated ADCs is strongly increased. Recently, time-domain quantization has drawn attention from its scalability in deep submicron CMOS processes. Furthermore, there are several interesting aspects of time-domain quantizer by processing the signal in time rather than only in voltage domain especially for power efficiency. This research focuses on developing a new architecture for power efficient, high resolution ADCs using both voltage and time domain information. As a first approach, a new ΔƩ ADC based on a noise-shaped two-step integrating quantizer which quantizes the signal in voltage and time domains is presented. Attaining an extra order of noise-shaping from the integrating quantizer, the proposed ΔƩ ADC manifests a second-order noise-shaping with a first-order loop filter. Furthermore, this quantizer provides an 8b uantization in itself, drastically reducing the oversampling requirement. The proposed ADC also incorporates a new feedback DAC topology that alleviates the feedback DAC complexity of a two-step 8b quantizer. The measured results of the prototype ADC implemented in a 0.13μm CMOS demonstrate peak SNDR of 70.7dB (11.5b ENOB) at 8.1mW power, with an 8x OSR at 80MHz sampling frequency. To further improve ADC performance, a Nyquist ADC based on a time-based pipelined TDC is also proposed as a second approach. In this work, a simple V-T conversion scheme with a cheap low gain amplifier in its first stage and a hybrid time-domain quantization stage based on simple charge pump and capacitive DAC in its backend stages, are also proposed to improve ADC linearity and power efficiency. Using voltage and time domain information, the proposed ADC architecture is beneficial for both resolution and power efficiency, with MSBs resolved in voltage domain and LSBs in time domain. The measured results of the prototype ADC implemented in a 0.13μm CMOS demonstrate peak SNDR of 69.3dB (11.2b ENOB) at 6.38mW power and 70MHz sampling frequency. The FOM is 38.2fJ/conversion-step

Improving Accuracy and Energy Efficiency of Pipeline Analog to Digital Converters

Analog-to-Digital converters (ADC) are key building blocks of analog and mixed-signal processing that link the natural world of analog signals and the world of digital processing. This work describes the analysis, design, development and test of novel high-resolution (≥12-bit), moderate speed (10-100MS/s), energy-efficient ADCs. Such ADCs are typically used for communication, imaging and video applications. CMOS process scaling is typically aimed at enabling fast, low-power digital circuits. Scaling leads to lower supply voltages, and to short channel devices with low gain and poor matching between small devices. On the other hand, to process and amplify analog signals analog circuits rely on wide signal swing, large transistor gain and good component matching. Hence, analog circuit performance has lagged far behind digital performance. Analog circuits such as ADCs are therefore nowadays performance bottlenecks in many electronic systems. The pipeline ADC is a popular architecture for implementing ADCs with a wide range of speed and resolution. This work aims to improve the accuracy and energy efficiency of the pipeline architecture by combining it with more accurate or more energy efficient architectures such as Sigma-Delta and Successive-Approximation (SAR). Such novel, hybrid architectures are investigated in this work. In the first design, a new architecture is developed which combines a low-OSR resetting Sigma-Delta modulator architecture with the pipeline architecture. This architecture enhances the accuracy and energy efficiency of the pipeline architecture. A prototype 14-bit 23MS/s ADC, based on this new architecture, is designed and tested. This ADC achieves calibration-free 14-bit linearity, 11.7-bit ENOB and 87dB SFDR while dissipating only 48mW of power. In the second design, new hybrid architecture based on SAR and pipeline architecture is developed. This architecture significantly improves the energy efficiency of the pipeline architecture. A prototype 12-bit 50MS/s ADC is designed based on this new architecture. “Half-gain” and “half-reference” pipeline stages are also introduced in this prototype for the first time to further reduce power dissipation. This ADC dissipates only 3.5mW power.Ph.D.Electrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/76025/1/leechun_1.pd

Low Noise, Jitter Tolerant Continuous-Time Sigma-Delta Modulator

The demand for higher data rates in receivers with carrier aggregation (CA) such as LTE, increases the efforts to integrate large number of wireless services into single receiving path, so it needs to digitize the signal in intermediate or high frequencies. It relaxes most of the front-end blocks but makes the design of ADC very challenging. Solving the bottleneck associated with ADC in receiver architecture is a major focus of many ongoing researches. Recently, continuous time Sigma-Delta analog-to-digital converters (ADCs) are getting more attention due to their inherent filtering properties, lower power consumption and wider input bandwidth. But, it suffers from several non-idealities such as clock jitter and ELD which decrease the ADC performance. This dissertation presents two projects that address CT-ΣΔ modulator non-idealities. One of the projects is a CT- ΣΔ modulator with 10.9 Effective Number of Bits (ENOB) with Gradient Descent (GD) based calibration technique. The GD algorithm is used to extract loop gain transfer function coefficients. A quantization noise reduction technique is then employed to improve the Signal to Quantization Noise Ratio (SQNR) of the modulator using a 7-bit embedded quantizer. An analog fast path feedback topology is proposed which uses an analog differentiator in order to compensate excess loop delay. This approach relaxes the requirements of the amplifier placed in front of the quantizer. The modulator is implemented using a third order loop filter with a feed-forward compensation paths and a 3-bit quantizer in the feedback loop. In order to save power and improve loop linearity a two-stage class-AB amplifier is developed. The prototype modulator is implemented in 0.13μm CMOS technology, which achieves peak Signal to Noise and Distortion Ratio (SNDR) of 67.5dB while consuming total power of 8.5-mW under a 1.2V supply with an over sampling ratio of 10 at 300MHz sampling frequency. The prototype achieves Walden's Figure of Merit (FoM) of 146fJ/step. The second project addresses clock jitter non-ideality in Continuous Time Sigma Delta modulators (CT- ΣΔM), the modulator suffer from performance degradation due to uncertainty in timing of clock at digital-to-analog converter (DAC). This thesis proposes to split the loop filter into two parts, analog and digital part to reduce the sensitivity of feedback DAC to clock jitter. By using the digital first-order filter after the quantizer, the effect of clock jitter is reduced without changing signal transfer function (STF). On the other hand, as one pole of the loop filter is implemented digitally, the power and area are reduced by minimizing active analog elements. Moreover, having more digital blocks in the loop of CT- ΣΔM makes it less sensitive to process, voltage, and temperature variations. We also propose the use of a single DAC with a current divider to implement feedback coefficients instead of two DACs to decrease area and clock routing. The prototype is implemented in TSMC 40 nm technology and occupies 0.06 mm^2 area; the proposed solution consumes 6.9 mW, and operates at 500 MS/s. In a 10 MHz bandwidth, the measured dynamic range (DR), peak signal-to-noise-ratio (SNR), and peak signal-to-noise and distortion (SNDR) ratios in presence of 4.5 ps RMS clock jitter (0.22% clock period) are 75 dB, 68 dB, and 67 dB, respectively. The proposed structure is 10 dB more tolerant to clock jitter when compared to the conventional ΣΔM design for similar loop filter

A highly digital, reconfigurable and voltage scalable SAR ADC

Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2009.Cataloged from PDF version of thesis.Includes bibliographical references (p. 109-112).Micropower sensor networks have a broad range of applications which include military surveillance, environmental monitoring, chemical detection and more recently, medical monitoring systems. Each node of the sensor network requires energy efficient circuits powered off small batteries or harvested energy. In such systems, a single reconfigurable analog-to-digital converter (ADC) is needed to digitize a wide range of signals with varying bandwidth and resolution requirements. This thesis describes the design of an ADC whose power scales exponentially with resolution and linearly with frequency to maximize the system lifetime. The proposed ADC has reconfigurable resolution from 5 to 10-bits and a scalable sample rate from 0 to 1-MS/s. The successive approximation register (SAR) architecture was chosen for its highly digital nature which enables low voltage operation. The supply voltage can be scaled from 1V down to 0.4V such that the ADC maintains a constant energy efficiency across all modes of operation when normalized with respect to sample rate and resolution. A capacitive digital-to -analog converter (DAC) in a split capacitor topology with a sub-DAC is used to minimize the DAC power and area. Top plate switches are used to decouple the MSB capacitors as resolution is scaled to avoid parasitic loading of the DAC. The DAC capacitors are laid out in a common-centroid configuration with edge effects minimized at each resolution mode to improve matching. A fully dynamic latched comparator is used to avoid static bias currents.(cont.) Power gating of the digital logic is used to reduce leakage power at low sample rates. Reconfigurability between single-ended or differential modes enables a power versus performance trade-off. Lastly, programmable sampling duration and internal bootstrapping is used to maintain sampling linearity at low voltages. The ADC has been submitted for fabrication in a low power 65nm digital CMOS process and simulation results are presented.by Marcus Yip.S.M

A 12b 50MS/s fully differential zero-crossing-based ADC without CMFB

As intrinsic device gain and power supply voltages decrease with CMOS technology scaling, it is becoming increasingly challenging for designers of conventional opamp-based switched-capacitor circuits to meet gain and output swing targets, and to ensure stability. Zero-crossing based circuits (ZCBC) are presented as an alternative architecture where each opamp is replaced with a current source and a zero-crossing detector. This changes the dynamics of the system while preserving the functionality. To further improve the robustness of ZCBC designs, we present a 50MS/s, 12b ZCBC pipelined ADC with fully differential signaling and automatic offset compensation