4,130 research outputs found
High-speed Low-voltage CMOS Flash Analog-to-Digital Converter for Wideband Communication System-on-a-Chip
With higher-level integration driven by increasingly complex digital systems and downscaling CMOS processes available, system-on-a-chip (SoC) is an emerging technology of low power, high cost effectiveness and high reliability and is exceedingly attractive for applications in high-speed data conversion wireless and wideband communication systems. This research presents a novel ADC comparator design methodology; the speed and performance of which is not restricted by the supply voltage reduction and device linearity deterioration in scaling-down CMOS processes. By developing a dynamic offset suppression technique and a circuit optimization method, the comparator can achieve a 3 dB frequency of 2 GHz in 130 nanometer (nm) CMOS process. Combining this new comparator design and a proposed pipelined thermometer-Gray- binary encoder designed by the DCVSPG logic, a high-speed, low-voltage clocked-digital- comparator (CDC) pipelined CMOS flash ADC architecture is proposed for wideband communication SoC. This architecture has advantages of small silicon area, low power, and low cost. Three CDC-based pipelined CMOS flash ADCs were implemented in 130 nm CMOS process and their experimental results are reported: 1. 4-b, 2.5-GSPS ADC: SFDR of 21.48-dB, SNDR of 15.99-dB, ENOB of 2.4-b, ERBW of 1-GHz, power of 7.9-mW, and area of 0.022-mm2. 2. 4-b, 4-GSPS ADC: SFDR of 25-dB, SNDR of 18.6-dB, ENOB of 2.8-b, ERBW of 2-GHz, power of 11-mW. 3. 6-b, 4-GSPS ADC: SFDR of 48-dB at a signal frequency of 11.72-MHz, SNDR of 34.43-dB, ENOB of 5.4-b, power of 28-mW. An application of the proposed CDC-based pipelined CMOS flash ADC is 1-GHz bandwidth, 2.5-GSPS digital receiver on a chip. To verify the performance of the receiver, a mixed-signal block-level simulation and verification flow was built in Cadence AMS integrated platform. The verification results of the digital receiver using a 4-b 2.5-GSPS CDC-based pipelined CMOS ADC, a 256-point, 12-point kernel function FFT and a frequency detection logic show that two tone signals up to 1125 MHz can be detected and discriminated. A notable contribution of this research is that the proposed ADC architecture and the comparator design with dynamic offset suppression and optimization are extremely suitable for future VDSM CMOS processes and make all-digital receiver SoC design practical
Characterization & Comparative Analysis of High Speed CMOS Comparator for Pipelined ADC
In todays high speed low power era, there is an
increasing demand of a High Speed Comparator for ADC, DAC
and various other applications in an analog and digital domain.
This paper describes and analyzes five different architecture for
low power and high speed comparators. In this paper, authors
have analyzed and simulated the designs using TSMC 0.35 m
CMOS technology with 2.0V for preamplifier based comparator
and 1.8V power supply for dynamic comparators. The simulation
results allow the circuit designer to fully explore the tradeoffs
in comparator design, such as offset voltage, speed, power and
area for Pipelined A/D Converters. Prelayout and postlayout
simulations are carried out using Eldo SPICE tool and layout
using IC Station
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Design and implementation of Radix-3/Radix-2 based novel hybrid SAR ADC in scaled CMOS technologies
This thesis focuses on low power and high speed design techniques for successive
approximation register (SAR) analog-to-digital converters (ADCs) in nanoscale
CMOS technologies. SAR ADCs’ speed is limited by the number of bits of
resolution. An N-bit conventional SAR ADC takes N conversion cycles. To speed
up the conversion process, we introduce a radix-3 SAR ADC which can compute
1:6 bits per cycle. To our knowledge, it is the first fully programmable and efficiently
hardware controlled radix-3 SAR ADC. We had to use two comparators per
cycle due to ADC architecture and we proposed a simple calibration scheme for
the comparators. Also, as the architecture of the DAC array is completely different
from the architecture of conventional radix-2 SAR ADC’s DAC arrays, we came up
with an algorithm for calibration of capacitors of the DAC.
Low power SAR ADCs face two major challenges especially at high resolutions:
(1) increased comparator power to suppress the noise, and (2) increased
DAC switching energy due to the large DAC size. Due to our proposed architecture,the radix-3 SAR ADC uses two comparators per cycle and two differential DACs.
To improve the comparator’s power efficiency, an efficient and low cost calibration
technique has been introduced. It allows a low power and noisy comparator to
achieve high signal-to-noise ratio (SNR).
To improve the DAC switching energy, we introduced a radix-3/radix-2
based novel hybrid SAR ADC. We use two single ended DACs for radix-3 SAR
ADC and these two single ended DACs can be used as one differential DAC for
radix-2 SAR ADC. So, overall, we only have a single DAC as conventional radix-
2 SAR ADC. In addition, a monotonic switching technique is adopted for radix-2
search to reduce the DAC capacitor size and hence, to reduce switching power. It
can reduce the total number of unit capacitors by four times. Our proposed hybrid
SAR ADC can achieve less DAC energy compared to radix-3 and radix-2 SAR
ADCs. Also, to utilize technology scaling, we used the minimum capacitor size
allowed by thermal noise limitations. To achieve high resolution, we introduced
calibration algorithm for the DAC array.
As mentioned earlier, the radix-3 SAR ADC offers higher power than conventional
radix-2 SAR ADC because of simultaneous use of two comparators. In
the proposed hybrid SAR ADC, we will be using radix-3 search for first few MSB
bits. So, the resolution required for radix-3 comparators are much larger than the
LSB value of 10-bit ADC. By implementing calibration of comparators, we can
use low power, high input referred offset and high speed comparators for radix-3
search. Radix-2 search will be used for rest of the bits and the resolution of the
radix-2 comparator has to be less than the required LSB value. So, a high power, low input referred offset and high speed comparator is used for radix-2 search.
Also, we introduced clock gating for comparators. So, radix-3 comparators will not
toggle during radix-2 search and the radix-2 comparators will be inactive during
radix-3 search. By using the aforementioned techniques, the overall comparator
power is definitely less than a radix-3 SAR ADC and comparable to a conventional
radix-2 SAR ADC.
A prototype radix-3/radix-2 based hybrid SAR ADC with the proposed
technique is designed and fabricated in 40nm CMOS technology. It achieves an
SNDR of 56.9 dB and consumes only 0.38 mW power at 30MS/s, leading to a
Walden figure of merit of 21.5 fJ/conv-step.Electrical and Computer Engineerin
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Energy-efficient data converter design in scaled CMOS technology
Data converters bridge the physical and digital worlds. They have been the crucial building blocks in modern electronic systems, and are expected to have a growing significance in the booming era of Internet-of-Things (IoT) and 5G communications. The applications raise energy-efficiency requirements for both low-speed and high-speed converters since they are widely deployed in wireless sensor nodes and portable devices. To explore the solutions, the author worked on three directions: 1) techniques to improve the efficiency of the low-speed converters including the comparator; 2) techniques to develop high-speed data converters including the reference stabilization; 3) new architecture to improve the efficiency of the capacitance-to-digital converter (CDC). In the first part, a power-efficient 10-bit SAR ADC featured with a gain-boosted dynamic comparator is presented. In energy-constrained applications, the converter is usually supplied with low supply voltage (e.g., 0.3 V-0.5 V), which reduces the comparator pre-amplifier (pre-amp) gain and results in higher noise. A novel comparator topology with a dynamic common-gate stage is proposed to increase the pre-amplification gain, thereby reducing noise and offset. Besides, statistical estimation and loading switching techniques are combined to further improve energy efficiency. A 40-nm CMOS prototype achieves a Walden FoM of 1.5 fJ/conversion-step while operating at 100-kS/s from a 0.5-V supply. To further improve the energy-efficiency of the comparator, a novel dynamic pre-amp is proposed. By using an inverter-based input pair powered by a floating reservoir capacitor, the pre-amp realizes both current reuse and dynamic bias, thereby significantly boosting g [subscript m] /I [subscript D] and reducing noise. Moreover, it greatly reduces the influence of the input common-mode (CM) voltage on the comparator performance, including noise, offset, and delay. A prototype comparator in 180-nm achieves 46-μV input-referred noise while consuming only 1 pJ per comparison under 1.2-V supply, which represents greater than 7 times energy efficiency boost compared to that of a Strong-Arm (SA) latch. The second part of this dissertation focuses on high-speed data converter techniques. A 10-bit high-speed two-stage loop-unrolled SAR ADC is presented. To reduce the SAR logic delay and power, each bit uses a dedicated comparator to store its output and generate an asynchronous clock for the next comparison. To suppress the comparator offset mismatch induced non-linearity, a shared pre-amp are employed in the second fine stage, which is implemented by a dynamic latch to avoid static power consumption. The prototype ADC in 40-nm CMOS achieves 55-dB peak SNDR at 200-MS/s sampling rate without any calibration. A key limiting factor for the SAR ADC to simultaneously achieve high speed and high resolution is the reference ripple settling problem caused by DAC switching. Unlike prior techniques that aim to minimize the reference ripple which requires large reference buffer power or on-chip decoupling capacitance area, this work proposes a new perspective: it provides an extra path for the full-sized reference ripple to couple to the comparator but with an opposite polarity, so that the effect of the reference ripple is canceled out, thus ensuring an accurate conversion result. The prototype 10-bit 120-MS/s SAR ADC is fabricated in 40-nm CMOS process and achieves an SNDR of 55 dB with only 3 pF reference decoupling capacitor. Finally, this dissertation also presents the design of an incremental time-domain two-step CDC. Unlike the classic two-step CDC, this work replaces the OTA-based active-RC integrator with a VCO-based integrator and performs time domain (TD) ΔΣ modulation. The VCO is mostly digital and consumes low power. Featuring the infinite DC gain in phase domain and intrinsic spatial phase quantization, this TDΔΣ enables a CDC design, achieving 85-dB SQNR by having only a 4-bit quantizer, a 1st-order loop and a low OSR of 15. The prototype fabricated in 40-nm CMOS achieves a resolution of 0.29 fF while dissipating only 0.083 nJ per conversion, which improves the energy efficiency by greater than 2 times comparing to that of state-of-the-art CDCsElectrical and Computer Engineerin
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Noise shaping Asynchronous SAR ADC based time to digital converter
Time-to-digital converters (TDCs) are key elements for the digitization of timing information in modern mixed-signal circuits such as digital PLLs, DLLs, ADCs, and on-chip jitter-monitoring circuits. Especially, high-resolution TDCs are increasingly employed in on-chip timing tests, such as jitter and clock skew measurements, as advanced fabrication technologies allow fine on-chip time resolutions. Its main purpose is to quantize the time interval of a pulse signal or the time interval between the rising edges of two clock signals. Similarly to ADCs, the performance of TDCs are also primarily characterized by Resolution, Sampling Rate, FOM, SNDR, Dynamic Range and DNL/INL. This work proposes and demonstrates 2nd order noise shaping Asynchronous SAR ADC based TDC architecture with highest resolution of 0.25 ps among current state of art designs with respect to post-layout simulation results. This circuit is a combination of low power/High Resolution 2nd Order Noise Shaped Asynchronous SAR ADC backend with simple Time to Amplitude converter (TAC) front-end and is implemented in 40nm CMOS technology. Additionally, special emphasis is given on the discussion on various current state of art TDC architectures.Electrical and Computer Engineerin
Offset-calibration with Time-Domain Comparators Using Inversion-mode Varactors
This paper presents a differential time-domain comparator formed by two voltage controlled delay lines, one per input terminal, and a binary phase detector for comparison solving. The propagation delay through the respective lines can be adjusted with a set of digitally-controlled inversion-mode varactors. These varactors provide tuning capabilities to the comparator; feature which can be exploited for offset calibration. This is demonstrated with the implementation of a differential 10-bit SAR-ADC. The design, fabricated in a 0.18μm CMOS process, includes an automatic mechanism for adjusting the capacitance of the varactors in order to calibrate the offset of the whole converter. Correct functionality was measured in all samples.Ministerio de Economía y Competitividad TEC2016-80923-POffice of Naval Research (USA) N0001414135
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