A 10 bit 50 MS/s SAR ADC with partial split capacitor switching scheme in 0.18 μm CMOS

This paper presents a 10 bit successive approximation register (SAR) analog-to-digital converter (ADC) in 0.18 μ m 1P6M CMOS technology with a 1.8 V supply voltage. To improve the conversion speed, a partial split capacitor switching scheme is proposed. By reducing the time constant of the bit cycles, the proposed technique shortens the settling time of a capacitive digital-to-analog converter (DAC). In addition, a new SAR control logic is proposed to reduce loop delay to further enhance the conversion speed. At 1.8 V supply voltage and 50 MS/s the SAR ADC achieves a signal-to-noise and distortion ratio (SNDR) of 57.5 dB and spurious-free dynamic range (SFDR) of 69.3 dB. The power consumption is 2.26 mW and the core die area is 0.096 mm².     

An ll-bit 22-MS/s 0.6 mW SAR ADC with parasitic capacitance compensation

Abstract： This paper presents an l 1-bit 22-MS/s 0.6-mW successive approximation register （SAR） analog-to- digital converter （ADC） using SMIC 65-nm low leakage （LL） CMOS technology with a 1.2 V supply voltage. To reduce the total capacitance and core area the split capacitor architecture is adopted. But in high resolution ADCs the parasitic capacitance in the LSB-side would decrease the linearity of the ADC and it is hard to calibrate. This paper proposes a parasitic capacitance compensation technique to cancel the effect with no calibration circuits. Moreover, dynamic circuits are used to minimize the switching power of the digital logic and also can reduce the latency time. The prototype chip realized an 11-bit SAR ADC fabricated in SMIC 65-nm CMOS technology with a core area of 300 × 200 μm2. It shows a sampling rate of 22 MS/s and low power dissipation of 0.6 mW at a 1.2 V supply voltage. At low input frequency the signal-to-noise-and-distortion ratio （SNDR） is 59.3 dB and the spurious-free dynamic range is 72.2 dB. The peak figure-of-merit is 36.4 fJ/conversion-step.     

一种有效位为11.3比特的14位100兆CMOS流水线型模数转换器

This paper demonstrates a 14-bit 100-MS/s pipelined analog-to-digital converter(ADC) in 0.18μm CMOS process with a 1.8 V supply voltage.A fast foreground digital calibration mechanism is employed to correct capacitor mismatches.The ADC implements an SHA-less 3-bit front-end to reduce the size of the sampled capacitor. The presented ADC achieves a 70.02 dB signal-to-noise distortion ratio(SNDR) and an 87.5 dB spurious-free dynamic range(SFDR) with a 30.7 MHz input signal,while maintaining over 66 dB SNDR and 76 dB SFDR up to 200 MHz input.The power consumption is 543 mW and a total die area of 3 x 4 mm2 is occupied.     

An 8 bit 1 MS/s SAR ADC with 7.72-ENOB

This paper presents a low power 8-bit 1 MS/s SAR ADC with 7.72-bit ENOB. Without an op-amp, an improved segmented capacitor DAC is proposed to reduce the capacitance and the chip area. A dynamic latch comparator with output offset voltage storage technology is used to improve the precision. Adding an extra positive feedback in the latch is to increase the speed. What is more, two pairs of CMOS switches are utilized to eliminate the kickback noise introduced by the latch. The proposed SAR ADC was fabricated in SMIC 0.18 μm CMOS technology. The measured results show that this design achieves an SFDR of 61.8 dB and an ENOB of 7.72 bits, and it consumes 67.5 μ W with the FOM of 312 fJ/conversion-step at 1 MS/s sample under 1.8 V power supply.     

A power-efficient 12-bit analog-to-digital converter with a novel constant-resistance CMOS input sampling switch

Apower-efficient 12-bit40-MS/spipelineanalog-to-digitalconverter（ADC）implementedina0.13 μm CMOS technology is presented. A novel CMOS bootstrapping switch, which offers a constant on-resistance over the entire input signal range, is used at the sample-and-hold front-end to enhance the dynamic performance of the pipelined ADC. By implementing with 2.5-bit-per-stage and a simplified amplifier sharing architecture between two successive pipeline stages, a very competitive power consumption and small die area can be achieved. Meanwhile, the substrate-biasing-effect attenuated T-type switches are introduced to reduce the crosstalk between the two op- amp sharing successive stages. Moreover, a two-stage gain boosted recycling folded cascode （RFC） amplifier with hybrid frequency compensation is developed to further reduce the power consumption and maintain the ADC＇s performance simultaneously. The measured results imply that the ADC achieves a spurious-free dynamic range （SFDR） of 75.7 dB and a signal-to-noise-plus-distortion ratio （SNDR） of 62.74 dB with a 4.3 MHz input signal; the SNDR maintains over 58.25 dB for input signals up to 19.3MHz. The measured differential nonlinearity （DNL） and integral nonlinearity （INL） are -0.43 to ＋0.48 LSB and -1.62 to ＋ 1.89 LSB respectively. The prototype ADC consumes 28.4 mW under a 1.2-V nominal power supply and 40 MHz sampling rate, transferring to a figure- of-merit （FOM） of 0.63 pJ per conversion-step.     

A 1 V 186-μW 50-MS/s 10-bit subrange SAR ADC in 130-nm CMOS process

This paper presents a 10-bit 50-MS/s subrange successive-approximation register (SAR) analog-to-digital converter (ADC) composed of a 4-bit SAR coarse ADC and a 6-bit SAR fine ADC. In the coarse ADC, multi-comparator SAR architecture is used to reduce the digital logic propagation delay, and a traditional asynchronous SAR ADC with monotonic switching method is used as the fine ADC. With that combination, power dissipation also can be much reduced. Meanwhile, a modified SAR control logic is adopted in the fine ADC to speed up the conversion and other techniques, such as splitting capacitors array, are borrowed to reduce the power consumption. Fabricated with 1P8M 130-nm CMOS technology, the proposed SAR ADC achieves 51.6-dB signal to noise and distortion ratio (SNDR) and consumes 186 μ W at 50 MS/s with a 1-V supply, resulting in a figure of merit (FOM) of 12 fJ/conversion-step. The core area is only 0.045 mm².     

基于非线性DAC的高速直接数字频率合成器

This paper presents a high speed ROM-less direct digital frequency synthesizer （DDFS） which has a phase resolution of 32 bits and a magnitude resolution of 10 bits. A 10-bit nonlinear segmented DAC is used in place of the ROM look-up table for phase-to-sine amplitude conversion and the linear DAC in a conventional DDFS. The design procedure for implementing the nonlinear DAC is presented. To ensure high speed, current mode logic （CML） is used. The chip is implemented in Chartered 0.35μm COMS technology with active area of 2.0 × 2.5 mm^2 and total power consumption of 400 mW at a single 3.3 V supply voltage. The maximum operating frequency is 850 MHz at room temperature and 1.0 GHz at 0℃.     

Overview of Energy-Efficient Successive-Approximation Analog-to-Digital Converters： State-of-the-Art and a Design Example

This paper makes a review of state-of-the- arts designs of successive-approximation register analog-to-digital converters （SAR ADCs）. Methods and technique specifications are collected in view of innovative ideas. At the end of this paper, a design example is given to illustrate the procedure to design an SAR ADC. A new method, which extends the width of the internal clock, is also proposed to facilitate different sampling frequencies, which provides more time for the digital-to-analog convert （DAC） and comparator to settle. The 10 bit ADC is simulated in 0.13 μm CMOS process technology. The signal-to-noise and distortion ratio （SNDR） is 54.41 dB at a 10 MHz input with a 50 MS/s sampling rate, and the power is 330 μW.     

A 10 bit 200 MS/s pipeline ADC using loading-balanced architecture in 0.18 μm CMOS

A new loading-balanced architecture for high speed and low power consumption pipeline analog-to-digital converter (ADC) is presented in this paper. The proposed ADC uses SHA-less, op-amp and capacitor-sharing technique, capacitor-scaling scheme to reduce the die area and power consumption. A new capacitor-sharing scheme was proposed to cancel the extra reset phase of the feedback capacitors. The non-standard inter-stage gain increases the feedback factor of the first stage and makes it equal to the second stage, by which, the load capacitor of op-amp shared by the first and second stages is balanced. As for the fourth stage, the capacitor and op-amp no longer scale down. From the system''s point of view, all load capacitors of the shared OTAs are balanced by employing a loading-balanced architecture. The die area and power consumption are optimized maximally. The ADC is implemented in a 0.18 μm 1P6M CMOS technology, and occupies a die area of 1.2×1.2 mm². The measurement results show a 55.58 dB signal-to-noise-and-distortion ratio (SNDR) and 62.97 dB spurious-free dynamic range (SFDR) with a 25 MHz input operating at a 200 MS/s sampling rate. The proposed ADC consumes 115 mW at 200 MS/s from a 1.8 V supply.     

一款调制器和过采样率可配置的单芯片1.2V 95-55dB动态范围的Delta-Sigma模数转换器设计

A single die 1.2 V multi-stage noise shaping（Mash） 2-2 delta sigma analog to digital converter（ADC）for wide applications is implemented. The configurable Mash 2-2 modulator with a new decimation filter design is presented to achieve wide and high dynamic range（DR） for multiple practical applications. The novel modulator can be configured as a Mash 2-2 modulator for high precision or a 2-order modulator for low DR. The decimation filter is designed to select the OSR flexibly among cascaded integrator comb（CIC） filter and two half-band filters（HBF）. The serial peripheral interface（SPI） can be used to adjust the sampling frequency and the oversampling ratio（OSR）. The design was fabricated in a 0.13 m CMOS process with an area of 0.91 mm2and a total power of 5.2 mW. The measurement results show that the dynamic range（DR） of the proposed ADC can change from 55to 95 dB with the configurable OSR from 16 to 256. The spurious free dynamic range（SFDR） and signal-to-noise distortion ratio（SNDR） can get 99 dB and 86.5 dB, respectively.     

一个全差分可编程的多通道神经信号记录芯片

A multi-channel,fully differential programmable chip for neural recording application is presented.The integrated circuit incorporates eight neural recording amplifiers with tunable bandwidth and gain,eight 4thorder Bessel switch capacitor filters,an 8-to-1 analog time-division multiplexer,a fully differential successive approximation register analog-to-digital converter(SAR ADC),and a serial peripheral interface for communication.The neural recording amplifier presents a programmable gain from 53 dB to 68 dB,a tunable low cut-off frequency from 0.1 Hz to 300 Hz,and 3.77 μVrms input-referred noise over a 5 kHz bandwidth.The SAR ADC digitizes signals at maximum sampling rate of 20 kS/s per channel and achieves an ENOB of 7.4.The integrated circuit is designed and fabricated in 0.18-μm CMOS mix-signal process.We successfully performed a multi-channel in-vivo recording experiment from a rat cortex using the neural recording chip.     

A 0.6 V 10 bit 1 MS/s monotonic switching SAR ADC with common mode stabilizer in 0.13 μm CMOS

This paper presents a 0.6 V 10 bit successive approximation register （SAR） ADC design dedicated to the wireless sensor network application. It adopts a monotonic switching scheme in the DAC to save chip area and power consumption. The main drawback of the monotonic switching scheme is its large common mode shift and the associated comparator offset variation. Due to the limited headroom at the 0.6 V supply voltage, the conventional constant current biasing technique cannot be applied to the dynamic comparator. In this design, a common mode stabilizer is introduced to address this issue in low-voltage design. The effectiveness of this method is verified through both simulation and measurement results. Fabricated with 1P8M 0.13 μm CMOS technology, the proposed SAR ADC consumes 6.3 μW at 1 MS/s from a 0.6 V supply, and achieves 51.25 dB SNDR at the Nyquist frequency and FOM of 21 fJ/conversion-step. The core area is only 120 × 300 μm^2.     

A 130 nm CMOS low-power SAR ADC for wide-band communication systems

This paper presents a low power 9-bit 80 MS/s SAR ADC with comparator-sharing technique in 130 nm CMOS process. Compared to the conventional SAR ADC, the sampling phase is removed to reach the full efficiency of the comparator. Thus the conversion rate increases by about 20% and its sampling time is relaxed. The design does not use any static components to achieve a widely scalable conversion rate with a constant FOM. The floorplan of the capacitor network is custom-designed to suppress the gain mismatch between the two DACs. The ＇set-and- down＇ switching procedure and a novel binary-search error compensation scheme are utilized to further speed up the SA bit-cycling operation. A very fast logic controller is proposed with a delay time of only 90 ps. At 1.2 V supply and 80 MS/s the ADC achieves an SNDR of 51.4 dB and consumes 1.86 mW, resulting in an FOM of 76.6 fJ/conversion-step. The ADC core occupies an active area of only 0.089 mm2.     

Ranking Potential Reply-Providers in Community Question Answering System

Community Question Answering （CQA） websites have greatly facilitated users＇ lives, with an increasing number of people seeking help and exchanging ideas on the Internet. This newlymerged community features two characteristics： social relations and an ask-reply mechanism. As users＇ behaviours and social statuses play a more important role in CQA services than traditional answer retrieving websites, researchers＇ concerns have shifted from the need to passively find existing answers to actively seeking potential reply providers that may give answers in the near future. We analyse datasets derived from an online CQA system named ＂Quora＂, and observed that compared with traditional question answering services, users tend to contribute replies rather than questions for help in the CQA system. Inspired by the findings, we seek ways to evaluate the users＇ ability to offer prompt and reliable help, taking into account activity, authority and social reputation char- acteristics. We propose a hybrid method that is based on a Question-User network and social network using optimised PageRank algorithm. Experimental results show the efficiency of the proposed method for ranking potential answer-providers.     

Low power high gain gain-controlled LNA and mixer for GNSS receivers Wei Binbin(魏斌斌)1, Jiang Jinguang(江金光)1,2,3*

A low power high gain gain-controlled LNA ＋ mixer for GNSS receivers is reported. The high gain LNA is realized with a current source load. Its gain-controlled ability is achieved using a programmable bias circuit. Taking advantage of the high gain LNA, a high noise figure passive mixer is adopted. With the passive mixer, low power consumption and high voltage gain of the LNA ＋ mixer are achieved. To fully investigate the performance of this circuit, comparisons between a conventional LNA ＋ mixer, a previous low power LNA ＋ mixer, and the proposed LNA ＋ mixer are presented. The circuit is implemented in 0.18 #m mixed-signal CMOS technology. A 3.8 dB noise figure, an overall 45 dB converge gain and a 10 dB controlled gain range of the two stages are measured. The chip occupies 0.24 mm2 and consumes 2 mA current under 1.8 V supply.     

一种应用于GPS接收机的高线性度SiGe HBT低噪声放大器

A high linearity 1.575 GHz SiGe：HBT low noise amplifier （LNA） for global positioning system applications is described. The bipolar cascoded with an MOSFET LNA was fabricated in a commercial 0.18 μm SiGe BiCMOS process, A resistor bias feed circuit with a feedback resistor was designed for the LNA input transistor to improve its intermodulation and compression performance. The packaged chip tested on board has displayed a noise figure of 1. I 1 dB, a power gain of 18 dB, an output 1 dB compression point of ＋7.8 dBm and an input third-order intercept point of ＋1.8 dBm. The chip occupies a 500 × 560μm^2 area and consumes 3.6 mA from a 2.85 V power supply.     

一种应用于GNSS接收机的低噪声和低杂散频率综合器

A low phase noise and low spur phase locked loop （PLL） frequency synthesizer for use in global navigation satellite system （GNSS） receivers is proposed. To get a low spur, the symmetrical structure of the phase frequency detector （PFD） produces four control signals, which can reach the charge pump （CP） simultaneously, and an improved CP is realized to minimize the charge sharing and the charge injection and make the current matched. Additionally, the delay is controllable owing to the programmable PFD, so the dead zone of the CP can be eliminated. The output frequency of the VCO can be adjusted continuously and precisely by using a programmable LC-TANK. The phase noise of the VCO is lowered by using appropriate MOS sizes. The proposed PLL frequency synthesizer is fabricated in a 0.18 μm mixed-signal CMOS process. The measured phase noise at 1 MHz offset from the center frequency is -127.65 dBc/Hz and the reference spur is -73.58 dBc.     

用于U波段移动数字电视的宽带大动态范围高线性度射频前端

A wideband large dynamic range and high linearity U-band RF front-end for mobile DTV is introduced,and includes a noise-cancelling low-noise amplifier(LNA),an RF programmable gain amplifier(RFPGA) and a current communicating passive mixer.The noise/distortion cancelling structure and RC post-distortion compensation are employed to improve the linearity of the LNA.An RFPGA with five stages provides large dynamic range and fine gain resolution.A simple resistor voltage network in the passive mixer decreases the gate bias voltage of the mixing transistor,and optimum linearity and symmetrical mixing is obtained at the same time.The RF front-end is implemented in a 0.25 μm CMOS process.Tests show that it achieves an ⅡP3(third-order intercept point) of –17 dBm,a conversion gain of 39 dB,and a noise figure of 5.8 dB.The RFPGA achieves a dynamic range of –36.2 to 23.5 dB with a resolution of 0.32 dB.