A 1.6-GS/s 12-bit return-to-zero GaAs RF DAC for multiple Nyquist operation

A 12-bit 1.6-GS/s digital-to-analog converter (DAC) implemented with 4-/spl mu/m/sup 2/ GaAs HBT process is presented. Return-to-zero (RZ) current switches are added to current steering DAC for high-frequency wideband applications to achieve 800-MHz bandwidth at first and second Nyquist band without the need for a reverse sinc equalization filter in wideband transmitter application. The RZ circuit also improves spectral purity by screening the switching noise from the analog output during data transition. Measured performance shows two-tone third-order harmonic distortion of -70 dB at 1.5-GHz output frequency, clocked at 1.6 GHz. Reliable interface with CMOS logic IC is guaranteed with the inclusion of a four-clock-deep FIFO circuit. The DAC dissipates 1.2 W at -5 V when sampled with 1.6-GHz clock, with typical output voltage swing of 1.2 V/sub PP/.     

A self-trimming 14-b 100-MS/s CMOS DAC

A 14-b 100-MS/s CMOS digital-analog converter (DAC) designed for high static and dynamic linearity is presented. The DAC is based on a central core of 15 thermometer decoded MSBs, 31 thermometer decoded upper LSBs (ULSBs) and 31 binary decoded lower LSBs (LLSBs). The static linearity corresponding to the 14-b specification is obtained by means of a true background self-trimming circuit which does not use additional current sources to replace the current source being measured during self-trimming. The dynamic linearity of the DAC is enhanced by a special track/attenuate output stage at the DAC output which tracks the DAC current outputs when they have settled but attenuates them for a half-clock cycle after the switching instant. The DAC occupies 3.44 mm×3.44 mm in a 0.35-μm CMOS process, and is functional at up to 200 MS/s, with best dynamic performance obtained at 100 MS/s. At 100 MS/s, power consumption is 180 mW from a 3.3-V power supply, and 210 mW at 200 MS/s     

A 1.4-V 25-Mw 600-MS/s 6-bit folding and interpolating ADC in 0.13-μm CMOS

A 600-MSample/s 6-bit folding and interpolating analog-to-digital converter (ADC) is presented. This ADC with single track-and-hold (T/H) circuits is based on cascaded folding amplifiers and input-connection-improved active interpolating amplifiers. The prototype ADC achieves 5.55 bits of the effective number of bits (ENOB) and 47.84 dB of the spurious free dynamic range (SFDR) at 10-MHz input and 4.3 bit of ENOB and 35.65 dB of SFDR at 200-MHz input with a 500 MS/s sampling rate; it achieves 5.48 bit of ENOB and 43.52 dB of SFDR at 1-MHz input and 4.66 bit of ENOB and 39.56 dB of SFDR at 30. 1-MHz input with a 600-MS/s sampling rate. This ADC has a total power consumption of 25 mW from a 1.4 V supply voltage and occupies 0.17 mm~2 in the 0.13-μm CMOS process.     

An IEEE 802.11 and 802.16 WLAN Wireless Transmitter Baseband Architecture with a 1.2-V, 600-MS/s, 2.4-mW DAC

In this paper, we propose a transmitter baseband architecture for the present and up-coming WLAN applications (IEEE 802.11a/g, 802.11n, 802.16), based on a 600-MS/s current-steering DAC with a passive output load, to perform the baseband signal processing, avoiding the use of any active analog reconstruction filter. The DAC, fabricated in a 0.13-μm CMOS technology, consumes 2.4 mW from a 1.2-V single supply voltage. The DAC exhibits 68 dB of SFDR at full-scale for a 12-MHz input signal frequency and 9.7 bits of full-scale dynamic range in the bandwith from dc to 10 MHz.     

A 10-bit 50-MS/s reference-free low power SAR ADC in 0.18-μm SOI CMOS technology

正A 10-bit 50-MS/s reference-free low power successive approximation register(SAR) analog-to-digital converter(ADC) is presented.An energy efficient switching scheme is utilized in this design to obtain low power and high frequency operation performance without an additional analog power supply or on-chip/off-chip reference. An on-chip calibration DAC(CDAC) is implemented to cancel the offset of the latch-type sense amplifier(SA) to ensure precision whilst getting rid of the dependence on the pre-amplifier,so that the power consumption can be reduced further.The design was fabricated in IBM 0.18-μm 1P4M SOI CMOS process technology.At a 1.5-V supply and 50-MS/s with 5-MHz input,the ADC achieves an SNDR of 56.76 dB and consumes 1.72 mW,resulting in a figure of merit(FOM) of 61.1 fJ/conversion-step.     

A 1.8-V 67-mW 10-bit 100-MS/s pipelined ADC using time-shifted CDS technique

A time-shifted correlated double sampling (CDS) technique is proposed in the design of a 10-bit 100-MS/s pipelined ADC. This technique significantly reduces the finite opamp gain error without compromising the conversion speed, allowing the active opamp blocks to be replaced by simple cascoded CMOS inverters. Both high-speed and low-power operation is achieved without compromising the accuracy requirement. An efficient common-mode voltage control is introduced for pseudodifferential architecture which can further reduce power consumption. Fabricated in a 0.18-/spl mu/m CMOS process, the prototype 10-bit pipelined ADC occupies 2.5 mm/sup 2/ of active die area. With 1-MHz input signal, it achieves 65-dB SFDR and 54-dB SNDR at 100MS/s. For 99-MHz input signal, the SFDR and SNDR are 63 and 51 dB, respectively. The total power consumption is 67 mW at 1.8-V supply, of which analog portion consumes 45 mW without any opamp current scaling down the pipeline.     

一个带有采样时间误差校正的14位200MS/s时钟交织模数转换器

通道间的采样时间误差会降低时钟交织模数转换器的精度。本论文提出了一种针对采样时间误差的具有低电路复杂度和快速收敛特性的校正算法。该算法基于相关性来探测采样时间误差,并可被应用于广义平稳的输入信号,被探测到的采样时间误差被一个压控采样开关修正。实验结果显示,对于一个2通道14位200MS/s的时钟交织模数转换器,当输入信号的频率为70.12MHz时,经校正后,信号与噪声失真比改善了19.1dB,无杂散动态范围改善了34.6dB。校正的收敛时间约为20000个采样时间间隔。     

基于40纳米CMOS工艺的500-MS/s 10-bit三通道电流舵型DAC的鲁棒性设计

A 500-MS/s 10-bit triple-channel current-steering DAC in 40 nm 1P8M CMOS advanced technology is proposed.The central symmetry random walk scheme is applied for current source arrays to avoid mismatching effects in nano-CMOS design.The high-speed latch drivers can be self-adaptively connected to switches in different voltage domains.The experimental data shows that the maximum DNL and INL are 0.42 LSB and 0.58 LSB.The measured SFDR at 1.7 MHz output signal is 58.91 dB,58.53 dB and 56.98 dB for R/G/B channels,respectively.The DAC has good static and dynamic performance despite the single-ended output.The average rising time and falling time of three channels are 0.674 ns and 0.807 ns.The analog/digital power supply is 3.3 V/1.1 V.This triple-channel DAC occupies 0.5656 mm2.     

基于过零检测的流水线型ADC的设计

该文对比传统基于运放结构的MDAC,介绍了基于过零检测电路ZCBC(zero-crossingbased circuit)的MDAC结构。该结构可以实现轨到轨的信号范围,更加适用于深亚微米下流水线型ADC的设计。并采用0.18μm CMOS工艺,设计了一款10bit 10MSPS 1.5bit/级的流水线型ADC。仿真结果表明:在采样频率为10MHz,输入信号频率为1MHz时,SFDR为66.39dB,ENOB为8.57bits,THD为-62.30dB,DNL为1.36LSB,INL为2.24LSB。     

一种改进的高速DAC电流开关及其控制信号的产生

系统分析了高速电流型CMOS数模转换器中电流开关对输出毛刺的影响,给出了减小输出毛刺的方法.改进了电流开关及其控制信号的产生电路.利用改进后的电路设计了一个8位数模转换器,在5V电源,满量程输出2 0mA条件下,模拟得到最大输出毛刺为3pV s,且电路在1 0 0MHz采样频率,1 0MHz信号频率下,无假信号动态范围达到53dB     

An area-efficient 55 nm 10-bit 1-MS/s SAR ADC for battery voltage measurement

An area-efficient CMOS 1-MS/s 10-bit charge-redistribution SAR ADC for battery voltage measurement in a SoC chip is proposed. A new DAC architecture presents the benefits of a low power approach without applying the common mode voltage. The threshold inverter quantizer(TIQ)-based CMOS Inverter is used as a comparator in the ADC to avoid static power consumption which is attractive in battery-supply application. Sixteen level-up shifters aim at converting the ultra low core voltage control signals to the higher voltage level analog circuit in a 55 nm CMOS process. The whole ADC power consumption is 2.5 mW with a maximum input capacitance of 12 pF in the sampling mode. The active area of the proposed ADC is 0.0462 mm2 and it achieves the SFDR and ENOB of 65.6917 dB and 9.8726 bits respectively with an input frequency of 200 kHz at 1 MS/s sampling rate.     

A 14-bit intrinsic accuracy Q2 random walk CMOS DAC

In this paper, a 14-bit, 150-MSamples/s current steering digital-to-analog converter (DAC) is presented. It uses the novel Q² random walk switching scheme to obtain full 14-bit accuracy without trimming or tuning. The measured integral and differential nonlinearity performances are 0.3 and 0.2 LSB, respectively; the spurious-free dynamic range is 84 dB at 500 kHz and 61 dB at 5 MHz. Running from a single 2.7-V power supply, it has a power consumption of 70 mW for an input signal of 500 kHz and 300 mW for an input signal of 15 MHz. The DAC has been integrated in a standard digital single-poly, triple-metal 0.5-μm CMOS process. The die area is 13.1 mm²     

A 10-bit 200-MHz CMOS video DAC for HDTV applications

This paper describes a 10-bit 200-MHz CMOS current steering digital-to-analog converter (DAC) for HDTV applications. The proposed 10-bit DAC is composed of a unit decoded matrix for 6 MSBs and a binary weighted array for 4 LSB’s, considering linearity, power consumption, routing area, and glitch energy. A new switching scheme for the unit decoded matrix is developed to improve linearity further. Cascade current sources and differential switches with deglitch latch improve dynamic performance. The measured differential nonlinearity (DNL) and integral nonlinearity (INL) are 0.3 LSB and 0.2 LSB, respectively. The converter achieves a spurious-free dynamic range (SFDR) of above 55 dB over a100-MHz bandwidth and low glitch energy of 1.5 pVs. The circuit is fabricated in a 0.25 μm CMOS process and occupies 0.91 mm². When operating at 200 M Sample/s, it dissipates 82 mW from a 3.3 V power supply.     

A 10-bit 100-Msps low power time-interleaved ADC using OTA sharing

A high performance 10-bit 100-MS/s two-channel time-interleaved pipelined ADC is designed for intermediate frequency 3G receivers,and OTA is shared among the channels for low power dissipation.Offset mismatch, gain mismatch and time skew mismatch are overcome by OTA sharing,increasing the accuracy of each channel and global passive sampling respectively.The linearity deterioration caused by the charge injection of the output switch and the crosstalk of the off-switch capacitor is removed by modifying the...     

10bit 100M低功耗时间交织运放共享模数转换器设计

本文设计了一个应用于3G接收机中频的10比特100兆采样率的双通道时间交织流水线模数转换器,为了降低功耗,运放在两通道间共享。针对通道间的直流失调失配,增益失配以及采样时间偏差,设计分别采用共享运放,增加每个通道转换精度以及全局采样技术来加以解决。通过改变时序,消除了输出开关电荷注入以及断开开关的电容造成的串扰,从而提高了整个模数转换器的线性度。整个模数转换器的供电电压为3.3V,功耗为70毫瓦,采用了180纳米CMOS工艺,面积为3×2mm2,在奈奎斯特频率以内,其杂散无失真动态范围大于70dB,其信杂比大于56dB。     

A 1.5-V 14-bit 100-MS/s self-calibrated DAC

Large-area current source arrays are widely used in current-steering digital-to-analog converters (DACs) to statistically maintain a required level of matching accuracy between the current sources. This not only results in large die size but also in significant degradation of dynamic range for high-frequency signals. To overcome technology barriers, relax requirements on the layout, and reduce DAC sensitivities to process, temperature, and aging, calibration is emerging as a viable solution for the next-generation high-performance DACs. In this paper, a new foreground calibration technique suitable for very-low-voltage environments is presented which effectively compensates for current source mismatch, and achieves high linearity with small die size and low power consumption. Settling and dynamic performance are also improved due to a dramatic reduction of parasitic effects. To demonstrate this technique, a 14-bit DAC prototype was implemented in a 0.13-/spl mu/m digital CMOS process. This is the first CMOS DAC reported that operates with a single 1.5-V power supply and achieves 14-bit linearity with less than 0.1 mm/sup 2/ of active area. At 100 MS/s, the spurious free dynamic range is 82 dB (62 dB) for signals of 0.9 MHz (42 MHz) and the power consumption is only 16.7 mW.     

一种1.5 V 8位100 MS/s电流舵D/A转换器

基于新型的低压与温度成正比(PTAT)基准源和PMOS衬底驱动低压运算放大器技术,采用分段温度计译码结构设计了一种1.5V8位100MS/s电流舵D/A转换器,工艺为TSMC0.25μm2P5MCMOS。当采样频率为100MHz,输出频率为20MHz时,SFDR为69.5dB,D/A转换器的微分非线性误差(DNL)和积分非线性误差(INL)的典型值分别为0.32LSB和0.52LSB。整个D/A转换器的版图面积为0.75mm×0.85mm,非常适合SOC的嵌入式应用。     

A 12-bit 0.35 μm CMOS area optimized current-steering hybrid DAC

In this paper a 12-bit current-steering hybrid DAC is implemented using AMS 0.35 μm CMOS process technology. The architecture and design methodology used for the implementation of the DAC offer advantages like design speed up, easiness in design and a small active area. The proposed hybrid DAC consists of four 3-bit parallel matched current-steering subDACs and resistive networks that properly weight the current output of each subDAC to obtain the overall voltage-mode output of the 12-bit hybrid DAC. The performance of the hybrid DAC is validated through static and dynamic performance metrics. Simulations indicate that the DAC has an accuracy of 12-bit and a SFDR higher than 66 dB in whole Nyquist frequency band. The simulated INL is better than 1 LSB, while simulated DNL is better than 0.25 LSB. At an update rate of 250 MS/s the SFDR for signals up to 10 MHz is higher than 66 dB. The Figure of Merit (FoM) of the implemented hybrid DAC is better than recently presented DACs with 12-bit resolutions and implemented using various process technologies. The proposed hybrid DAC supporting high update rates with good dynamic performance can be used as an alternative in various applications in industry including video, digital TV, cable modems etc.     

A current-steering self-calibration 14-bit 100-MSPs DAC

This paper presents the design and implementation of a 14-bit,100 MS/s CMOS digital-to-analog converter(DAC).Analog background self-calibration based on the concept of analog current trimming is introduced.A constant clock load switch driver,a calibration period randomization circuit and a return-to-zero output stage have been adopted to improve the dynamic performance.The chip has been manufactured in a SMIC 0.13-μm process and occupies 1.33× 0.97 mm2 of the core area.The current consumption is 50 mA under 1.2/3.3 V dual power supplies for digital and analog,respectively.The measured differential and integral nonlinearity is 3.1 LSB and 4.3 LSB,respectively.The SFDR is 72.8 dB at a 1 MHz signal and a 100 MHz sampling frequency.     

一种带二进制校正的10位100 MS/s SAR ADC

基于SMIC 65 nm CMOS工艺,设计了一种带二进制校正的10位100 MS/s逐次逼近型模数转换器(SAR ADC),主要由自举开关、低噪声动态比较器、电容型数模转换器(C-DAC)、异步SAR逻辑以及数字纠错电路组成。电容型数模转换器采用带2位补偿电容的拆分单调电容转换方案,通过增加2位补偿电容,克服了电容型数模转换器在短时间内建立不稳定和动态比较器失调电压大的问题,使SAR ADC的性能更加稳定。数字纠错电路将每次转换输出的12位冗余码转换成10位的二进制码。使用Spectre进行前仿真验证,使用Virtuoso进行版图设计,后仿真结果表明,当电源电压为1.2 V、采样率为100 MS/s、输入信号为49.903 MHz时,该ADC的SNDR达到58.1 dB,而功耗仅为1.3 mW。