一种低功耗嵌入式14位400MHz数模转换器

设计了一个14位刷新频率达400MHz,用于高速频率合成器的低功耗嵌入式数模转换器。该数模转换器采用5+4+5分段式编码结构,其电流源控制开关输出驱动级采用归零编码以提高DAC动态特性。该数模转换器核采用0.18μm1P6M混合信号CMOS工艺实现,整个模块面积仅为1.1mm×0.87mm。测试结果表明,该DAC模块的微分非线性误差是-0.9～+0.5LSB,积分非线性误差是-1.4～+1.3LSB,在400MHz工作频率下,输出信号频率为80MHz时的无杂散动态范围为76.47dB,并且功耗仅为107.2mW。     

An I/Q channel 12-bit 120?MS/s CMOS DAC with deglitch circuits

This paper describes an I/Q channel 12bit 120?MS/s DAC with deglitch circuits. The proposed DAC implemented in a 0.35???m CMOS n-well process employs three stage 4 bit thermometer decoders and deglitch circuits to minimize glitch energy and linearity error. The measurement results show a ±1.5?LSB/±1.3?LSB of INL/DNL and 31 pV·s of glitch energy. ENOB and SFDR are measured to be 10.5 bit and 71.09?dB at sampling frequency of 120?MHz and input frequency of 1?MHz with a total power consumption of 105?mW. Linearity error between I-channel DAC and Q-channel DAC is measured to be approximately 1.5?mV, i.e. the accuracy of 13 bit.     

一种基于0.35μm CMOS工艺的14位100MSPS DAC设计

基于 TSMC 0 .3 5μm CMOS工艺设计了一种工作电压为 3 V/ 5 V的 1 4位 1 0 0 MSPS DAC。 1 4位DAC在 5 0 Ω负载条件下满量程电流可达 2 0 m A,当采样速率为 1 0 0 MHz时 ,5 V电源的满量程条件下功耗为1 90 m W,而 3 V时的相应功耗为 45 m W该 DAC的积分非线性误差 ( IN L )为± 1 .5 LSB,微分非线性误差( DN L)为± 0 .75 LSB。在 1 2 5 MSPS,输出频率为 1 0 MHz条件下的无杂波动态范围 ( SFDR)为 72 d Bc。     

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.     

A low-glitch binary-weighted DAC with delay compensation scheme

This paper presents a high-speed, low-glitch, and low-power design for a 10-bit binary-weighted current-steering digital-to-analog converter (DAC). Instead of using large input buffers to drive a lot of current switches and re-timing latches, the proposed design uses variable-delay buffers with a compact layout to compensate for the delay difference among different bits, and to reduce glitch energy from 132 to 1.36 pV s during major code transitions. The measured spurious free dynamic range (SFDR) has been improved over 10 dB, as compared to DACs without variable-delay buffers. At 250 MS/s update rate, the proposed DAC achieves 56 dB SFDR for 0.67 MHz output frequency and 49 dB SFDR for 94 MHz output frequency with 50 Ω termination. For static performance, the measured integral nonlinearity (INL) and differential nonlinearity (DNL) is less than 1.6 and 1.8 LSB, respectively. The proposed DAC can be used in various applications in industry, including digital video, digital TV, wireless communication system, etc. This chip was implemented in TSMC 1P6M 0.18 μm CMOS technology and dissipates 19 mW from a single 1.8 V power supply.     

A 0.9-V 12-mW 5-MSPS algorithmic ADC with 77-dB SFDR

An ultra-low-voltage CMOS two-stage algorithm ADC featuring high SFDR and efficient background calibration is presented. The adopted low-voltage circuit technique achieves high-accuracy high-speed clocking without the use of clock boosting or bootstrapping. A resistor-based input sampling branch demonstrates high linearity and inherent low-voltage operation. The proposed background calibration accounts for capacitor mismatches and finite opamp gain error in the MDAC stages via a novel digital correlation scheme involving a two-channel ADC architecture. The prototype ADC, fabricated in a 0.18 /spl mu/m CMOS process, achieves 77-dB SFDR at 0.9 V and 5MSPS (30 MHz clocking) after calibration. The measured SNR, SNDR, DNL, and INL at 80 kHz input are 50 dB, 50 dB, 0.6 LSB, and 1.4 LSB, respectively. The total power consumption is 12 mW, and the active die area is 1.4 mm/sup 2/.     

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 3.3-V 12-b 50-MS/s A/D converter in 0.6-μm CMOS with over80-dB SFDR

A 12-b analog-to-digital converter (ADC) is optimized for spurious-free dynamic range (SFDR) performance at low supply voltage and suitable for use in modern wireless base stations. The 6-7-b two-stage pipeline ADC uses a bootstrap circuit to linearize the sampling switch of an on-chip sample-and-hold (S/H) and achieves over 80-dB SFDR for signal frequencies up to 75 MHz at 50 MSample/s (MSPS) without trimming, calibration, or dithering. INL is 1.3 LSB, differential nonlinearity (DNL) is 0.8 LSB. The 6-b and 7-b flash sub-ADCs are implemented efficiently using offset averaging and analog folding. In 0.6-μm CMOS, the 16-mm² ADC dissipates 850 mW     

A 10 bit 1 GSPS Nyquist DAC in 180 nm CMOS with high FOM

A new segmented architecture is presented to improve the dynamic and static performance of the current steering digital-to-analog converters (DACs). In the proposed architecture instead of a single binary DAC, distributed binary cells are used. So the effect of the mismatch and timing errors of the binary cells are not accumulated and are averaged out. For realization of the MSB unit cells those binary cells are reused to form the larger weighted unit cells. Realization of the MSB unit cells with smaller cells results in improved dynamic performances as the effects of gradient errors are minimized and the effects of nonlinear parasitic capacitances are reduced. The DAC has been designed in 180 nm five-metal nwell CMOS process. The simulation results show that the DAC can achieve a maximum spurious free dynamic range (SFDR) of 70.99 dB at 2.93 MHz signal for a sampling rate of 1 GSPS considering the mismatch effects. For 1 GSPS sampling rate the simulated Nyquist SFDR is >70 dB with mismatch. The simulated third order intermodulation distortion (IM3) of the DAC with mismatch effect is 71.40 dB, for a dual tone test with 491.21 and 495.12 MHz signals. The DAC is optimized for digital signal synthesis applications in wireless base stations and other communication applications. The power dissipation of the DAC is 78.21 mW at 498.05 MHz signal for a sampling rate of 1 GSPS with 1.8 V supply.     

A systematic design approach for low-power 10-bit 100 MS/s pipelined ADC

A systematic design approach for low-power 10-bit, 100 MS/s pipelined analog-to-digital converter (ADC) is presented. At architectural level various per-stage-resolution are analyzed and most suitable architecture is selected for designing 10-bit, 100 MS/s pipeline ADC. At Circuit level a modified wide-bandwidth and high-gain two-stage operational transconductance amplifier (OTA) proposed in this work is used in track-and-hold amplifier (THA) and multiplying digital-to-analog converter (MDAC) sections, to reduce power consumption and thermal noise contribution by the ADC. The signal swing of the analog functional blocks (THA and MDAC sections) is allowed to exceed the supply voltage (1.8 V), which further increases the dynamic range of the circuit. Charge-sharing comparator is proposed in this work, which reduces the dynamic power dissipation and kickback noise of the comparator circuit. The bootstrap technique and bottom plate sampling technique is employed in THA and MDAC sections to reduce the nonlinearity error associated with the input signal resulting in a signal-to-noise-distortion ratio of 58.72/57.57 dB at 2 MHz/Nyquist frequency, respectively. The maximum differential nonlinearity (DNL) is +0.6167/−0.3151 LSB and the maximum integral nonlinearity (INL) is +0.4271/−0.4712 LSB. The dynamic range of the ADC is 58.72 dB for full-scale input signal at 2 MHz input frequency. The ADC consumes 52.6 mW at 100 MS/s sampling rate. The circuit is implemented using UMC-180 nm digital CMOS technology.     

A 10-bit 100 MSamples/s BiCMOS D/A Converter

This paper presents a 10-bit Digital-to-Analogue Converter (DAC) based on the current steering principle. The DAC is processed in a 0.8µm BiCMOS process and is designed to operate at a sampling rate of 100MSamples/s. The DAC is intended for applications using direct digital synthesis, and focus has been set on reducing dynamic nonlinearities to achieve a high spurious free dynamic range (SFDR) at high generated frequencies. The main part of the DAC consists of a matrix of current cells. Each current cell contains an emitter-coupled logic (ECL) flip-flop, clocked by a global ECL clock to ensure accurate clocking. A bipolar differential pair, with a cascode CMOS current sink, steered by the differential output of the ECL flip-flop, is used in each current cell to steer the current. The DAC operates at 5V, and has a power consumption of approximately 650mW. The area of the chip-core is 2.2mm × 2.2mm. The measured integral nonlinearity (INL) and differential nonlinearity (DNL) are both approximately 2 LSB. At a generated frequency of f _g0.1 f _s(f _s = 100MSamples/s) the measured SFDR is 50dB, and at f _g0.3 f _s the measured SFDR is as high as 43dB. The DAC is operating up to a sampling frequency of approximately 140MSamples/s. The DAC uses the hierarchical switching scheme and therefore the dynamic performance is not described well using the conventional glitch energy. A new energy measure that replaces the conventional glitch energy is therefore proposed. This energy measure is especially useful during the design phase.     

一种高性能多位量化Σ-Δ调制器的设计

实现了一种适用于信号检测的低功耗Σ-Δ调制器。调制器采用2阶3位量化器结构,并使用数据加权平均算法降低多位DAC产生的非线性。调制器采用TSMC 0.18μm混合信号CMOS工艺实现。该调制器工作于1.8V电源电压,在50kHz信号带宽和12.8MHz采样频率下,整体功耗为3mW,整体版图尺寸为1.25mm×1.15mm。后仿真结果显示,在电容随机失配5‰的情况下,该调制器可以达到91.4dB的信噪失真比(SNDR)和93.6dB的动态范围(DR)。     

Nyquist电流型7位20MHz采样率CMOS数模转换器

介绍了一种高速7位DAC的设计及芯片测试结果,该DAC选取高5位单位电流源,低2位二进制电流源的分段结构。考虑了电流源匹配、毛刺降低以及版图中误差补偿等方面的问题来优化电路。流片采用0.35μmChartered双层多晶四层金属工艺,测试结果表明在20 MH z的采样频率下,微分非线性度和积分非线性度分别小于±0.2 LSB和±0.35 LSB。该DAC的满幅建立时间是20 ns,芯片面积为0.17 mm×0.23 mm。电源电压为3.3 V,功耗为3 mW。     

Power efficient high-speed DAC for wideband communication applications

This paper demonstrates a power efficient design of high-speed Digital-to-Analog Converters (DACs) for wideband communication systems. For Wireless personal area network applications with a 250 MHz signal bandwidth, a 6 bit DAC capable of two times the Nyquist rate sampling is implemented in a current steering segmented 2 + 4 architecture optimized for power efficiency. Along with a proposed master-slave deglitch circuit, several circuit techniques are investigated to improve dynamic performances such as linearity. Implemented in a 0.18 um CMOS process, our DAC achieved a superior conversion performance over the state-of-the-arts, exhibiting integral nonlinearity of less than 0.27 LSB and differential nonlinearity of less than 0.15 LSB. Measured spurious free dynamic range for 251 MHz output signal is 40.92 dB, with total power consumption at 1 GS/s of 6mW, yielding a figure-of-merits of 78.3 pJ/(conversion step*W).     

A 10-b, 500-MSample/s CMOS DAC in 0.6 mm2

A 10-b current steering CMOS digital-to-analog converter (DAC) is described, with optimized performance for frequency domain applications. For sampling frequencies up to 200 MSample/s, the spurious free dynamic range (SFDR) is better than 60 dB for signals from DC to Nyquist. For sampling frequencies up to 400 MSample/s, the SFDR is better than 55 dB for signals from DC to Nyquist. The measured differential nonlinearity and integral nonlinearity are 0.1 least significant bit (LSB) and 0.2 LSB, respectively. The circuit is fabricated in a 0.35-μm, single-poly, four-metal, 3.3 V, standard digital CMOS process and occupies 0.6 mm². When operating at 500 MSample/s, it dissipates 125 mW from a 3.3 V power supply. This DAC is optimized for embedded applications with large amounts of digital circuitry     

A power-efficient 10-bit 40-MS/s sub-sampling pipelined CMOS analog-to-digital converter

This paper presents a 10-bit 40-MS/s pipelined analog-to-digital converter (ADC) in a 0.13-μm CMOS process for subsampling applications. A simplified opamp-sharing scheme between two successive pipelined stages is proposed to reduce the power consumption. For subsampling, a cost-effective fast input-tracking switch with high linearity is introduced to sample the input signal up to 75 MHz. A two-stage amplifier with hybrid frequency compensation is developed to achieve both high bandwidth and large swing with low power dissipation. The measured result shows that the ADC achieves over 77 dB spurious free dynamic range (SFDR) and 57.3 dB signal-to-noise-plus-distortion ratio (SNDR) within the first Nyquist zone and maintains over 70 dB SFDR and 55.3 dB SNDR for input signal up to 75 MHz. The peak differential nonlinearity (DNL) and integral nonlinearity (INL) are ±0.2 LSB and ±0.3 LSB, respectively. The ADC consumes 15.6 mW at the sampling rate of 40 MHz from a 1.2-V supply voltage, and achieves a figure-of-merit (FOM) value of 0.22 pJ per conversion step.     

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     

Design and verification of a 10-bit 1.2-V 100-MSPS D/A IP core based on a 0.13-μm low power CMOS process

Based on a low supply voltage curvature-compensated bandgap reference and central symmetry Q~2 random walk NMOS current source layout routing method,a 1.2-V 10-bit 100-MSPS CMOS current-steering digital-to-analog converter is implemented in a SMIC 0.13-μm CMOS process.The total consumption is only 10 mW from a single 1.2-V power supply,and the integral and differential nonlinearity are measured to be less than 1 LSB and 0.5 LSB, respectively.When the output signal frequency is 1-5 MHz at 100-MSPS samplin...     

基于QN旋转布局的10位500 MS/s分段电流舵DAC

针对分段电流舵数/模转换器（Digital-to-Analog Converter，DAC），通过理论分析和推导，研究电流源阵列系统失配误差和寄生效应对非线性的影响，采用电流源阵列Q^N旋转游走版图布局方案，能够减小电流源系统失配的一次误差，而且版图布线简单，由寄生效应引起的电流源失配较小，利于DAC非线性的优化.基于0.18μm CMOS，采用"6+4"的分段结构，设计了一种10位500MS/s分段电流舵DAC，流片测试结果表明，在输入频率为1.465MHz，采样速率为500MS/s的条件下，无杂散动态范围（Spurious Free Dynamic Range，SFDR）为64.9dB，有效位数（Effective Number of Bits，ENOB）为8.8 bit，微分非线性误差（Differential Non-linearity，DNL）和积分非线性误差（Integral Non-linearity，INL）分别为0.77LSB和1.12LSB.     

Design of a 12-bit high-speed CMOS D/A converter using a new 3D digital decoder structure useful for wireless transmitter applications

In this paper a 12-bit Nyquist current-steering digital-to-analog converter (DAC) is implemented using TSMC 0.35 μm standard CMOS process technology. The proposed DAC is an essential part in baseband section of wireless transmitter circuits. Using oversampling ratio (OSR) for it leads to avoid use of an active analog reconstruction filter. The optimum segmentation (75%) has been used to get the best DNL and reduce glitch energy. This segmentation ratio guarantees the monotonicity. Higher performance is achieved using a new 3D thermometer decoding method which reduces the area, power consumption and the number of control signals of the digital section. Using two digital channels in parallel, helps reach 1 GHz sampling frequency. Simulations indicate that the DAC has an accuracy better than 10.7-bit for upcoming higher data rate standards (IEEE 802.16 and 802.11n), and a spurious-free-dynamic-range (SFDR) higher than 64 dB in whole Nyquist frequency band. The post layout four corner Monte-Carlo simulated INL is better than 0.74 LSB while simulated DNL is better than 0.49 LSB. The analog voltage supply is 3.3 V while the digital part of the chip operates with only 2.4 V. Total power consumption in Nyquist rate measurement is 144.9 mW. Active area of chip is 1.37 mm².