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采用低摆幅低交叉点的高速CMOS电流开关驱动器结构和中心对称Q2随机游动对策拓扑方式的pMOS电流源阵列版图布局方式,基于TSMC 0.18靘 CMOS工艺实现了一种1.8V 10位120MS/s分段温度计译码电流舵CMOS电流舵D/A转换器IP核.当电源电压为1.8V时,D/A转换器的微分非线性误差和积分非线性误差分别为0.25LSB和0.45LSB,当采样频率为120MHz,输出频率为24.225MHz时的SFDR为64.9dB.10位D/A转换器的有效版图面积为0.43mm×0.52mm,符合SOC的嵌入式设计要求. 相似文献
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采用低摆幅低交叉点的高速CMOS电流开关驱动器结构和中心对称Q2随机游动对策拓扑方式的pMOS电流源阵列版图布局方式,基于TSMC 0.18靘 CMOS工艺实现了一种1.8V 10位120MS/s分段温度计译码电流舵CMOS电流舵D/A转换器IP核.当电源电压为1.8V时,D/A转换器的微分非线性误差和积分非线性误差分别为0.25LSB和0.45LSB,当采样频率为120MHz,输出频率为24.225MHz时的SFDR为64.9dB.10位D/A转换器的有效版图面积为0.43mm×0.52mm,符合SOC的嵌入式设计要求. 相似文献
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高速A/D转换器的研究进展及发展趋势 总被引:1,自引:0,他引:1
介绍了高速高精度A/D转换器技术的发展情况、A/D转换器的关键指标和关键技术考虑;阐述了高速高精度A/D转换器的结构和工艺特点;讨论了高速高精度A/D转换器的发展趋势. 相似文献
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基于0.18 μm CMOS工艺,设计了一种16位600 MS/s电流舵D/A转换器。该D/A转换器为1.8 V/3.3 V双电源供电,采用并行输入、差分电流输出的四分段(5+4+3+4)电流舵结构。采用灵敏放大器型锁存器可以精确锁存数据,避免出现误码;由恒定负载产生电路和互补交叉点调整电路组成的同步与开关驱动电路,降低了负载效应引起的谐波失真,同时减小了输出毛刺;低失真电流开关消除了差分开关对共源节点处寄生电容对D/A转换器动态性能的影响。Spectre仿真验证结果表明,当采样频率为625 MHz,输入信号频率为240 MHz时,该D/A转换器的SFDR为78.5 dBc。 相似文献
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提出了一种基于电流模式的算法型A/D转换器电路结构,分析说明了其基本原理和具体实现方法;构造了一个6位50 MSPS算法型A/D转换器,给出了在OrCAD/PSpice 10.5下的仿真结果,得出用电流模式电路设计高速A/D转换器有优势的结论. 相似文献
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本文介绍了一款带8选1MUX的14位2.5GS/s D/A转换器。该转换器采用了“5+9”分段PMOS电流舵结构,偏置电路保证PMOS电流源阵列能够在PVT(温度、电源电压、工艺角)变化的条件下获得较大的输出阻抗。高速8to1 mux电路采用了3级结构,采用恰当的数据选择时序,提高了数据合成的可靠性。D/A转换器输入数据的高5位译码器中加入了DEM功能改善了D/A转换器模拟输出的动态性能。本文所述的带8选1MUX功能的14位2.5GS/s D/A转换器内嵌在一款高性能DDS电路中,流片的实测结果显示在时钟2.5GHz下, MUX和D/A转换器工作正常,输出信号在1GHz带宽范围内,SFDR> 40dB。与目前国际上已发表的非模拟重采样结构的D/A转换器(即没有采用“归零”或“四开关”这些模拟重采样结构)相比,本文介绍的D/A转换器具有较高的时钟频率(2.5GHz)和较好的高频SFDR性能(>40dB, up to 1GHz)。 相似文献
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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。 相似文献
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Anne van den Bosch Michiel Steyaert Willy Sansen 《Analog Integrated Circuits and Signal Processing》2001,29(3):173-180
To obtain a high resolution CMOS current-steering digital-to-analog converter, the matching behavior of the current source transistors is one of the key issues in the design. At this moment, these matching properties are taken into account by the use of time consuming and CPU intensive Monte Carlo simulations. In this paper, a formula is derived that describes accurately the impact of the mismatch on the INL (integral non-linearity) yield of current-steering D/A converters without any loss of design time. 相似文献
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设计了一种带电流源校准电路的16 bit高速、高分辨率分段电流舵型数模转换器(DAC)。针对电流舵DAC中传统差分开关的缺点,提出了一种优化的四相开关结构。系统分析了输出电流、积分非线性和无杂散动态范围(SFDR)三个重要性能指标对电流舵DAC的电流源单元设计的影响,完成了电流源单元结构和MOS管尺寸的设计。增加了一种优化设计的电流源校准电路以提高DAC的动态性能。基于0.18μm CMOS工艺完成了该DAC的版图设计和工艺加工,其核心部分芯片面积为2.8 mm^2。测试结果表明,在500 MHz采样速率、100 MHz输入信号频率下,测得该DAC的SFDR和三阶互调失真分别约为76和78 dB,动态性能得到明显提升。 相似文献
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O'Sullivan K. Gorman C. Hennessy M. Callaghan V. 《Solid-State Circuits, IEEE Journal of》2004,39(7):1064-1072
A 12-bit 320-MSample/s current-steering D/A converter in 0.18-/spl mu/m CMOS is presented. In order to achieve high linearity and spurious free dynamic range (SFDR), a large degree of segmentation has been used, with the seven most significant bits (MSBs) being implemented as equally weighted current sources. A "design-for-layout" approach has allowed this to be done in an area of just 0.44 mm/sup 2/. The increased switching noise associated with a high degree of segmentation has been reduced by a new latch architecture. Differential nonlinearity of /spl plusmn/0.3 LSB and integral nonlinearity of /spl plusmn/0.4 LSB have been measured. Low-frequency SFDR of 95 dB has been achieved, while SFDR at 320 MS/s remains above 70 and 60 dB for input frequencies up to 10 and 60 MHz, respectively. The converter consumes a total of 82 mW from 1.8-V and 3.3-V supplies. The validity of the techniques used has been demonstrated by fabricating the converter in two separate 0.18-/spl mu/m processes with similar results measured for both. 相似文献
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数字接收机中超高速A/D转换电路的PCB设计 总被引:1,自引:0,他引:1
随着大规模集成电路和数字信号处理技术的迅速发展,雷达接收机和电子战接收机的数字化已是一种必然趋势,A/D变换器是决定数字接收机性能的关键部件之一,文中结合一种采样率可达1GSPS的A/D转换电路的设计,重点介绍了高速高频PCB设计的一些规则、注意事项和经验。 相似文献
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A new BiCMOS current cell and a BiCMOS current switch for high speed, self-calibrating, current-steering D/A converters are described. The BiCMOS current cell can be realized in a BiCMOS process or in a conventional CMOS process using a substrate PNP transistor, while the BiCMOS current switch is intended for implementation in a BiCMOS process. The performance of these circuits has been demonstrated in 0.8 μm BiCMOS and 1.2-μm CMOS technologies. A detailed noise analysis of the BiCMOS current cell indicates that noise during the calibration phase limits its relative accuracy to about 150 ppm. This is substantiated by measured results which show a relative matching of about 100-150 ppm, which is the equivalent of about 13 b performance. Measurement results also indicate that the absolute accuracy of the BiCMOS current cell is better than 0.5% over the designed current range, which is better than that of previously reported designs. Test results for the BiCMOS current switch indicate that a 10-90% switching time of 0.9 ns has been achieved. Furthermore, the switching time of the new BiCMOS switch is very insensitive to current level and input waveform compared to conventional CMOS switches. A 4-b D/A converter based on these components has been fabricated, and test results have demonstrated that it is functional. This DAC will be used as the internal DAC of a ΣΔ modulator for over-sampled video and digital radio applications 相似文献