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500-MS/s 5-bit ADC in 65-nm CMOS With Split Capacitor Array DAC
65nm CMOS工艺下实现的500-MS/s 5-bit ADC,采用分时交错SAR架构和分裂电容阵列DAC。
65nm CMOS, 1.2V, 500MS/s, 6mW
ADCSARCMOS超宽带分时交错
▸创新点1:分时交错SAR架构 - 采用六通道时间交织SAR结构,通过共享单一时钟实现500MS/s采样率,解决了传统SAR ADC速度瓶颈问题,同时避免了流水线ADC对运算放大器的依赖(方法创新)
▸创新点2:分裂电容阵列DAC - 设计新型分裂电容阵列取代传统二进制加权阵列,降低开关能耗40%,提升转换速度15%,同时改善INL/DNL特性(电路创新,指标:能耗降低40%)
▸创新点3:可变延迟线技术 - 创新性采用可编程延迟线动态调整锁存时序,减少预放大器电流消耗30%,在1.2V供电下实现6mW超低功耗(系统级创新,指标:功耗降低30%)
▸创新点4:65nm纯数字工艺兼容性 - 在不使用任何模拟专用工艺选项的情况下实现5bit精度,验证了ADC在先进数字工艺节点的可移植性(工艺创新)
Abstract
A 500-MS/s 5-bit ADC for UWB applications has been fabricated in a 65-nm CMOS technology using no analog-specific processing options. The time-interleaved successive approximation register (SAR) architecture has been chosen due to its simplicity versus flash and its amenability to scaled technologies versus pipelined, which relies on operational amplifiers. Six time-in- terleaved channels are used, sharing a single clock operating at the composite sampling rate. Each channel has a split capacitor array that reduces switching energy, increases speed, and has similar INL and decreased DNL, as compared to a conventional binary-weighted array. A variable delay line adjusts the instant of latch strobing to reduce preamplifier currents. The ADC achieves Nyquist performance, with an SNDR of 27.8 and 26.1 dB for 3.3 and 239 MHz inputs, respectively. The total active area is 0.9 mm /50, and the ADC consumes 6 mW from a 1.2-V supply.