【摘要】 本文提出了一种适用于三维集成电路芯片间时钟同步的全数字延时锁定环设计.在给定的三维集成电路中,该全数字延时锁定环采用可变逐次逼近寄存器控制器设计来缩短锁定时间,以消除谐波锁定问题并拓宽工作频率范围,实现硅过孔引起的延时偏差可容忍和垂直堆叠芯片间时钟信号同步.整个设计采用TSMC 65nm CMOS低功耗工艺实现.仿真结果显示在工艺角最坏情况下最高工作频率是833MHz(SS,125℃,1.08V),在工艺角最好情况下最低工作频率是167MHz(FF,-40℃,1.32V),整个工作频率范围内最长锁定时间固定为103个输入时钟周期,在典型工艺角下功耗为0.8mW@833 MHz(TT,25℃,1.2V).版图有效核心面积为0.018mm2.更多还原

【Abstract】 In this paper,an all-digital delay-locked loop(ADDLL)for die-to-die clock synchronization of threedimensional integrated circuit(3 D-IC)is presented.The proposed ADDLL can endure the delay variations between through silicon vias and synchronize the clock signals between vertically stacked dies of the given 3 D-IC.In order to solve the harmonic lock problem and widen the operating frequency,the circuit shortened the lock process by the use of variable successive approximation register-controlled scheme.The presented ADDLL is implemented using the TSMC 65 nm CMOS low power technology,and the simulation results show that the highest operating frequency is833 MHz at the worst case(SS,125℃,1.08 V),the lowest operating frequency is 167 MHz at the best case(FF,-40 ℃,1.32 V),the longest lock time is 103 cycles of the input clock,and the power consumption is estimated to be 0.8 mW@833 MHz at the typical case(TT,25 ℃,1.2 V).The area of the ADDLL per die is 0.018 mm2.更多还原