Time-Borrowing Multi-Cycle On-Chip Interconnects for Delay Variation Tolerance

K. Bowman, J. Tschanz, M. Khellah, M. Ghoneima, Y. Ismail, V. De
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引用次数: 13

Abstract

Insertion of time-borrowing (TB) flip-flops in multi-cycle repeater-based on-chip interconnects enables significant improvements in mean performance and energy by averaging systematic and random within-die (WID) delay variations across multiple interconnect segments. A statistically-based analytical model is derived to design a TB N-cycle interconnects with optimal delay variation tolerance. The model elucidates the dependency of the transparency window required to achieve data delay averaging on the delay variation mismatch between interconnect segments. Statistical circuit simulations and analyses in a 65nm process technology demonstrate that TB multi-cycle interconnects enable a 4-6% mean maximum clock frequency (FMAX) improvement and a corresponding 10% average energy savings over optimally designed multi-cycle interconnects with conventional master-slave flip-flops. The maximum mean FMAX benefit ranges from 4.0-7.5%, corresponding to approximately a bin-split shift in the FMAX distribution. For 1.41X larger WID delay variations, the maximum mean FMAX gain rises to 5-10%
延时容差的借时多周期片上互连
在基于多周期中继器的片上互连中插入借时(TB)触发器,通过平均多个互连段的系统和随机模内(WID)延迟变化,可以显著提高平均性能和能量。推导了一种基于统计的分析模型,用于设计具有最优延迟变化容限的TB n环互连。该模型阐明了实现数据延迟平均所需的透明窗口依赖于互连段之间的延迟变化不匹配。基于65nm工艺技术的统计电路仿真和分析表明,与采用传统主从触发器的优化设计的多周期互连相比,TB多周期互连可使平均最大时钟频率(FMAX)提高4-6%,相应的平均节能10%。最大平均FMAX收益范围为4.0-7.5%,大约对应于FMAX分布中的bin-split移位。对于1.41倍较大的WID延迟变化,最大平均FMAX增益上升到5-10%
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