Title :
The Optimal Fan-Out of Clock Network for Power Minimization by Adaptive Gating
Author :
Wimer, Shmuel ; Koren, Israel
Author_Institution :
Sch. of Eng., Bar-Ilan Univ., Ramat-Gan, Israel
Abstract :
Gating of the clock signal in VLSI chips is nowadays a mainstream design methodology for reducing switching power consumption. In this paper we develop a probabilistic model of the clock gating network that allows us to quantify the expected power savings and the implied overhead. Expressions for the power savings in a gated clock tree are presented and the optimal gater fan-out is derived, based on flip-flops toggling probabilities and process technology parameters. The resulting clock gating methodology achieves 10% savings of the total clock tree switching power. The timing implications of the proposed gating scheme are discussed. The grouping of FFs for a joint clocked gating is also discussed. The analysis and the results match the experimental data obtained for a 3-D graphics processor and a 16-bit microcontroller, both designed at 65-nanometer technology.
Keywords :
VLSI; clocks; flip-flops; logic design; microcontrollers; probability; 3D graphics processor; VLSI chips; adaptive gating; clock gating network; clock network optimal fan-out; clock signal; clock tree switching power; flip-flop toggling probabilities; gated clock tree; joint clocked gating; mainstream design methodology; microcontroller; nanometer technology; power minimization; power savings; probabilistic model; switching power consumption reduction; word length 16 bit; Clocks; Flip-flops; Logic gates; Power demand; Probabilistic logic; Clock gating; clock networks; clock tree; dynamic power minimization; optimal fan-out;
Journal_Title :
Very Large Scale Integration (VLSI) Systems, IEEE Transactions on
DOI :
10.1109/TVLSI.2011.2162861
