On-chip inductance modeling and analysis
Proceedings of the 37th Annual Design Automation Conference
Proceedings of the 37th Annual Design Automation Conference
Static timing analysis including power supply noise effect on propagation delay in VLSI circuits
Proceedings of the 38th annual Design Automation Conference
An algorithm for optimal decoupling capacitor sizing and placement for standard cell layouts
Proceedings of the 2002 international symposium on Physical design
On-chip power supply network optimization using multigrid-based technique
Proceedings of the 40th annual Design Automation Conference
Scaling trends of on-chip power distribution noise
IEEE Transactions on Very Large Scale Integration (VLSI) Systems
ISQED '05 Proceedings of the 6th International Symposium on Quality of Electronic Design
Maximum effective distance of on-chip decoupling capacitors in power distribution grids
GLSVLSI '06 Proceedings of the 16th ACM Great Lakes symposium on VLSI
Decoupling capacitors for multi-voltage power distribution systems
IEEE Transactions on Very Large Scale Integration (VLSI) Systems
Statistical power supply dynamic noise prediction in hierarchical power grid and package networks
Integration, the VLSI Journal
Power supply noise aware workload assignment for multi-core systems
Proceedings of the 2008 IEEE/ACM International Conference on Computer-Aided Design
Hi-index | 0.00 |
With technology scaling, the trend for high performance integrated circuits is towards higher power dissipation, higher operating frequency and lower power supply voltages. This causes a dramatic increase in power supply current being delivered through the on-chip power grid and is recognized in the International Technology Roadmap for Semiconductors as one of the difficult challenges. The design of appropriate power grids and the addition of decoupling capacitance has become crucially important in order to control power-grid-induced noise. In this paper, we show analytical relationships between noise and various technology parameters, and we show the resulting trends in noise based on current roadmap predictions.