Quantifying the effect of local interconnects on on-chip power distribution |
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Affiliation: | 1. Digital Design Group SK Hynix Memory Solutions, San Jose, California 95133, USA;2. Department of Electrical and Computer Engineering, Stony Brook University, Stony Brook, New York 11794, USA;1. Center of Nanoelectronics and Devices, AUC and Zewail City of Science and Technology, New Cairo 11835, Egypt;2. Electronics and Communications Engineering Department, Cairo University, Giza 12613, Egypt;1. NISC Research Center, Nile University, Cairo, Egypt;2. Engineering Mathematics and Physics Dept., Faculty of Engineering, Cairo University, Cairo, Egypt |
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Abstract: | Existing methods to analyze and optimize on-chip power distribution networks typically focus only on global power network modeled as a two-dimensional mesh. In practice, current is supplied to switching transistors through a local power network at the lower metal layers. The local power network is connected to a global network through a stack of vias. The effect of these vias and the resistance of the local power network are typically ignored when optimizing a power network and placing decoupling capacitors. By modeling the power distribution network as a three-dimensional mesh, the error due to ignoring via and local interconnect resistances is quantified. It is demonstrated that ignoring the local power network and vias can both underestimate (by up to 45%) or overestimate (by up to 50%) the effective resistance of a power distribution network. The error depends upon multiple parameters such as the width of local and global power lines and via resistance. A design space is also generated to indicate the valid width of local and global power lines where the target resistance is satisfied. It is shown that a wider global network can be used to obtain a narrower local network, providing additional flexibility in the physical design process since routability is an important concern at lower metal layers. At high via resistances, however, this approach causes significant increase in the width of a global power network, indicating the growing significance of local power network and vias. |
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Keywords: | On-chip interconnect Power delivery Power integrity Power supply noise |
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