Supply voltage drop study considering on-chip self inductance of a 32-bit processor´s power grid

Author

Andersson, Daniel A. ; Nilsson, Björn ; Pihl, Johnny ; Svensson, Lars J. ; Larsson-Edefors, Per

Author_Institution

Atmel Norway AS, Tiller

fYear

2009

fDate

12-15 May 2009

Firstpage

1

Lastpage

4

Abstract

Conventional IR drop analysis suggests that on-chip inductive effects can be neglected when estimating supply voltage drops. We present a supply voltage drop analysis for a commercial 32-bit application processor. Our power grid model uses a backbone RL extracted netlist of the processor´s power grid, complemented with capacitances from the processor design and a current signature defined by the worst-case switching test vector, located in the power-up sequence of the processor. Our circuit simulations show that on-chip self inductance makes the actual supply voltage drop deviate by more than 55% and 25% from the ~6% and ~8% drop, respectively, of nominal supply voltage that a conventional IR power grid model yields.

Keywords

integrated circuit modelling; microprocessor chips; power grids; on-chip self inductance; power-up sequence; processor power grid; supply voltage drop; switching test vector; word length 32 bit; Bonding; Capacitance; Estimation error; Inductance; Logic circuits; Network-on-a-chip; Power grids; Power systems; Voltage; Wire;

fLanguage

English

Publisher

ieee

Conference_Titel

Signal Propagation on Interconnects, 2009. SPI '09. IEEE Workshop on

Conference_Location

Strasbourg

Print_ISBN

978-1-4244-4490-8

Electronic_ISBN

978-1-4244-4489-2

Type

conf

DOI

10.1109/SPI.2009.5089853

Filename

5089853