Title :
Library compatible Ceff for gate-level timing
Author :
Sheehan, Bernard N.
Author_Institution :
Mentor Graphics Corp., Wilsonville, OR, USA
Abstract :
Accurate gate-level static timing analysis in the presence of RC loads has become an important problem for modern deep-submicron designs. Non-capacitive loads are usually analyzed using the concept of an effective capacitance, Ceff. Most published algorithms for C eff, however, require special cell characterization or supplemental information that is not part of standard timing libraries. In this paper we present a novel Ceff algorithm that is strictly compatible with existing timing libraries. It is also fast, easily implemented, and quite accurate-within 3% of transistor-level simulation in our tests. The method is based on approximating a gate by a current source, estimating the delay difference when the gate drives the actual RC load and a reference capacitor, and then converting the delay discrepancy into a Ceff value. Central to carrying out this program is the innovative concept of delay correction transfer function
Keywords :
VLSI; capacitance; cellular arrays; delays; integrated circuit interconnections; logic CAD; software libraries; timing; transfer functions; RC loads; cell characterization; current source; deep-submicron designs; delay correction transfer function; delay difference; delay discrepancy; effective capacitance; gate-level timing; noncapacitive loads; reference capacitor; static timing analysis; transistor-level simulation; Capacitance; Delay effects; Delay estimation; Drives; Graphics; Iterative algorithms; Libraries; Standards publication; Testing; Timing;
Conference_Titel :
Design, Automation and Test in Europe Conference and Exhibition, 2002. Proceedings
Conference_Location :
Paris
Print_ISBN :
0-7695-1471-5
DOI :
10.1109/DATE.2002.998394
