Title :
System-Level Modeling for Transient Electrostatic Discharge Simulation
Author :
Tianqi Li ; Pilla, Viswa ; Zhen Li ; Maeshima, Junji ; Shumiya, Hideki ; Araki, Kenji ; Pommerenke, David J.
Author_Institution :
EMC Lab., Missouri Univ. of Sci. & Technol., Rolla, MO, USA
Abstract :
This paper introduces an improved electrostatic discharge (ESD) system-level transient simulation modeling method and discusses its validation using IEC 61000-4-2 ESD pulses on a real-world product. The system model is composed of high current and broadband (up to 3 GHz) models of R, L, C, ferrite beads, diodes, and integrated circuit IO pins. A complex return path model is the key to correctly model the system´s response to the IEC excitation. The model includes energy-limited time-dependent IC damage models. A power-time integral method is introduced to accurately determine if a junction would experience thermal runaway under an arbitrary injection waveform. The proposed method does not require knowledge of the junction´s microscopic geometry, material information, defect location, or melting temperature.
Keywords :
IEC standards; diodes; electrostatic discharge; ferrite devices; integrated circuit reliability; IEC 61000-4-2 ESD pulse; IEC excitation; arbitrary injection waveform; complex return path model; diode broadband model; diode high current model; energy-limited time-dependent IC damage model; ferrite bead broadband model; ferrite bead high current model; improved ESD system-level transient simulation modeling method; improved electrostatic discharge system-level transient simulation model; integrated circuit IO pin broadband model; integrated circuit IO pin high current model; junction defect location; junction material information; junction melting temperature; junction microscopic geometry; power-time integral method; thermal runaway; Capacitors; Electrostatic discharges; Hidden Markov models; Integrated circuit modeling; Junctions; Semiconductor device modeling; Semiconductor diodes; Common mode; IEC 61000-4-2; electromagnetic compatibility (EMC); electrostatic discharge (ESD); human machine model (HMM); system efficient ESD design (SEED); transmission line pulser (TLP);
Journal_Title :
Electromagnetic Compatibility, IEEE Transactions on
DOI :
10.1109/TEMC.2015.2443844
