Title :
Local thermal effects in high performance bipolar devices/circuits
Author :
Dennison, R.T. ; Walter, K.M.
Author_Institution :
IBM Corp., Hopewell Junction, NY, USA
Abstract :
Self-heating effects in high-performance bipolar devices and circuits are discussed. A transistor model with self-heating effects, circuit simulation results with and without self-heating, and transient thermal measurements are presented. The relatively large thermal spreading resistance associated with the small device sizes used in VLSI and higher levels of integration in conjunction with the high power levels used in these devices give rise to large thermal gradients between devices within the same circuit. This is shown to result in an additional small (1% to 4%) delay component in a typical CSEF circuit. Larger delay is expected for certain circuits with devices operated at high power densities
Keywords :
VLSI; bipolar integrated circuits; bipolar transistors; integrated logic circuits; semiconductor device models; CSEF circuit; VLSI; additional delays; bipolar ICs; circuit simulation results; current switch emitter follower; high power densities; high-performance bipolar devices; large thermal gradients between devices; local thermal effects; self-heating effects; small device sizes; thermal spreading resistance; transient thermal measurements; transistor model; Bipolar transistor circuits; Capacitance; Circuit simulation; Electrical resistance measurement; Power generation; Silicon; Surface resistance; Temperature; Thermal conductivity; Thermal resistance;
Conference_Titel :
Bipolar Circuits and Technology Meeting, 1989., Proceedings of the 1989
Conference_Location :
Minneapolis, MN
DOI :
10.1109/BIPOL.1989.69483
