Analysis of propagation-delays in high-speed bipolar gates

Abstract

This paper presents novel accurate propagation-delay expressions for evaluating the speed performances of very-high-speed bipolar gates. Our expressions were derived by sensitivity analysis though SPICE simulations. We previously developed high-speed emitter-coupled logic (ECL) and source-coupled logic (SCL) gates for high-speed operations using transient currents in emitter or source followers. In this work, we analyze the propagation-delay times of the conventional and proposed bipolar ECL gates using novel propagation-delay expressions. The base-emitter diffusion capacitance (CD) is a speed-limiting parameter in a bipolar gate. The ECL gate mainly consists of the current switch and emitter followers. Thus, we distinguished the base-emitter diffusion capacitances in current switch transistors and emitter follower ones to enhance the accuracy of the expressions by sensitivity analysis. Our expressions for both conventional and novel high-speed ECL gates were expressed as the linear weighted sum of 11 time constants. The propagation-delay times in conventional and novel high-speed gates calculated from our expressions agree well with simulation results. The expressions show that our circuit technique can reduce the delay times for RBCD and τF in the current switch transistors, which are dominant speed limiting time constants in high-speed bipolar ECL gates.