Low Power Resonant Rotary Global Clock Distribution Network Design

Abstract

Along with the increasing complexity of the modern very large scale integrated (VLSI) circuit design, the power consumption of the clock distribution network in digital integrated circuits is continuously increasing. In terms of power and clock skew, the resonant clock distribution network has been studied as a promising alternative to the conventional clock distribution network. Resonant clock distribution network, which works based on adiabatic switching principles, provides a complete solution for on-chip clock generation and distribution for low-power and low-skew clock network designs for high-performance synchronous VLSI circuits.This dissertation work aims to develop the global clock distribution network for one kind of resonant clocking technologies: The resonant rotary clocking technology. The following critical aspects are addressed in this work: (1) A novel rotary oscillator array (ROA) topology is proposed to solve the signal rotation direction uniformity problem, in order to support the design of resonant rotary clocking based low-skew clock distribution network; (2) A synchronization scheme is proposed to solve the large scale rotary clocking generation circuit synchronization problem; (3) A low-skew rotary clock distribution network design methodology is proposed with frequency, power and skew optimizations; (4) A resonant rotary clocking based physical design flow is proposed, which can be integrated in the current mainstream IC design flow; (5) A dynamic rotary frequency divider is proposed for dynamic frequency scaling applications. Experimental and theoretical results show: (1) The efficiency of the proposed methodology in the construction of low-skew, low-power resonant rotary clock distribution network. (2) The effectiveness of the dynamic rotary frequency divider in extending the operating frequency range of the low-power resonant rotary based applications.%%%%Ph.D., Electrical Engineering – Drexel University, 2014