Title :
Design of a 10GHz clock distribution network using coupled standing-wave oscillators
Author :
O´Mahony, Frank ; Yue, C. Patrick ; Horowitz, Mark A. ; Wong, S. Simon
Author_Institution :
Stanford Univ., CA, USA
Abstract :
In this paper, a global clock network that incorporates standing waves and coupled oscillators to distribute a high-frequency clock signal with low skew and low jitter is described. The key design issues involved in generating standing waves on a chip are discussed, including minimizing wire loss within an available technology. A standing-wave oscillator, a distributed oscillator that sustains ideal standing waves on lossy wires, is introduced. A clock grid architecture comprised of coupled, standing-wave oscillators and differential, low-swing clock buffers is presented. The measured results for a prototyped standing-wave clock grid operating at 10GHz and fabricated in a 0.18μm 6M CMOS logic process are presented. A technique is proposed for on-chip skew measurements with subpicosecond precision.
Keywords :
CMOS digital integrated circuits; clocks; integrated circuit design; microprocessor chips; oscillators; 0.18 micron; 10 GHz; CMOS logic process; clock distribution network; clock grid architecture; clock signal; coupled standing-wave oscillator; differential buffer; distributed oscillator; global clock network; lossy wire; low-swing clock buffer; on-chip skew measurement; resonant clocking; subpicosecond precision; wire loss; CMOS process; Clocks; Computational Intelligence Society; Coupling circuits; Integrated circuit interconnections; Integrated circuit measurements; Jitter; Microprocessors; Oscillators; Prototypes;
Conference_Titel :
Design Automation Conference, 2003. Proceedings
Print_ISBN :
1-58113-688-9
DOI :
10.1109/DAC.2003.1219105
