Open Access
A low power clock generator with adaptive inter-phase charge balancing for variability compensation in 40-nm CMOS
Author(s) -
U. Schulze,
Martin Broich,
Oliver Weiss,
Tobias G. Noll
Publication year - 2011
Publication title -
advances in radio science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.211
H-Index - 22
eISSN - 1684-9973
pISSN - 1684-9965
DOI - 10.5194/ars-9-241-2011
Subject(s) - clock generator , cmos , electronic engineering , clock signal , benchmark (surveying) , computer science , compensation (psychology) , power (physics) , clock rate , block (permutation group theory) , engineering , electrical engineering , psychology , physics , geometry , mathematics , geodesy , quantum mechanics , psychoanalysis , jitter , geography
Abstract. Power dissipation besides chip area is still one main optimization issue in high performance CMOS design. Regarding high throughput building blocks for digital signal processing architectures which are optimized down to the physical level a complementary two-phase clocking scheme (CTPC) is often advantageous concerning ATE-efficiency. The clock system dissipates a significant part of overall power up to more than 50% in some applications. One efficient power saving strategy for CTPC signal generation is the charge balancing technique. To achieve high efficiency with this approach a careful optimization of timing relations within the control is inevitable. However, as in modern CMOS processes device variations increase, timing relations between sensitive control signals can be affected seriously. In order to compensate for the influence of global and local variations in this work, an adaptive control system for charge balancing in a CTPC generator is presented. An adjustment for the degree of charge recycling is performed in each clock cycle. In the case of insufficient recycling the delay elements which define duration and timing position of the recycling pulse are corrected by switchable timing units. In a benchmark with the conventional clock generation system, a power reduction gain of up to 24.7% could be achieved. This means saving in power of more than 12% for a complete number-crunching building block.