Title :
A 4 GHz Non-Resonant Clock Driver With Inductor-Assisted Energy Return to Power Grid
Author :
Alimadadi, Mehdi ; Sheikhaei, Samad ; Lemieux, Guy ; Mirabbasi, Shahriar ; Dunford, William ; Palmer, Patrick
Author_Institution :
Electr. & Comput. Eng. Dept., Univ. of British Columbia, Vancouver, BC, Canada
Abstract :
Power consumption of a multi-GHz local clock driver is reduced by returning energy stored in the clock-tree load capacitance back to the on-chip power-distribution grid. We call this type of return energy recycling. To achieve a nearly square clock waveform, the energy is transferred in a non-resonant way using an on-chip inductor in a configuration resembling a full-bridge DC-DC converter. A zero-voltage switching technique is implemented in the clock driver to reduce dynamic power loss associated with the high switching frequencies. A prototype implemented in 90 nm CMOS shows a power savings of 35% at 4 GHz. The area needed for the inductor in this new clock driver is about 6% of a local clock region.
Keywords :
CMOS integrated circuits; DC-DC power convertors; clocks; driver circuits; inductors; power grids; switching convertors; zero voltage switching; CMOS process; clock-tree load capacitance; dynamic power loss; energy recycling; frequency 4 GHz; full-bridge DC-DC converter; multiGHz local clock driver; nonresonant clock driver; on-chip inductor; on-chip power-distribution grid; power consumption; power grid; size 90 nm; square clock waveform; switching frequency; zero-voltage switching technique; Charge recycling; energy recovery; energy recycling; full-bridge converter; low-power clock driver; multi-GHz clock; switching DC-DC converter;
Journal_Title :
Circuits and Systems I: Regular Papers, IEEE Transactions on
DOI :
10.1109/TCSI.2009.2037850
