Title :
Reducing radiation-hardened DigitalCircuit power consumption
Author :
McIver, John K., III ; Clark, Lawrence T.
Author_Institution :
Arizona State Univ., Tempe, AZ, USA
Abstract :
Low-power radiation-hardened sequential digital circuits supporting multiple supply voltages, integrated logic, and a low standby power state are presented. By basing the design on proven radiation hard circuits, single event effects hardness is guaranteed. The circuit is based on differential cascode voltage switch logic, which provides an integral level shift and allows storage at the full supply voltage supported by the process, while allowing the combinatorial logic supply voltage to scale for power savings. When compared to a conventional master-slave flip-flop design, the proposed flip-flop design provides up to 80% energy reduction with logic operating at reduced voltage and speed. Fifty-percent energy reduction is obtained without compromising speed when operating with all circuits at maximum voltage.
Keywords :
digital integrated circuits; flip-flops; hardness; power consumption; radiation hardening (electronics); differential cascode voltage switch logic; hardness; integral level shift; integrated logic circuit; logic operating; logic supply voltage; low standby power state; master-slave flip-flop design; power consumption; power saving; radiation hardened digital circuit; silicon on insulator; Digital circuits; Energy consumption; Flip-flops; Logic circuits; Logic design; Master-slave; Sequential circuits; Switches; Switching circuits; Voltage; Flip-flop; low power; low standby power; multiple power-supply voltages; radiation hardening; silicon on insulator;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2005.861082
