Title :
Advanced encryption system with dynamic pipeline reconfiguration for minimum energy operation
Author :
Chellappa, Srivatsan ; Ramamurthy, Chandarasekaran ; Vashishtha, Vinay ; Clark, Lawrence T.
Author_Institution :
Arizona State Univ., Tempe, AZ, USA
Abstract :
Power dissipation is a major concern in sub-nanometer IC designs with technology scaling pushing towards higher clock frequencies. Techniques such as dynamic voltage (and frequency) scaling (DVS) to minimize power while providing good throughput have become commonplace. This paper presents a fully pipelined 256-bit key advanced encryption system (AES) design implemented with power-saving pulse-clocked latches as pipeline flip-flops that supports pipeline collapse, whereby pipeline stages can be unified by making stage latches transparent. The design is fabricated on a foundry 90-nm low standby power process. Measured results show the design is capable of 64 Gb/s encryption, limited by the I/O speed. A 7.6% decrease in the energy per operation beyond DVS power reduction using pipeline stage unification (PSU) is obtained.
Keywords :
VLSI; cryptography; flip-flops; integrated circuit design; pipeline processing; power aware computing; power integrated circuits; advanced encryption system; dynamic pipeline reconfiguration; dynamic voltage scaling; minimum energy operation; pipeline collapse; pipeline flip-flops; pipeline stage unification; power dissipation; power-saving pulse-clocked latches; size 90 nm; sub-nanometer IC designs; Clocks; Delays; Flip-flops; Latches; Pipeline processing; Pipelines; IC power; advanced encryption standard; dynamic voltage scaling; pipeline stage unification; pulse latch;
Conference_Titel :
Quality Electronic Design (ISQED), 2015 16th International Symposium on
Conference_Location :
Santa Clara, CA
Print_ISBN :
978-1-4799-7580-8
DOI :
10.1109/ISQED.2015.7085425
