Title :
High-speed pulsed-hysteresis-latch design for improved SER performance in 20 nm bulk CMOS process
Author :
Narasimham, B. ; Chandrasekharan, K. ; Wang, J.K. ; Djaja, G. ; Gaspard, N.J. ; Mahatme, N.N. ; Assis, Thiago R. ; Bhuva, B.L.
Author_Institution :
Broadcom® Corp., Irvine, CA, USA
Abstract :
A novel pulsed-latch design using hysteresis that operates similarly to an edge-triggered flip-flop with improved SER performance is presented. Design was implemented along with standard D-flip-flop (D-FF) and DICE flip-flop in a 20 nm CMOS process. Alpha and Neutron SER test results indicate ~26× and ~3× better SER hardness respectively for the pulsed-hysteresis-latch compared to D-FF. The design also benefits from a 25% higher speed and has a low area overhead of ~8% over the D-FF. A typical processor utilizing the pulsed-hysteresis-latch design can benefit from a ~5× overall SER reduction which is shown to be better than targeted DICE-FF based hardening, both in terms of SER reduction and performance penalty.
Keywords :
CMOS integrated circuits; flip-flops; hysteresis; radiation hardening (electronics); CMOS process; D-FF; DICE flip-flop; SER performance; SER reduction; alpha SER test results; edge-triggered flip-flop; neutron SER test results; performance penalty; pulsed-hysteresis-latch design; pulsed-latch design; size 20 nm; standard D-flip-flop; Clocks; Flip-flops; Hysteresis; Inverters; Latches; Neutrons; Standards; SER; Single-event; alpha; flip-flop; hardening-by-design; hysteresis; latch; neutron; pulsed-latch; soft error;
Conference_Titel :
Reliability Physics Symposium, 2014 IEEE International
Conference_Location :
Waikoloa, HI
DOI :
10.1109/IRPS.2014.6861095
