Title :
Design Flow for Radhard TMR Flip-Flops
Author :
Petrovic, Vladimir ; Krstic, Milo
Author_Institution :
IHP, Frankfurt, Germany
Abstract :
Protection against radiation effects in digital ASICs chip can be achieved using different design approaches. One of the popular approaches for increasing the reliability is the hardware triplication. However, the hardware triplication does not mean that the susceptibility to radiation effects can be automatically overcome. The automatic random placement of standard cells can result in higher power consumption and more occupied silicon area), with marginal improvement of the linear energy transfer threshold (LET) value. Additionally, the TMR approach usually requires changes in the standard ASIC design flow, even requesting significant modifications of the RTL code. In this paper, we will investigate the issues of design flow for TMR flip-flops, addressing both the issues of compliance to the standard ASIC design methodology, enabling the use of non-modified RTL code, as well as the layout generation of radhard TMR flip-flops, based on standard non-hardened flip-flop components.
Keywords :
application specific integrated circuits; flip-flops; integrated circuit design; power consumption; radiation hardening (electronics); LET; RTL code; application-specific integrated circuit; automatic random placement; design flow; digital ASIC chip; hardware triplication; linear energy transfer threshold; power consumption; radhard TMR flip-flop; radiation effect; register-transfer level; triple modular redundancy; Clocks; Flip-flops; Libraries; Radiation effects; Standards; Transient analysis; Tunneling magnetoresistance; ASIC design flow; Single event effect; fault tolerance; radhard design; radiation effects; triple modular redundancy;
Conference_Titel :
Design and Diagnostics of Electronic Circuits & Systems (DDECS), 2015 IEEE 18th International Symposium on
Conference_Location :
Belgrade
Print_ISBN :
978-1-4799-6779-7
DOI :
10.1109/DDECS.2015.65
