Browsing by Subject "Hardening"

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    Reconfigurable hardened latch and flip-flop for FPGAs
    (IEEE, 2017-07) Ahangari, Hamzeh; Alouani, I.; Öztürk, Özcan; Niar, S.
    In this paper, we propose Joint Latch (JLatch) and Joint Flip-Flop (JFF), two novel reconfigurable structures which bring the reconfigurability of reliability to user latches and flip-flops (FFs) in reconfigurable devices such as FPGAs. Specifically, we implement two reconfigurable storage elements that exploit a trade-off between reliability and amount of available resources. In fault prone conditions, JLatch (or JFF) is configured in such a way that four pre-selected normal static latches (or FFs) are combined together at circuit level to form one hardened storage cell. Solution focuses on transient faults such as soft errors, where we show that critical charge is increased by at least three orders of magnitude (1000X) to practically bring immunity against any Single Event Upset (SEU). If four latches inside an FPGA logic block are far enough, it can effectively cope with Multiple Bit Upsets (MBUs) as well. Additionally, provided that special transistor sizing is applied (only necessary for some latch structures), JLatch and JFF take advantage of a novel self-correcting technique to correct any single fault immediately. Our solution provides reconfigurability of reliability with negligible performance and area overhead with only one (two) extra transistor(s) per latch (FF). The delay of this technique is less than the delay of conventional TMR (Triple Modular Redundancy) technique with a majority voter at output. © 2017 IEEE.
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    Register file reliability enhancement through adjacent narrow-width exploitation
    (IEEE, 2016-04) Ahangari, Hamzeh; Alouani, I.; Öztürk, Özcan; Niar, S.; Rivenq, A.
    Due to the increasing vulnerability of CMOS circuits, new generations of microprocessors require an inevitable focus on reliability issues. As the Register File (RF) constitutes a critical element within the processor pipeline, it is mandatory to enhance the RF reliability to develop fault tolerant architectures. This paper proposes Adjacent Register Hardened RF (ARH), a new RF architecture that exploits the adjacent byte-level narrow-width values for hardening registers at runtime. Registers are paired together by some special switches referred to as joiners. Dummy sign bits of each register are used to keep redundant data of its counterpart register. We use 7T/14T SRAM cell [6] to combine redundant bits together to make a single bit cell which is, by far, more resilient against faults. Our simulations show that with 3% to 12% power overhead and 10% to 20% increase in area, in comparison to baseline RF, we can obtain up to 80% reduction in soft error rate (SER). © 2016 IEEE.