A High Performance and Low Power Triple-Node-Upset Self-Recoverable Latch Design

Abstract

The charge sharing effect is becoming increasingly severe due to the continuous reduction of semiconductor process feature size. In the nanoscale digital circuit, the probability of triple-node upset (TNU) is increasing, which seriously affects the reliability of the circuit. To improve the reliability of the digital circuit, this paper presents an optimized TNU self-recoverable latch (HLTNURL). This latch consists of three dual-node-self-recoverable dual interlocked storage cells (DNSR-DICE) and one clock-gating C-element. Whenever any three nodes invert, the latch is able to self-recover to its correct logical values. The HSPICE simulation results indicate that this latch enables full self-recovery of TNU in all cases. In comparison with existing TNU self-recoverable latches, the proposed HLTNURL latch is able to reduce the power dissipation, delay, area overhead, and area-power-delay product (APDP) by 32.41%, 79.73%, 1.32%, and 88% on average. In addition, the HLTNURL latch proposed in this paper has high reliability and low sensitivity to process, voltage, and temperature (i.e., PVT) variations.