Design of Double-Upset Recoverable and Transient-Pulse Filterable Latches for Low Power and Low-Orbit Aerospace Applications
Aibin Yan, Yan Chen, Zhelong Xu, Zhili Chen, Jie Cui, Zhengfeng Huang, Patrick Girard, Xiaoqing Wen
Abstract
To meet the requirements of both high reliability and low power in low-orbit aerospace applications, this article first presents a single-event Double-Upset (SEDU) self-Recoverable and single-event Transient (SET) Pulse Filterable (DURTPF) latch design with low power. The DURTPF latch mainly consists of eight mutually feeding-back C-elements (CEs) and an SET pulse filterable Schmitt-trigger (ST). To make an ST behave not only as a pulse filterable ST but also as an error interceptive CE, an input-split ST is created, leading to an enhanced-version of the DURTPF latch, namely DURTPF-EV. The DURTPF-EV latch mainly consists of seven mutually feeding-back CEs including an input-split ST. Simulation results demonstrate both the SEDU self-recoverability and SET pulse filterability of the proposed latches at the cost of moderate silicon area. Using the clock gating technology, the DURTPF latch reduces power dissipation by about 63% on average compared with the state-of-the-art SEDU self-recoverable latch designs that are not SET-pulse filterable. Moreover, the DURTPF-EV latch is more cost-effective and its reliability is also enhanced, making it more suitable for low power and low-orbit aerospace applications.