Single Event Latch-Up Hardening Using TCAD Simulations in 130 nm and 65 nm Embedded SRAM in Flash-Based FPGAs

Author

Rezzak, Nadia ; Jih-Jong Wang

Author_Institution

Microsemi SOC, San Jose, CA, USA

Volume

62

Issue

4

fYear

2015

fDate

Aug. 2015

Firstpage

1599

Lastpage

1608

Abstract

In this work 3D-TCAD simulation is used to investigate and harden single event latch-up (SEL) occurring in embedded SRAMs, in both 130 nm and 65 nm Flash-based Field Programmable Gate Arrays (FPGAs). The methodology to perform accurate SEL simulations on realistic designs suitable for high volume manufacturing is presented. One important new finding is that depending on the technology node, the number of SRAM cells included in the 3D structure significantly affects the SEL threshold. The number of SRAM cells needs to be optimized for accurate SEL prediction within a reasonable simulation time.The simulation results are validated using heavy ion and neutron data. After trade-off studies, process mitigation solutions are chosen to improve the SEL threshold in 65 nm and achieve immunity in neutron environment.

Keywords

SRAM chips; field programmable gate arrays; radiation hardening (electronics); semiconductor device manufacture; 3D TCAD simulation; SEL; TCAD simulations; embedded SRAM; flash-based FPGA; flash-based field programmable gate arrays; high volume manufacturing; single event latch-up hardening; size 130 nm; size 65 nm; Doping; Field programmable gate arrays; Integrated circuit modeling; Layout; SRAM cells; Three-dimensional displays; 3D-TCAD simulation; SRAMs; flash-based FPGA; single event latch-up;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/TNS.2015.2450210

Filename

7181742