Title :
Minimalist recovery techniques for single event effects in spaceborne microcontrollers
Author :
Caldwell, D.W. ; Rennels, D.A.
Author_Institution :
California Univ., Los Angeles, CA, USA
Abstract :
This paper presents a fault-tolerant design approach to allow the use of non-hardened commodity microcontrollers as embedded computing nodes in spacecraft, where a high rate of transient errors and occasional latch ups are expected due to the space radiation environment. In order to preserve their primary advantage of high functional density, low-cost approaches were explored that leverage features of existing commercial microcontrollers. A built-in, high-speed serial port is used for voting among redundant devices and a novel wire-OR output voting scheme exploits the bidirectional controls of I/O pins. A fault-tolerant node testbed was implemented, and fault-insertion tests were conducted to test the effectiveness of the fault-tolerance techniques.
Keywords :
aerospace computing; embedded systems; fault tolerant computing; microcontrollers; system recovery; bidirectional controls; commodity microcontrollers; embedded computing; fault-insertion tests; fault-tolerant design; high-speed serial port; input output pins; latch ups; minimalist recovery techniques; single event effects; space radiation; spaceborne microcontrollers; spacecraft; transient error; voting scheme; Bidirectional control; Circuit faults; Fault tolerance; Microcontrollers; Pins; Radiation hardening; Single event upset; Space vehicles; Testing; Voting;
Conference_Titel :
Dependable Computing for Critical Applications 7, 1999
Conference_Location :
San Jose, CA, USA
Print_ISBN :
0-7695-0284-9
DOI :
10.1109/DCFTS.1999.814289
