Title :
Real time recovery of fault tolerant processing elements
Author_Institution :
The Draper Lab., Cambridge, MA, USA
fDate :
12/1/1997 12:00:00 AM
Abstract :
A critical problem in the design of ultra-reliable fault tolerant systems is that of how to bring a redundant member back on-line, after a transient fault, without degrading critical real-time functions. Recovery from transients is imperative to maintain necessary system reliability in the face of transient errors which have been estimated to occur at a rate of 5 to 100 times that of permanent failures. Excessive delays associated with recovery become a problem when as much as 1 Mbytes of RAM in the faulty processor must be made congruent with the processing majority while maintaining full functionality of critical, real-time control algorithms. This paper describes a hardware assisted recovery technique which uses memory “tags” to determine which memory segments need to be restored such that recovery can be performed incrementally without affecting real-time operational tasks. Also presented is performance data associated with this technique´s application to a Draper Laboratory quad-redundant processor responsible for vehicle control of a manned undersea vehicle
Keywords :
delays; fault tolerant computing; marine systems; random-access storage; real-time systems; redundancy; transients; transport control; 1 Mbyte; Draper Laboratory quad-redundant processor; RAM; critical real-time functions; delays; fault tolerant processing; manned undersea vehicle; performance data; real time recovery; real-time control algorithms; transient errors; transient fault; ultra-reliable fault tolerant systems; vehicle control; Degradation; Delay; Fault tolerance; Fault tolerant systems; Maintenance; Random access memory; Read-write memory; Real time systems; Reliability; Vehicles;
Journal_Title :
Aerospace and Electronic Systems Magazine, IEEE
