1 / 12

Chapter Fault Tolerant Design of Digital Systems

4.1 The Important of Fault Tolerance. Fault Tolerant design can provide dramatic improvements in system availability and lead to a substantial reduction in maintenance costs as a consequence of fewer system failures. Two different approaches to increase the reliability:Fault preventionFault to

sondra
Download Presentation

Chapter Fault Tolerant Design of Digital Systems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


    1. Chapter Fault Tolerant Design of Digital Systems

    2. 4.1 The Important of Fault Tolerance Fault Tolerant design can provide dramatic improvements in system availability and lead to a substantial reduction in maintenance costs as a consequence of fewer system failures. Two different approaches to increase the reliability: Fault prevention Fault tolerance

    3. 4.2 Basic Concepts of Fault Tolerance Fault tolerant system: it is a system which has the built-in capability (without external assistant) to preserve the continued correct execution of its programs and input/output functions in the present of a certain set of operational faults. Types of faults: anticipated faults unanticipated faults

    4. 4.3 Static Redundancy Also known as “masking redundancy” Two major techniques employed: Triple modular redundancy Use of error correcting codes 4.3.1 Triple Modular Redundancy (TMR) Could be expanded to NMR (N-modular-redundancy) An NMR system can tolerate up to n module failures, where n = (N-1)/2 In general, in an NMR system N is an odd number.

    5. 4.3.1 Triple Modular Redundancy (TMR) The Reliability equation of an NMR system is: For the TMR case N=3 and n=1

    6. 4.3.1 Triple Modular Redundancy (TMR) Note: Another way to calculate RTMR Exercise : Evaluate RTMR if RM = 0.6 and 0.5 and 0.4

    7. Reliability & MTBF & Failure rate For a constant failure rate, Thus, for TMR where

    8. We should look for a more useful parameter than MTBF. Other Parameters for evaluating system reliability Reliability Improvement Factor (RIF) = Where, 1-RN : probability of failure of non-redundant system. 1-RR : probability of failure of redundant system. Mission Time Improvement Factor (MTIF) = Where Rf is some predetermined reliability (e.g. 0.99 or 0.90), while TR and TN are times at which the system reliability RR(t) and RN(t), respectively, fall to the value Rf .

    9. The reliability of the voter element If the voter has the reliability , then the reliability of the TMR becomes: If , the reliability of the system is less than that of the original system for all t. Thus, we have to improve the reliability of the voter. where, Rv is the reliability of the voter.

    10. The major advantages of the TMR scheme Major advantages of the TMR are: The fault-masking action occurs immediately; both temporary and permanent faults are masked. No separate fault detection is necessary before masking. The conversion from a non-redundant system to a TMR system is straightforward.

    11. 4.4 Dynamic redundancy A system with dynamic redundancy consists of several modules but with only one operating at a time. If a fault is detected in the operating module it is switched out and replaced by a spare. It requires consecutive actions of fault detection and fault recovery. A dynamic redundant system with S spares has a reliability : where Rm is the reliability of each module, active or spare in the system. This reliability function is obtained assuming that the fault detection and the switchover mechanism are perfect.

    12. 4.4 Dynamic redundancy The reliability R is an increasing function of the number of spare modules. However, the use of too many spares may have a detrimental effect on the system reliability. Losq has shown that for every dynamic redundant system there exists a finite best number of spares for a given mission time: When the mission time is extremely short ? one spare is best. When the mission time is less than one-tenth of the simplex (i.e. non-redundant) mean-life ? five spares or fewer is the best.

    13. 4.4 Dynamic redundancy The detection of a fault in the individual modules of a dynamic system can be achieved by using one of the following techniques: Periodic tests: Offline. Disadvantage: cannot detect temporary faults unless they occur while the module is tested. Self-checking circuits: provide a very cost effective method of fault detection Watchdog timers: timer, checkpoints Reconfiguration: switching the faulty element and selecting the system output to come from one of the alternative modules. Retry: so that a module will not be removed because of a temporary fault. Self-repair: the replacement is invisible to the user and the system continues its operation uninterrupted. In general dynamic redundant systems can be divided into two categories: Cold-standby system. Hot-standby system.

More Related