Artificial neural networks for fault diagnosis, modelling and control of diesel engines

Mesbahi, Ehsan

January 2000

No description available.

621.43

Sensor validation; Fault diagnosis

The relative phase distortion detection technique

Goodhall, Anthony John

January 1994

No description available.

620.00452

Fault detection; Visual inspection

Intelligent methods of power system components monitoring by artificial neural networks and optimisation using evolutionary computing techniques

Wong, Kam Cheung

January 1999

No description available.

621.31042

Genetic algorithm; Fault detection

Development of a fault tolerant flight control system

Feldstein, Cary Benjamin.

10 April 2008

No description available.

Flight control

Fault-tolerant computing

Reconfiguration under failure of the brushless d.c. motor

McWilliam, Charles J.

January 1998

No description available.

621.31042

Synchronous; Fault tolerance; Simulation

Fault recovery in process control

Horn, Timothy Andrew

05 February 2015

Fault Recovery in process control requires effective fault detection, diagnosis and recovery schemes, and a fault-tolPi-ant system design. Fault detection and diagnosis involves creating a realistic model of the process, and using this model to analyse for fault conditions. The fault detection principles include feature extraction and pattern recognition, and analogue value limits and rate cf change limits. Fault recovery scheme? cover the realisation of redundancy ana back-up sub-systems, and state restoration techniques in the form of complete shutdowns, backward and forward recovery to a safe operating state. System design concepts include for the development of process control systems towards *hierarchical, level based distribution of functions. The level-based discussion is used as the basis for effective fault tolerant system design. Two case studies are included to show how fault recovery schemes were effected in a single process computer and in a distributed control system. Abstract

Process control

Fault location (Engineering)

Stochastic fault simulation of triple-modular redundant asynchronous pipeline circuits

Lynch, John Daniel

10 1900

Ph.D. / Electrical Engineering / The expected unreliability of nano-scale electronic components has renewed interest in the decades-old field of fault-tolerant logic design. Fault-tolerant design makes it possible to build reliable systems from unreliable components. This has spurred recent research into the application of classical FT techniques to nanoelectronics. Meanwhile, the growing gap between logic gate and wire delays, and the growing power consumption of clock generation and distribution circuits, in nanometer-scale silicon integrated circuits has renewed research in asynchronous, or clockless, logic design. This dissertation examines the application of triple modular redundancy (TMR), one of several FT circuit design techniques, to improve the reliability of a variety of clockless circuits and systems. A new fault model, appropriate for clockless circuits is derived and applied to measure the reliability of nonredundant and triplex micropipelines. A new circuit element that combines the functionality of a Muller C-element and a majority gate is introduced to solve special problems at the simplex-triplex interface. The effectiveness of asynchronous FT circuit design strategies based on the results of Monte Carlo simulation experiments with representative circuits modeled in Verilog hardware description language (HDL) is presented.

Defect site prediction based upon statistical analysis of fault signatures

Trinka, Michael Robert

30 September 2004

Good failure analysis is the ability to determine the site of a circuit defect quickly and accurately. We propose a method for defect site prediction that is based on a site's probability of excitation, making no assumptions about the type of defect being analyzed. We do this by analyzing fault signatures and comparing them to the defect signature. We use this information to construct an ordered list of sites that are likely to be the site of the defect.

defect

testing

circuit

fault

diagnosis

Design and analysis of robust algorithms for fault tolerant computing

Jang, Jai Eun

04 April 1990

Graduation date: 1990

Algorithms

Multiprocessors

Fault-tolerant computing

Empirical timing analysis of CPUs and delay fault tolerant design using partial redundancy

Chang, Sanghoan

15 May 2009

The operating clock frequency is determined by the longest signal propagation delay, setup/hold time, and timing margin. These are becoming less predictable with the increasing design complexity and process miniaturization. The difficult challenge is then to ensure that a device operating at its clock frequency is error-free with quantifiable assurance. Effort at device-level engineering will not suffice for these circuits exhibiting wide process variation and heightened sensitivities to operating condition stress. Logic-level redress of this issue is a necessity and we propose a design-level remedy for this timing-uncertainty problem. The aim of the design and analysis approaches presented in this dissertation is to provide framework, SABRE, wherein an increased operating clock frequency can be achieved. The approach is a combination of analytical modeling, experimental analy- sis, hardware /time-redundancy design, exception handling and recovery techniques. Our proposed design replicates only a necessary part of the original circuit to avoid high hardware overhead as in triple-modular-redundancy (TMR). The timing-critical combinational circuit is path-wise partitioned into two sections. The combinational circuits associated with long paths are laid out without any intrusion except for the fan-out connections from the first section of the circuit to a replicated second section of the combinational circuit. Thus only the second section of the circuit is replicated. The signals fanning out from the first section are latches, and thus are far shorter than the paths spanning the entire combinational circuit. The replicated circuit is timed at a subsequent clock cycle to ascertain relaxed timing paths. This insures that the likelihood of mistiming due to stress or process variation is eliminated. During the subsequent clock cycle, the outcome of the two logically identical, yet time-interleaved, circuit outputs are compared to detect faults. When a fault is detected, the retry sig- nal is triggered and the dynamic frequency-step-down takes place before a pipe flush, and retry is issued. The significant timing overhead associated with the retry is offset by the rarity of the timing violation events. Simulation results on ISCAS Benchmark circuits show that 10% of clock frequency gain is possible with 10 to 20 % of hardware overhead of replicated timing-critical circuit.

Timing

Delay

FMAX

Fault tolerant