This paper presents a method for deriving requirements for the efficiency of diagnostic functions in distributed electronic turbofan engine control systems. Distributed engine control systems consist of sensor, actuator, and control unit nodes that exchange data over a communication network. The method is applicable to engine control systems that are partially redundant. Traditionally, turbofan engine control systems use dual channel solutions in which all units are duplicated. Our method is intended for analyzing the diagnostic requirements for systems in which a subset of the sensors and the actuators is nonredundant. Such systems rely on intelligent monitoring and analytical redundancy to detect and tolerate failures in the nonredundant units. These techniques cannot provide perfect diagnostic coverage and, hence, our method focuses on analyzing the impact of nonperfect diagnostic coverage on the reliability and safety of distributed engine control systems. The method is based on a probabilistic analysis that combines fault trees and Markov chains. The input parameters for these models include failure rates as well as several coverage factors that characterize the performance of the diagnostic functions. Since the use of intelligent monitoring can cause false alarms, i.e., an error is falsely indicated by a diagnostic function, the parameters also include a false alarm rate. The method was used to derive the diagnostic requirements for a hypothetical unmanned aerial vehicle engine control system. Given the requirement that an engine failure due to the control system is not allowed to occur more than ten times per million hours, the diagnostic functions in a node must achieve 99% error coverage for transient faults and 90–99% error coverage for permanent faults. The system-level diagnosis must achieve 90–95% detection coverage for node failures, which are not detected by the nodes themselves. These results are based on the assumption that transient faults are 100 times more frequent than permanent faults. It is important to have a method for deriving probabilistic requirements on diagnostic functions for engine control systems that rely on analytical redundancy as a means to reduce the hardware redundancy. The proposed method allows us to do this using an existing tool (FAULTTREE+) for safety and reliability analysis.
Skip Nav Destination
e-mail: olof.hannius@volvo.com
e-mail: dan.ring@volvo.com
e-mail: johan@ce.chalmers.se
Article navigation
March 2008
Research Papers
Derivation of Diagnostic Requirements for a Distributed UAV Turbofan Engine Control System
Olof Hannius,
Olof Hannius
Performance and Control Systems,
e-mail: olof.hannius@volvo.com
Volvo Aero Corporation
, 461 81 Trollhättan, Sweden
Search for other works by this author on:
Dan Ring,
Dan Ring
Performance and Control Systems,
e-mail: dan.ring@volvo.com
Volvo Aero Corporation
, 461 81 Trollhättan, Sweden
Search for other works by this author on:
Johan Karlsson
Johan Karlsson
Department of Computer Science and Engineering,
e-mail: johan@ce.chalmers.se
Chalmers University of Technology
, 412 96 Göteborg, Sweden
Search for other works by this author on:
Olof Hannius
Performance and Control Systems,
Volvo Aero Corporation
, 461 81 Trollhättan, Swedene-mail: olof.hannius@volvo.com
Dan Ring
Performance and Control Systems,
Volvo Aero Corporation
, 461 81 Trollhättan, Swedene-mail: dan.ring@volvo.com
Johan Karlsson
Department of Computer Science and Engineering,
Chalmers University of Technology
, 412 96 Göteborg, Swedene-mail: johan@ce.chalmers.se
J. Eng. Gas Turbines Power. Mar 2008, 130(2): 021602 (11 pages)
Published Online: January 22, 2008
Article history
Received:
July 14, 2006
Revised:
July 6, 2007
Published:
January 22, 2008
Citation
Hannius, O., Ring, D., and Karlsson, J. (January 22, 2008). "Derivation of Diagnostic Requirements for a Distributed UAV Turbofan Engine Control System." ASME. J. Eng. Gas Turbines Power. March 2008; 130(2): 021602. https://doi.org/10.1115/1.2795776
Download citation file:
Get Email Alerts
Cited By
Shape Optimization of an Industrial Aeroengine Combustor to reduce Thermoacoustic Instability
J. Eng. Gas Turbines Power
Dynamic Response of A Pivot-Mounted Squeeze Film Damper: Measurements and Predictions
J. Eng. Gas Turbines Power
Review of The Impact Of Hydrogen-Containing Fuels On Gas Turbine Hot-Section Materials
J. Eng. Gas Turbines Power
Effects of Lattice Orientation Angle On Tpms-Based Transpiration Cooling
J. Eng. Gas Turbines Power
Related Articles
Experiments on Active Vibration Control of a Flexible Four-Bar Linkage Mechanism
J. Vib. Acoust (January,2000)
Decentralized Feedback Control of Pumping Losses and NO x Emissions in Diesel Engines
J. Eng. Gas Turbines Power (October,2018)
On the Uniqueness of Solutions for the Identification of Linear Structural Systems
J. Appl. Mech (January,2006)
Development of an Automatic Adjustable Colonoscope
J. Med. Devices (December,2011)
Related Chapters
Constructing Dynamic Event Trees from Markov Models (PSAM-0369)
Proceedings of the Eighth International Conference on Probabilistic Safety Assessment & Management (PSAM)
Evaluation of the Analytical Bottom-Up SIL Proof by Statistical Top-Down Methods (PSAM-0242)
Proceedings of the Eighth International Conference on Probabilistic Safety Assessment & Management (PSAM)
Research on Automatic Cross Section Cutting and Forming Control in Coal Mine Underground Based on Oil Cylinder Stroke Sensor and PCC Electrical Control System
International Conference on Mechanical Engineering and Technology (ICMET-London 2011)