Optimized reconfigurable autopilot design for an aerospace CPS

Arsalan H. Khan; Zeashan H. Khan; Salman H. Khan

doi:10.1007/978-981-4585-36-1_13

Optimized reconfigurable autopilot design for an aerospace CPS

Arsalan H. Khan^*
, Zeashan H. Khan
, Salman H. Khan

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

7 Scopus citations

Abstract

A modular flight control strategy is presented here to demonstrate the improved command tracking performance with fault tolerance and reconfiguration capabilities. The modular control design process consists of inner and outer loop design concept, where outer baseline controller feedback loop ensures the stability and robustness and inner reconfigurable design is responsible for the fault-tolerance against actuator faults/failures. This guarantees augmented autonomy and intelligence on board aircraft for real time decision and fault tolerant control. Requirements for aerospace cyber physical systems (ACPS) and software are far more stringent than those found in industrial automation systems. The results shows that fault tolerant aspect is mandatory for ACPS, that must support real time behavior and also requires ultra-high reliability as many systems or/sub-systems are safety critical and require certification.

Original language	English
Title of host publication	Computational Intelligence for Decision Support in Cyber-Physical Systems
Publisher	Springer Verlag
Pages	381-420
Number of pages	40
ISBN (Print)	9789814585354
DOIs	https://doi.org/10.1007/978-981-4585-36-1_13
State	Published - 2014
Externally published	Yes

Publication series

Name	Studies in Computational Intelligence
Volume	540
ISSN (Print)	1860-949X

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

ASJC Scopus subject areas

Artificial Intelligence

Access to Document

10.1007/978-981-4585-36-1_13

Cite this

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abstract = "A modular flight control strategy is presented here to demonstrate the improved command tracking performance with fault tolerance and reconfiguration capabilities. The modular control design process consists of inner and outer loop design concept, where outer baseline controller feedback loop ensures the stability and robustness and inner reconfigurable design is responsible for the fault-tolerance against actuator faults/failures. This guarantees augmented autonomy and intelligence on board aircraft for real time decision and fault tolerant control. Requirements for aerospace cyber physical systems (ACPS) and software are far more stringent than those found in industrial automation systems. The results shows that fault tolerant aspect is mandatory for ACPS, that must support real time behavior and also requires ultra-high reliability as many systems or/sub-systems are safety critical and require certification.",

author = "Khan, \{Arsalan H.\} and Khan, \{Zeashan H.\} and Khan, \{Salman H.\}",

year = "2014",

doi = "10.1007/978-981-4585-36-1\_13",

language = "English",

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AU - Khan, Zeashan H.

AU - Khan, Salman H.

PY - 2014

Y1 - 2014

N2 - A modular flight control strategy is presented here to demonstrate the improved command tracking performance with fault tolerance and reconfiguration capabilities. The modular control design process consists of inner and outer loop design concept, where outer baseline controller feedback loop ensures the stability and robustness and inner reconfigurable design is responsible for the fault-tolerance against actuator faults/failures. This guarantees augmented autonomy and intelligence on board aircraft for real time decision and fault tolerant control. Requirements for aerospace cyber physical systems (ACPS) and software are far more stringent than those found in industrial automation systems. The results shows that fault tolerant aspect is mandatory for ACPS, that must support real time behavior and also requires ultra-high reliability as many systems or/sub-systems are safety critical and require certification.

AB - A modular flight control strategy is presented here to demonstrate the improved command tracking performance with fault tolerance and reconfiguration capabilities. The modular control design process consists of inner and outer loop design concept, where outer baseline controller feedback loop ensures the stability and robustness and inner reconfigurable design is responsible for the fault-tolerance against actuator faults/failures. This guarantees augmented autonomy and intelligence on board aircraft for real time decision and fault tolerant control. Requirements for aerospace cyber physical systems (ACPS) and software are far more stringent than those found in industrial automation systems. The results shows that fault tolerant aspect is mandatory for ACPS, that must support real time behavior and also requires ultra-high reliability as many systems or/sub-systems are safety critical and require certification.

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M3 - Chapter

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EP - 420

BT - Computational Intelligence for Decision Support in Cyber-Physical Systems

PB - Springer Verlag

ER -

Optimized reconfigurable autopilot design for an aerospace CPS

Abstract

Publication series

UN SDGs

ASJC Scopus subject areas

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