A multi–objective evolutionary algorithm is used in the framework of H1 control theory to find the controller gains that minimize a weighted combination of the infinite–norm of the sensitivity function (for disturbance attenuation requirements) and complementary sensitivity function (for robust stability requirements). After considering a single operating point for a level flight trim condition of a F-16 fighter aircraft model, two different approaches will then be considered to extend the domain of validity of the control law: 1) the controller is designed for different operating points and gain scheduling is adopted; 2) a single control law is designed for all the considered operating points by multiobjective minimisation. The two...
A multi-model multi-criteria vector optimisation technique based on the minimisation of the Kreissel...
An evolutionary optimisation method for Multidisciplinary Design Optimisation (MDO) and aircraft sys...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/90725/1/AIAA-2011-6256-879.pd
A multi–objective evolutionary algorithm is used in the framework of H1 control theory to find the ...
The use of an evolutionary algorithm in the framework of H1 control theory is being considered as a ...
The use of an evolutionary algorithm in the framework of H∞ control theory is being considered as a ...
The emerging paradigm of grid computing provides a powerful platform for the solution of complex and...
In a physical system several targets are normally being considered in which each of nominal and robu...
This thesis presents one of the first applications of H∞-optimization to the design of controllers f...
In this paper the adaption of the software environment ’Multi-Objective Parameter Synthesis’ (MOPS) ...
A leading cause of accidents during the landing phase of a flight lies in a considerable altitude lo...
This article proposes a linear matrix inequality–based robust controller design approach to implemen...
An evolutionary algorithm approach is proposed for the robust design of control systems. The evoluti...
Bu çalışma ile, verilen bir kontrolcü yapısı için çelişen hedeflerin aynı anda sağlanabileceği kontr...
When designing an aircraft engineers are usually given a design or set of design points especially o...
A multi-model multi-criteria vector optimisation technique based on the minimisation of the Kreissel...
An evolutionary optimisation method for Multidisciplinary Design Optimisation (MDO) and aircraft sys...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/90725/1/AIAA-2011-6256-879.pd
A multi–objective evolutionary algorithm is used in the framework of H1 control theory to find the ...
The use of an evolutionary algorithm in the framework of H1 control theory is being considered as a ...
The use of an evolutionary algorithm in the framework of H∞ control theory is being considered as a ...
The emerging paradigm of grid computing provides a powerful platform for the solution of complex and...
In a physical system several targets are normally being considered in which each of nominal and robu...
This thesis presents one of the first applications of H∞-optimization to the design of controllers f...
In this paper the adaption of the software environment ’Multi-Objective Parameter Synthesis’ (MOPS) ...
A leading cause of accidents during the landing phase of a flight lies in a considerable altitude lo...
This article proposes a linear matrix inequality–based robust controller design approach to implemen...
An evolutionary algorithm approach is proposed for the robust design of control systems. The evoluti...
Bu çalışma ile, verilen bir kontrolcü yapısı için çelişen hedeflerin aynı anda sağlanabileceği kontr...
When designing an aircraft engineers are usually given a design or set of design points especially o...
A multi-model multi-criteria vector optimisation technique based on the minimisation of the Kreissel...
An evolutionary optimisation method for Multidisciplinary Design Optimisation (MDO) and aircraft sys...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/90725/1/AIAA-2011-6256-879.pd