Your search keyword '"Mixed sensitivity"' showing total 50 results

1. Research on the Current Control Strategy of a Brushless DC Motor Utilizing Infinite Mixed Sensitivity Norm.

Author

Yuan, Tianqing, Chang, Jiu, and Zhang, Yupeng

Subjects

ROBUST control, BRUSHLESS electric motors, ACTIVE noise control, TRANSFER functions

Abstract

During the brushless DC (BLDC) motor working process, the system encounters inevitable uncertainties. These ambiguities stem from potential fluctuations, random occurrences, measurement inaccuracies, varying operational conditions, environmental shifts such as temperature alterations, among other factors. Uncertainties, an inherent aspect of any real control system, can be broadly classified into two categories: sensor signal uncertainties and discrepancies between the mathematical and actual models due to parameter perturbations. To mitigate the impact of sensor noise and parameter perturbations on the BLDC motor, a robust control strategy utilizing infinite norm mixed sensitivity based on PI control strategy (PI-H∞-MIX) is proposed in this paper. Firstly, the closed-loop control structure and transfer function model of the BLDC motor control system current loop are analyzed based on the current loop circuit topology, and then, the model parameters perturbation is analyzed, and the multiplicative uncertainty bound is given. In addition, the appropriate weighting function is selected to ensure the robustness of the system. In this case, the controller design problem is transformed into the H∞ standard control problem, and then, the system augmentation matrix is established, and the controller is solved by Matlab/Simulink. Finally, the performances of the traditional PI control strategy and the PI-H∞-MIX are compared and analyzed. The results show that (1) the proposed PI-H∞-MIX strategy can improve the control system robustness under the parameter perturbation condition effectively, and (2) the proposed PI-H∞-MIX strategy can suppress the noise signal of the sensor. [ABSTRACT FROM AUTHOR]

Published

2023

2. New Insights on Robust Control of Tilting Trains with Combined Uncertainty and Performance Constraints.

Author

Hassan, Fazilah, Zolotas, Argyrios, and Halikias, George

Subjects

*ROBUST control, *ROBUST optimization

Abstract

A rigorous study on optimized robust control is presented for non-preview (nulling-type) high-speed tilting rail vehicles. The scheme utilizes sensors on the vehicle's body, contrary to that of preview tilt (which uses prior rail track information). Tilt with preview is the industrial norm nowadays but is a complex scheme (both in terms of inter-vehicle signal connections and when it comes to straightforward fault detection). Non-preview tilt is simple (as it essentially involves an SISO control structure) and more effective in terms of (the localization of) failure detection. However, the non-preview tilt scheme suffers from performance limitations due to non-minimum-phase zeros in the design model (due to the compound effect of the suspension dynamic interaction and sensor combination used for feedback control) and presents a challenging control design problem. We proposed an optimized robust control design offering a highly improved non-preview tilt performance via a twofold model representation, i.e., (i) using the non-minimum phase design model and (ii) proposing a factorized design model version with the non-minimum phase characteristics treated as uncertainty. The impact of the designed controllers on tilt performance deterministic (curving acceleration response) and stochastic (ride quality) trade-off was methodically investigated. Nonlinear optimization was employed to facilitate fine weight selection given the importance of the ride quality as a bounded constraint in the design process. [ABSTRACT FROM AUTHOR]

Published

2023

3. Research on H∞ adaptive control of aero-engine based on RBF neural network compensation

Author

XUE Hongyang, CAI Kailong, LI Huangqi, and PU Zhigang

Subjects

aero-engine, multi-variable control, uncertainty, mixed sensitivity, rbf neural network compensation, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

Aero-engine control system is an important mechanism of aircraft, the uncertainty of control gain attenuation and unmodeled dynamics of aero-engine can affect its control performance, therefore, a controller combining H∞ adaptive control and compensation control is designed.Firstly, the H∞ adaptive controller is designed based on the mixed sensitivity theory.And then, based on Lyapunov strict stability theory, the radial basis function (RBF)neural network compensation controller is designed to compensate the uncertainty, and the fitting speed is adjusted by the linear function related to the error.Finally, the normalized aero-engine model is taken as the controlled object to carry out the multi-variable simulation test.The results show that the adaptive controller designed in this paper can effectively compensate the uncertainty and reduce the overshoot and adjusting time compared with the H∞controller.

Published

2023

4. Improvement in Position Response of Laser Focus Controlled Magnetic Actuator Based on Mixed Sensitivity Robust Control.

Author

Wu, Liping, Tong, Ling, Yang, Guang, Zhang, Qi, Xu, Fangchao, Jin, Junjie, Zhang, Xiaoyou, and Sun, Feng

Subjects

MAGNETIC actuators, ROBUST control, MAGNETIC control, LASER beam cutting, LASER beams, NOZZLES

Abstract

The relative position between the laser beam and the nozzle is controlled by laser-focus-controlled magnetic actuators to achieve non-coaxial laser cutting and improve laser cutting efficiency. In this paper, a 3-DOF (degrees of freedom) magnetic actuator is designed to solve the inconsistency of the laser beam focus and the nozzle focus in off-axis laser cutting. A mixed sensitivity robust controller is designed, and its simulation analysis and experimental research are carried out. First, the kinetic mathematical equations are established according to the structure of the actuator. Then, a mixed sensitivity robust controller is designed and analyzed using MATLAB/Simulink. The control performance is simulated and analyzed under 20% parameter variation and pulse disturbance with an uncertain mathematical model and external disturbance, respectively. Finally, the experimental study of the step response of the actuator is carried out. The experimental results show that the step response of the actuator in the Y, X, and θ directions can quickly reach the steady-state value. Furthermore, the steady-state error in the X is 1.6%; the steady-state error in the Y is 0.39%; the steady-state error in the θ is 0.45%. Their errors are all less than 0.025 mm, so they meet the position performance requirements. It can provide technical support for laser off-axis cutting. [ABSTRACT FROM AUTHOR]

Published

2023

5. Review of H∞ Static Output Feedback Controller Synthesis Methods: Application to Fighter Aircraft Control

Author

Schoon, Daam (author) and Schoon, Daam (author)

Abstract

To gain more insight into the performance of state-of-the-art Static Output Feedback (SOF) controller synthesis methods for H∞-control, quantitative comparisons are made between Lyapunov methods and well-known established non-smooth optimization methods, i.e. Hinfstruct and HIFOO. Three methods were deemed to be the most promising to compete and were bundled into one toolbox named SOFHi. The algorithms were extended to incorporate structured SOF and a variant of SOFHi was proposed to significantly improve upon the computational efficiency of the original implementation. Extensive comparisons show that SOFHi was able to compete with the established non-smooth methods and even able to significantly outperform one of them. Lastly, an elaborate flight control benchmark example is given to showcase the effectiveness of the algorithms, which involves the design of a gain-scheduled normal acceleration Control Augmentation System (CAS) for a highly maneuverable fighter aircraft., Aerospace Engineering

Published

2024

6. New Insights on Robust Control of Tilting Trains with Combined Uncertainty and Performance Constraints

Author

Fazilah Hassan, Argyrios Zolotas, and George Halikias

Subjects

tilting trains, robust control, optimization, mixed sensitivity, robust performance, active suspensions, Mathematics, QA1-939

Abstract

A rigorous study on optimized robust control is presented for non-preview (nulling-type) high-speed tilting rail vehicles. The scheme utilizes sensors on the vehicle’s body, contrary to that of preview tilt (which uses prior rail track information). Tilt with preview is the industrial norm nowadays but is a complex scheme (both in terms of inter-vehicle signal connections and when it comes to straightforward fault detection). Non-preview tilt is simple (as it essentially involves an SISO control structure) and more effective in terms of (the localization of) failure detection. However, the non-preview tilt scheme suffers from performance limitations due to non-minimum-phase zeros in the design model (due to the compound effect of the suspension dynamic interaction and sensor combination used for feedback control) and presents a challenging control design problem. We proposed an optimized robust control design offering a highly improved non-preview tilt performance via a twofold model representation, i.e., (i) using the non-minimum phase design model and (ii) proposing a factorized design model version with the non-minimum phase characteristics treated as uncertainty. The impact of the designed controllers on tilt performance deterministic (curving acceleration response) and stochastic (ride quality) trade-off was methodically investigated. Nonlinear optimization was employed to facilitate fine weight selection given the importance of the ride quality as a bounded constraint in the design process.

Published

2023

7. H∞ Control law for line of sight stabilization in two-axis gimbal system.

Author

Ashok Kumar, M and Kanthalakshmi, S

Subjects

*AERODYNAMIC load, *DIGITAL signal processing

Abstract

A two-axis gimbaled stabilization system in air vehicles must stabilize the line of sight of the payload toward a target against the external motion induced by air vehicle maneuvering and aerodynamic forces. The target tracking and pointing performances of the air vehicles are largely affected by air vehicle motion decoupling capability. In this work, the H ∞ controller design is carried out for a two-axis gimbal system. The plant model is generated using experimental frequency response data and mathematical formulation of the system. The mixed sensitivity problem is posed and weighting functions are selected so that they not only fulfill all the design goals but also accommodate the modeling uncertainties. The stabilization loop is designed and implemented in digital signal processor-based hardware for only one axis (in azimuth). [ABSTRACT FROM AUTHOR]

Published

2022

8. Mixed sensitivity control: a non-iterative approach

Author

R. Galindo Orozco

Subjects

robust control, robust stability, robust performance, mixed sensitivity, stabilizing controllers, unstructured uncertainty, sub-optimal control, γ-iteration, Control engineering systems. Automatic machinery (General), TJ212-225, Systems engineering, TA168

Abstract

Recent analytical solutions to Mixed Sensitivity Control (MSC) are developed and compared with standard MSC based on γ-iteration. The proposed MSC solution gives conditions for strong stability and overcomes the pole-zero cancellations between the plant and the controller of non-iterative solutions, keeping the low-computational effort advantage of non-iterative solutions. The proposed MSC is based on the minimization of the most common closed-loop sensitivity functions in low-frequencies and the free-parameters of the stabilizing-controllers solve an algebraic equation of restriction that assigns the same value to the infinity-norms of the sensitivity functions at low and high-frequencies, guaranteeing robust stability and robust performance. It is assumed that the plant state dimension is double the plant input dimension and that the linear time-invariant nominal plant has a stabilizable and detectable realization and is strongly stabilizable. This MSC problem is solved in a one-parameter observer-controller configuration and reference tracking-control of positions is realized on a two-degrees of freedom feedback-configuration. An approximated optimal value of the location of the closed-loop poles is proposed based on Glover and McFarlane's optimal stability margin [(1989)] which in turn is based on Nehari's Theorem. Simulations of a mechanical system illustrate the results.

Published

2020

9. A Novel H∞ Robust Control Strategy for Voltage Source Inverter in Microgrid

Author

Hongtao Shi, Jie zhang, Jian Zhou, Yifan Li, and Zhongnan Jiang

Subjects

H∞ robust control, mixed sensitivity, parameter perturbation, voltage stability, adaptive virtual impedance group, General Works

Abstract

The voltage control performance of the voltage source inverter (VSI) in a microgrid may change under different load conditions. However, in the case of traditional control strategies, the robustness of VSI is insufficient. In response to the above problems, a novel robust control scheme for VSI in the microgrid based on H∞ hybrid sensitivity is proposed in this study. The grid-side interference during the VSI operation is taken as the variable, and the sensitivity function is designed to build a H∞ robust voltage controller for VSI. In addition, an adaptive virtual impedance group is designed to further improve the voltage control robustness under a variety of operation conditions. Finally, comparative simulation experiments are carried out to verify the anti-interference ability of the proposed control strategy under different working conditions.

Published

2021

10. Improvement in Position Response of Laser Focus Controlled Magnetic Actuator Based on Mixed Sensitivity Robust Control

Author

Liping Wu, Ling Tong, Guang Yang, Qi Zhang, Fangchao Xu, Junjie Jin, Xiaoyou Zhang, and Feng Sun

Subjects

electromagnetic drive, mixed sensitivity, robust control, differential control, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

The relative position between the laser beam and the nozzle is controlled by laser-focus-controlled magnetic actuators to achieve non-coaxial laser cutting and improve laser cutting efficiency. In this paper, a 3-DOF (degrees of freedom) magnetic actuator is designed to solve the inconsistency of the laser beam focus and the nozzle focus in off-axis laser cutting. A mixed sensitivity robust controller is designed, and its simulation analysis and experimental research are carried out. First, the kinetic mathematical equations are established according to the structure of the actuator. Then, a mixed sensitivity robust controller is designed and analyzed using MATLAB/Simulink. The control performance is simulated and analyzed under 20% parameter variation and pulse disturbance with an uncertain mathematical model and external disturbance, respectively. Finally, the experimental study of the step response of the actuator is carried out. The experimental results show that the step response of the actuator in the Y, X, and θ directions can quickly reach the steady-state value. Furthermore, the steady-state error in the X is 1.6%; the steady-state error in the Y is 0.39%; the steady-state error in the θ is 0.45%. Their errors are all less than 0.025 mm, so they meet the position performance requirements. It can provide technical support for laser off-axis cutting.

Published

2022

11. LIGHTWEIGHT OPTIMIZATION DESIGN OF BODY-IN-WHITE BASED ON NSGA-II MIXED SENSITIVITY ANALYSIS

Author

ZHAO ShuEn, YANG MingSen, and PENG GuangXu

Subjects

Body-in-white, Lightweight design, Mixed sensitivity, Multi-objective optimization, Mechanical engineering and machinery, TJ1-1570, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

With the problem of lightweight for body-in-white, a parametric optimization method based on mixed sensitivity analysis was proposed. The bending stiffness and modal properties of body-in-white were calibrated through the finite element simulation. Then the model was used to do mixed sensitivity analysis about stiffness and modal by experiment design, and related parts that have little influence on stiffness and modal properties were screened out. Takes thickness of related parts as design variables, the body-in-white quality and bending and torsion stiffness as the optimization targets, modal properties as constraint. The body-in-white lightweight of multi-objective optimization design was carried out by NSGA-II. Then simulate calculation was carried out by Isight to optimize the thickness of those parts, so as to realize the lightweight optimization design of the body-in-white structure. The simulation results show that its stiffness and modal performance were guaranteed after the parametric optimization, and the weight of the body-in-white was reduced by 5.7% of the original structure.

Published

2019

12. H∞ mixed sensitivity robust control method of relay ICPT system for output voltage regulation.

Author

Wu, Xiaokang, Xu, Chong, Wei, Bin, Xia, Chenyang, and Li, Xinyu

Subjects

*ROBUST control, *VOLTAGE

Abstract

Aiming at the problem that the output voltage of relay inductive coupled power transfer (ICPT) system is susceptible to changes due to the influence of system load changes, frequency perturbations, and input voltage fluctuations, an H∞ mixed sensitivity robust control method is adopted to relay ICPT system to regulate the output voltage. First, the working principle of the relay ICPT system is analyzed. Then, the GSSA model of the relay ICPT system is established. By constructing the S/R/T mixed sensitivity function, a suitable weighting function is selected from the frequency domain perspective and converted into H∞ standard control problem to get a robust controller. Finally, an experimental platform is built to verify the control effect of the controller on the system output voltage. Experimental results show that the designed controller in this paper stabilizes the system output voltage and obtains good tracking performance, suppression parameter perturbation performance, anti-interference performance, and improves system robustness simultaneously. [ABSTRACT FROM AUTHOR]

Published

2021

13. POLE PLACEMENT AND MIXED SENSITIVITY OF LTI MIMO SYSTEMS HAVING CONTROLLED OUTPUTS DIFFERENT FROM MEASUREMENTS.

Author

FIORES, MIGUEL A. and GALINDO, RENÉ

Subjects

POLE assignment, MIMO systems, ROBUST control, TRACKING control systems, DIOPHANTINE equations

Abstract

Multi-Input Multi-Output (MIMO) Linear Time-Invariant (LTI) controllable and observable systems where the controller has access to some plant outputs but not others are considered. Analytical expressions of coprime factorizations of a given plant, a solution of the Diophantine equation and the two free parameters of a two-degrees of freedom (2DOF) controller based on observer stabilizing control are presented solving a pole placement problem, a mixed sensitivity criterion, and a reference tracking problem. These solutions are based on proposed stabilizing gains solving a pole placement problem by output feedback. The proposed gains simplify the coprime factorizations of the plant and the controller, and allow assigning a decoupled characteristic polynomial. The 2DOF stabilizing control is based on the Parameterization of All Stabilizing Controllers (PASC) where the free parameter in the feedback part of the controller solves the mixed sensitivity robust control problem of attenuation of a Low-Frequency (LF) additive disturbance at the input of the plant and of a High-Frequency (HF) additive disturbance at the measurement, while the free parameter in the reference part of the controller assures that the controlled output tracks the reference at LF such as step or sinusoidal inputs. With the proposed expressions, the mixed sensitivity problem is solved without using weighting functions, so the controller does not increase its order; and the infinite norm of the mixed sensitivity criterion, as well as the assignment of poles, is determined by a set of control parameters. [ABSTRACT FROM AUTHOR]

Published

2021

14. Mixed sensitivity control: a non-iterative approach.

Author

Orozco, R. Galindo

Subjects

ALGEBRAIC equations, ROBUST control, PROBLEM solving, SIMULATION methods & models, UNCERTAINTY

Abstract

Recent analytical solutions to Mixed Sensitivity Control (MSC) are developed and compared with standard MSC based on γ-iteration. The proposed MSC solution gives conditions for strong stability and overcomes the pole-zero cancellations between the plant and the controller of non-iterative solutions, keeping the low-computational effort advantage of non-iterative solutions. The proposed MSC is based on the minimization of the most common closed-loop sensitivity functions in low-frequencies and the free-parameters of the stabilizing-controllers solve an algebraic equation of restriction that assigns the same value to the infinity-norms of the sensitivity functions at low and high-frequencies, guaranteeing robust stability and robust performance. It is assumed that the plant state dimension is double the plant input dimension and that the linear time-invariant nominal plant has a stabilizable and detectable realization and is strongly stabilizable. This MSC problem is solved in a one-parameter observer-controller configuration and reference tracking-control of positions is realized on a two-degrees of freedom feedback-configuration. An approximated optimal value of the location of the closed-loop poles is proposed based on Glover and McFarlane's optimal stability margin [(1989)] which in turn is based on Nehari's Theorem. Simulations of a mechanical system illustrate the results. [ABSTRACT FROM AUTHOR]

Published

2020

15. New Insights on Robust Control of Tilting Trains with Combined Uncertainty and Performance Constraints

Author

Halikias, Fazilah Hassan, Argyrios Zolotas, and George

Subjects

tilting trains, robust control, optimization, mixed sensitivity, robust performance, active suspensions

Abstract

A rigorous study on optimized robust control is presented for non-preview (nulling-type) high-speed tilting rail vehicles. The scheme utilizes sensors on the vehicle’s body, contrary to that of preview tilt (which uses prior rail track information). Tilt with preview is the industrial norm nowadays but is a complex scheme (both in terms of inter-vehicle signal connections and when it comes to straightforward fault detection). Non-preview tilt is simple (as it essentially involves an SISO control structure) and more effective in terms of (the localization of) failure detection. However, the non-preview tilt scheme suffers from performance limitations due to non-minimum-phase zeros in the design model (due to the compound effect of the suspension dynamic interaction and sensor combination used for feedback control) and presents a challenging control design problem. We proposed an optimized robust control design offering a highly improved non-preview tilt performance via a twofold model representation, i.e., (i) using the non-minimum phase design model and (ii) proposing a factorized design model version with the non-minimum phase characteristics treated as uncertainty. The impact of the designed controllers on tilt performance deterministic (curving acceleration response) and stochastic (ride quality) trade-off was methodically investigated. Nonlinear optimization was employed to facilitate fine weight selection given the importance of the ride quality as a bounded constraint in the design process.

Published

2023

16. A New Method of Modeling for Cuk Converter Based on Signal Flow Graph Approach and its Control by using a Mixed Sensitivity Type Robust Technique

Author

Leila Mohammadian, Ebrahim Babaei, and Mohammad Bagher Bannae Sharifian

Subjects

mixed sensitivity, model based control, robust control, signal flow graph, cuk converter, Engineering design, TA174

Abstract

In this paper, a new method based on signal flow graph is proposed for modeling a Cuk converter. Furthermore, the original signal flow graph based method suggested in literature is also implemented on the Cuk converter. The proposed method is very simple in the process, compared to other methods of modeling and the old method of signal flow graph. By using signal flow graph approach the three models of small signal, large signal and steady state are extracted. Also, without adding any additional computation, the desired transfer function between any two state variables of the circuit is extractable. After modeling the converter, a controller design problem for the Cuk converter will be discussed. A robust control method is proposed for controlling the system. It will be shown that, although the switching converter has a nonlinear nature, but this does not affect the controller design problem. By using a linear controller with parameters tuned with a robust method of mixed sensitivity type, controlling the converter is possible.

Published

2017

17. H∞ robust control of load frequency in diesel-battery hybrid electric propulsion ship

Author

LI Hongyue, WANG Xihuai, XIAO Jianmei, and CHEN Chen

Subjects

hybrid electric propulsion, load frequency control, linear matrix inequality(LMI), mixed sensitivity, H∞robust control, Naval architecture. Shipbuilding. Marine engineering, VM1-989

Abstract

Considering the load frequency fluctuation in the shipboard integrated power system caused by such stochastic uncertainty as wind, wave and current, the battery is adopted here to compensate for the difference between diesel generator output power and ship demand power, and the secondary frequency control is used for the diesel generator to guarantee the power balance in the shipboard integrated power system and suppress the frequency fluctuation. The load frequency control problem is modeled as a state space equation, the robust controller is designed by selecting the appropriate sensitivity function and complementary sensitivity function based on the H∞ mixed sensitivity principle, and the controller is solved by the linear matrix inequality(LMI)approach. The amplitude frequency characteristics denote the reasonability of the designed controller and the design requirement is satisfied by the impact of the impulse signal. The simulation results show that, compared with the classical PI controller, the controller designed by the H∞ robust method can significantly suppress frequency fluctuation under stochastic uncertainty, and improve the power variation of the diesel generator, battery and state of charge(SOC). The robust stability and robust performance of the power system are also advanced.

Published

2017

18. Mixed Sensitivity-Based Robust H∞ Control Method for Real-Time Hybrid Simulation

Author

Xizhan Ning

Subjects

real-time hybrid simulation, H∞ control, time delay, mixed sensitivity, Mathematics, QA1-939

Abstract

Real-time hybrid simulation (RTHS), dividing the emulated structure into numerical substructures (NS) and physical substructures (PS), is a powerful technique to obtain responses and then to assess the seismic performance of civil engineering structures. A transfer system, a servo-hydraulic actuator or shaking table, is used to apply boundary conditions between the two substructures. However, the servo-hydraulic actuator is inherently a complex system with nonlinearities and may introduce time delays into the RTHS, which will decrease the accuracy and stability of the RTHS. Moreover, there are various uncertainties in RTHS. An accurate and robust actuator control strategy is necessary to guarantee reliable simulation results. Therefore, a mixed sensitivity-based H∞ control method was proposed for RTHS. In H∞ control, the dynamics and robustness of the closed-loop transfer system are realized by performance weighting functions. A form of weighting function was given considering the requirement in RTHS. The influence of the weighting functions on the dynamics was investigated. Numerical simulations and actual RTHSs were carried out under symmetric and asymmetric dynamic loads, namely sinusoidal and earthquake excitation, respectively. Results indicated that the H∞ control method used for RTHS is feasible, and it exhibits an excellent tracking performance and robustness.

Published

2021

19. Model-based robust H∞ control of a granulation process using Smith predictor with Reference updating.

Author

Shaqarin, T., Al-Rawajfeh, A.E., Hajaya, M.G., Alshabatat, N., and Noack, B.R.

Subjects

*GRANULATION, *ROBUST control, *TIME delay systems

Abstract

• Efficient controller was applied for a linear MIMO granulation model with time delay. • Smith predictor & Reference updating were keys in applying the robust controller. • Uncertainties in model parameters & time delay were studied successfully. • Proposed controller managed time delay, physical constraints & model mismatch. Model-based feedback control is developed for a continuous granulation process addressing the challenge of time delay and physics-based input-output constraints. The process plant is a multi-input multi-output (MIMO) linear model with time delay. A robust H ∞ controller is designed using the mixed sensitivity loop shaping design. A framework has been laid down to insure the robustness of the Smith predictor by incorporating the model mismatch as an additive uncertainty in the predictor's structure. The control performance and robustness is assessed by simulations for regulation and reference tracking problems. We show significant performance gains by employing a Smith predictor and the technique of reference updating: The control is coping significantly better with time delay, physical constraints and model mismatch. The proposed control approach is more efficient as compared to other widely used methods such as model predictive control (MPC); obtaining a stable behaviour of the response and control effort while forcing them to remain within the desired bounds. [ABSTRACT FROM AUTHOR]

Published

2019

20. Control of rotary double inverted pendulum system using mixed sensitivity H∞ controller.

Author

Sanjeewa, Sondarangallage D.A. and Parnichkun, Manukid

Subjects

TRACKING control systems, UNCERTAIN systems, PENDULUMS, UNCERTAINTY (Information theory)

Abstract

Balancing control of a rotary double inverted pendulum system is a challenging research topic for researchers in dynamics control field because of its nonlinear, high degree-of-freedom, under actuated and unstable characteristics. The system always works under uncertainties and disturbances. Many control algorithms fail or ineffectively control the rotary double inverted pendulum system. In this article, mixed sensitivity H∞control is proposed to balance the rotary double inverted pendulum system. The controller is proposed to ensure the robust stability and enhance the time domain performance of the system under uncertainties and disturbances. Structure of the system, dynamics model and controller synthesis are presented. For performance evaluation, the proposed mixed sensitivity H∞controller is compared with linear quadratic regulator from both simulation and experiment on the rotary double inverted pendulum system. The results show high performance of the proposed controller on the rotary double inverted pendulum system with model uncertainties and external disturbances. [ABSTRACT FROM AUTHOR]

Published

2019

21. PID, 2-DOF PID and Mixed Sensitivity Loop-Shaping Based Robust Voltage Control of Quadratic Buck DC-DC Converter

Author

Fateh Ounis and Noureddine Golea

Subjects

dc-dc converters, mixed sensitivity, loop-shaping, pid control, quadratic buck converter, robust control., Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

DC-DC Quadratic Buck Converter (QBC) is largely used in applications where the high step-down conversion ratio is required. In the practical implementation, QBC is subject to uncertainties, disturbance, and sensor noise. To address the QBC control problems, a two-degree of freedom PID (2-DOF PID) is designed in the robust control framework. Further, for comparison purpose, a one-degree of freedom PID (1-DOF PID) and mixed sensitivity loop-shaping (MS-LS) controller are also proposed. Considering QBC parasitic components, the QBC small-signal transfer function is derived based on a practical approach. Sensitivity functions are used to specify the desired design requirements, and non-smooth optimization is used to tune both PID's parameters. The three control structures are implemented and tested in the Matlab/Simulink environment. As attested by simulation results, the 2-DOF PID exhibits a better regulation accuracy with enhanced robust stability and robust performance for a wide range of supply voltage/load variation and sensor noise effect.

Published

2016

22. A shuffled frog-leaping algorithm based mixed-sensitivity H∞ control of a seismically excited structural building using MR dampers.

Author

Lin, Xiufang, Chen, Shumei, and Huang, Guorong

Subjects

*SENSITIVITY theory (Mathematics), *DAMPERS (Mechanical devices), *MAGNETORHEOLOGICAL dampers, *FUZZY algorithms, *EXCITATION (Physiology)

Abstract

An intelligent robust controller, which combines a shuffled frog-leaping algorithm (SFLA) and an H∞ control strategy, is designed for a semi-active control system with magnetorheological (MR) dampers to reduce seismic responses of structures. Generally, the performance of mixed-sensitivity H∞ (MSH) control highly depends on expert experience in selecting the parameters of the weighting functions. In this study, as a recently-developed heuristic approach, a multi-objective SFLA with constraints is adopted to search for the optimal weighting functions. In the proposed semi-active control, firstly, based on the Bouc–Wen model, the forward dynamic characteristics of the MR damper are investigated through a series of tensile and compression experiments. Secondly, the MR damper inverse model is developed with an adaptive-network-based fuzzy inference system (ANFIS) technique. Finally, the SFLA-optimized MSH control approach integrated with the ANFIS inverse model is used to suppress the structural vibration. The simulation results for a three-story building model equipped with an MR damper verify that the proposed semi-active control method outperforms fuzzy control and two passive control methods. Besides, with the proposed strategy, the changes in structural parameters and earthquake excitations can be satisfactorily dealt with. [ABSTRACT FROM AUTHOR]

Published

2018

23. H∞ Mixed Sensitivity Control for a Three-Port Converter

Author

Jiang You, Hongsheng Liu, Bin Fu, and Xingyan Xiong

Subjects

three-port converter, parameters change, mixed sensitivity, H∞ control, Technology

Abstract

The three-port converter (TPC) obtains major attention due to its power density and ability to dispose different electric powers flexibly. Since the control models of the TPC are derived from particular steady state work point through small signal modeling method, the model parameters usually be deviated from their normal values with the change of operation and load conditions. Furthermore, there are couplings and interactions in power delivery between different ports, which have a significant influence in the dynamic control performance of the system. In this paper, the H∞ mixed sensitivity method is employed to design robust controllers for a TPC control system. Simulation results are given to demonstrate the effectiveness of the proposed scheme, and experimental studies are conducted on a prototype circuit to further validate the developed method. Compared to a traditional PI controller, it shows that a mixed sensitivity based robust controller manifest balanced performance in model parameters changes attenuation and dynamic control performance.

Published

2019

24. A Novel H∞ Robust Control Strategy for Voltage Source Inverter in Microgrid

Author

Jie zhang, Hongtao Shi, Yifan Li, Jian Zhou, and Zhongnan Jiang

Subjects

Economics and Econometrics, Renewable Energy, Sustainability and the Environment, Computer science, H∞ robust control, Energy Engineering and Power Technology, mixed sensitivity, General Works, Fuel Technology, Control theory, voltage stability, adaptive virtual impedance group, parameter perturbation, Microgrid, Robust control, Voltage source inverter

Abstract

The voltage control performance of the voltage source inverter (VSI) in a microgrid may change under different load conditions. However, in the case of traditional control strategies, the robustness of VSI is insufficient. In response to the above problems, a novel robust control scheme for VSI in the microgrid based on H∞ hybrid sensitivity is proposed in this study. The grid-side interference during the VSI operation is taken as the variable, and the sensitivity function is designed to build a H∞ robust voltage controller for VSI. In addition, an adaptive virtual impedance group is designed to further improve the voltage control robustness under a variety of operation conditions. Finally, comparative simulation experiments are carried out to verify the anti-interference ability of the proposed control strategy under different working conditions.

Published

2021

25. PID, 2-DOF PID AND MIXED SENSITIVITY LOOP-SHAPING BASED ROBUST VOLTAGE CONTROL OF QUADRATIC BUCK DC-DC CONVERTER.

Author

OUNIS, Fateh and GOLEA, Noureddine

Subjects

VOLTAGE control, CONVERTERS (Electronics), DEGREES of freedom, PID controllers, ROBUST control

Abstract

DC-DC Quadratic Buck Converter (QBC) is largely used in applications where the high step-down conversion ratio is required. In the practical implementation, QBC is subject to uncertainties, disturbance, and sensor noise. To address the QBC control problems, a two-degree of freedom PID (2-DOF PID) is designed in the robust control framework. Further, for comparison purpose, a one-degree of freedom PID (1-DOF PID) and mixed sensitivity loopshaping (MS-LS) controller are also proposed. Considering QBC parasitic components, the QBC smallsignal transfer function is derived based on a practical approach. Sensitivity functions are used to specify the desired design requirements, and non-smooth optimization is used to tune both PID's parameters. The three control structures are implemented and tested in the Matlab/Simulink environment. As attested by simulation results, the 2-DOF PID exhibits a better regulation accuracy with enhanced robust stability and robust performance for a wide range of supply voltage/load variation and sensor noise effect. [ABSTRACT FROM AUTHOR]

Published

2016

26. μ-Synthesis for Fractional-Order Robust Controllers

Author

Vlad Mihaly, Mihai Stanese, Mircea Susca, Petru Dobra, and Dora Morar

Subjects

D–K iteration, 0209 industrial biotechnology, Computer science, General Mathematics, Stability (learning theory), MathematicsofComputing_GENERAL, CNC machine, 02 engineering and technology, μ-synthesis, fractional-order control, 020901 industrial engineering & automation, Control theory, 0202 electrical engineering, electronic engineering, information engineering, Computer Science (miscellaneous), QA1-939, Fractional-order control, MATLAB, Engineering (miscellaneous), computer.programming_language, swarm optimization, Linear matrix inequality, mixed sensitivity, artificial bee colony optimization, Benchmark (computing), Numerical control, Computer Science::Programming Languages, 020201 artificial intelligence & image processing, Linear Matrix Inequality, Robust control, computer, Mathematics, robust control

Abstract

The current article presents a design procedure for obtaining robust multiple-input and multiple-output (MIMO) fractional-order controllers using a μ-synthesis design procedure with D–K iteration. μ-synthesis uses the generalized Robust Control framework in order to find a controller which meets the stability and performance criteria for a family of plants. Because this control problem is NP-hard, it is usually solved using an approximation, the most common being the D–K iteration algorithm, but, this approximation leads to high-order controllers, which are not practically feasible. If a desired structure is imposed to the controller, the corresponding K step is a non-convex problem. The novelty of the paper consists in an artificial bee colony swarm optimization approach to compute the nearly optimal controller parameters. Further, a mixed-sensitivity μ-synthesis control problem is solved with the proposed approach for a two-axis Computer Numerical Control (CNC) machine benchmark problem. The resulting controller using the described algorithm manages to ensure, with mathematical guarantee, both robust stability and robust performance, while the high-order controller obtained with the classical μ-synthesis approach in MATLAB does not offer this.

Published

2021

27. Modeling and robust H-infinite control of a novel non-contact ultra-quiet Stewart spacecraft.

Author

Xu, Yufei, Liao, He, Liu, Lei, and Wang, Yue

Subjects

*ROBUST control, *SPACE vehicles, *VIBRATION isolation, *ROCKET payloads, *DYNAMICS, *MATHEMATICAL models, *EULER acceleration

Abstract

This paper presents the modeling and robust H ∞ control of a novel ultra-quiet spacecraft which employs the non-contact Stewart platform to actively control its support module (SM) and payload module (PM). The SM and PM are mechanically separated such that the disturbances and vibrations from the SM can be perfectly suppressed. However, this novel spacecraft has internal instability. To overcome the instability, this paper derives the dynamics model of the non-contact Stewart spacecraft using Newton–Euler approach at first. Then, the mixed sensitivity robust H ∞ control is developed to guarantee both the attitude stability and precision pointing. Finally, simulation studies are provided to validate the effectiveness of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2015

28. H∞ interactive controller design for teaching purposes

Author

Díaz, José Manuel, Dormido, Sebastián, Nicolau, Bernat, Costa Castelló, Ramon, Díaz, José Manuel, Dormido, Sebastián, Nicolau, Bernat, and Costa Castelló, Ramon

Abstract

H∞-based controller design is one of the most powerful methodologies for controller design in the frequency domain. Unfortunately, its use requires advanced knowledge of control theory. The use of interactive tools allows to a non-specialized user to use these techniques and to learn the fundamental concepts behind the H∞ theory. In this work a graphical and completely interactive tool used to introduce students in H∞ control is presented.

Published

2020

29. Hinf interactive controller design for teaching purposes

Author

Universitat Politècnica de Catalunya. Departament d'Enginyeria de Sistemes, Automàtica i Informàtica Industrial, Universitat Politècnica de Catalunya. SAC - Sistemes Avançats de Control, Díaz, José Manuel, Dormido Bencomo, Sebastián, Nicolau, Bernat, Costa Castelló, Ramon, Universitat Politècnica de Catalunya. Departament d'Enginyeria de Sistemes, Automàtica i Informàtica Industrial, Universitat Politècnica de Catalunya. SAC - Sistemes Avançats de Control, Díaz, José Manuel, Dormido Bencomo, Sebastián, Nicolau, Bernat, and Costa Castelló, Ramon

Abstract

Hinf-based controller design is one of the most powerful methodologies for controller design in the frequency domain. Unfortunately, its use requires advanced knowledge of control theory. The use of interactive tools allows to a non-specialized user to use these techniques and to learn the fundamental concepts behind the Hinf theory. In this work a graphical and completely interactive tool used to introduce students in Hinf control is presented., Peer Reviewed, Postprint (author's final draft)

Published

2020

30. Design of Robust Control for Single Machine Infinite Bus System.

Author

Dulau, Mircea and Bica, Dorin

Abstract

There are many considerations to be taken into when choosing a controller for a system. This paper presents the basic concepts of the robust control design, applied on electromechanical mathematical model of the synchronous generator. The second order model of Single Machine Infinite Bus (SMIB) system is used to develop a robust controller, by H-infinite (H∞) synthesis techniques, which guarantee stability and performance. Using Matlab software facilities, the frequency characteristics of sensitivities functions and the mechanical power time response in close-loop connection with the designed controller have been simulated. [ABSTRACT FROM AUTHOR]

Published

2015

31. H∞ mixed sensitivity optimization for high speed tilting trains

Author

Shaharil Mohd Shah, Argyrios C. Zolotas, and Fazilah Hassan

Subjects

Optimization, Signal processing, Control and Optimization, Computer Networks and Communications, Computer science, Tilting train, Active suspension, Signal, Mixed sensitivity, Ride quality, Fault detection and isolation, Tilt (optics), Hardware and Architecture, Control and Systems Engineering, Control theory, Computer Science (miscellaneous), Sensitivity (control systems), Electrical and Electronic Engineering, Mathematics::Representation Theory, Instrumentation, Information Systems

Abstract

The industrial norm of tilting high speed trains, nowadays, is that of Precedence tilt (also known as Preview tilt). Precedence tilt, although succesfull as a concept, tends to be complex (mainly due to the signal interconnections between vehicles and the advanced signal processing required for monitoring). Research studies of early prior to that of precedence tilt schemes, i.e. the so-called Nulling-type schemes, utilized local-per-vehicle signals to provide tilt action (this was essentially a typical disturbance rejection-scheme) but suffered from inherent delays in the control). Nulling tilt may still be seen as an important research aim due to the simple nature and most importantly due to the more straightforward fault detection compared to precedence schemes. The work in this paper presents a substantial extension conventional to robust H∞ mixed sensitivity nulling tilt control in literature. A particular aspect is the use of optimization is used in the design of the robust controller accompanied by rigorous investigation of the conflicting deterministic/stochastic local tilt trade-off.

Published

2020

32. İnsansız hava araçları için kazanç ayarlamalı gürbüz kontrol

Author

Kasnakoğlu, Coşku, Şahin, İsmail Hakkı, Kasnakoğlu, Coşku, and Şahin, İsmail Hakkı

Abstract

In this thesis, gain scheduled robust control of unmanned aerial vehicles (UAV) is examined. Mathematical H_? optimization problem is solved using Linear Matrix Inequalties (LMIs) to synthesize sub-optimal controllers. Mixed sensitivity H_? optimization and H_? loop shaping methods are used in the controller design. First, a nonlinear helicopter model is built, trimmed and linearized from which an approximate affine-parameter-dependent model is constructed. Then, LMI based mixed sensivity H_? controllers are designed in order to achieve stabilization and reference tracking for a small unmanned helicopter at various flight conditions. Local H_? controllers are designed at trim conditions based on local linear models. The pointwise controllers achieve local stability and performance, but fail in stabilization and tracking over the full envelope. A scheduling controller is built by blending the local controller outputs. In addition, local H_? controllers are designed with common Lyapunov function. This allows controller scheduling between the design points with guaranteed stability and performance across the design envelope. Moreover, a parameter-dependent controller is synthesized to stabilize the affine-parameter-dependent helicopter model attaining stabilization and reference tracking for the family of linear models. All methods except for the local controller approach yield in satisfactory performance over the full flight envelope. Afterwards, H_? loop-shaping controller design is studied. Synthesized controler are scheduled parametrically with guaranteed robust stability over multiple operating points. Synthesis LMIs for state feedback and dynamic output feedback are derived in the parametric H_? loop-shaping framework. The results are extended to parameter-dependent plants to build a parameter-dependent controller utilizing a common Lyapunov function. The developed theory is applied to a small helicopter model, for which the operating region is covered by a famil, Bu tezde insansız hava araçlarının (İHA) kazanç ayarlamalı gürbüz kontrolü incelenmiştir. Temel olarak H_? optimizasyon problemi doğrusal matris eşitsizlikleri (DME) kullanılarak çözülmüştür. Kontrol tasarımında ise H_? karma hassasiyet ve H_? döngü şekillendirme prensiplerine dayalı kontrolcüler elde edilmiştir. İlk olarak, çeşitli uçuş koşullarında küçük bir insansız helikopter için kararlılık ve referans izleme sağlayabilen karma hassasiyet prensibine dayalı kontrolcü tasarımları üzerinde durulmuştur. Öncelikle yerel doğrusal modeller kullanılarak yerel karma hassasiyet H_? denetleyicileri bütün denge koşullarında tasarlanmıştır. Yerel H_? denetleyiciler yerel kararlılık ve performans koşullarını sağlarken, tam zarf üzerinde kararlılık ve referans izlemede başarısız oldukları görülmüştür. Bu problemin önüne geçmek için, kazanç ayarlamalı H_? denetleyiciler ortak Lyapunov fonksiyonu kullanılarak tasarlanmıştır. Bu yöntem daha tutucu bir yöntem olmakla beraber kontrolcü sentezinde tek bir ortak Lyapunov fonksiyonu kullanıldığından kapalı çevrim sistemin kararlılığı ara noktalarda da garanti altına alınmaktadır. Bu şekilde yapılan tasarım ile tüm uçuş zarfında kararlılığı ve performansı garanti eden kazanç ayarlamalı denetleyicileri sentezlenmiştir. Elde edilen kontrolcüler doğrusal olmayan benzetim modelinde test edilmiştir. Daha sonra küçük bir insansız helikopter için kazanç ayarlamalı H_? döngü şekillendirme kontrolcüsü tasarımı incelenmiştir. Teorik olarak garanti edilen bir kontrol yasası için, doğrusal helikopter modellerinin parametreye bağımlılığı kullanılarak, parametre bağımlı bir H_? döngü şekillendirme denetleyicisi tasarlanmıştır. Önerilen tasarım, ortak bir Lyapunov fonksiyonuyla parametreye bağlı değişen parametreye bağımlı bir kontrolcü sentezlemek için kullanılmıştır. Bu kontrolcüler birbirine bağlandığında, pratik bir kazanç ayarlamalı H_? döngü şekillendirme kontrolcüsü elde edilebilir. Bu tasarım yöntemi ile kararlılık ve performans tüm çalışma

Published

2019

33. Research for the clamping force control of pneumatic manipulator based on the mixed sensitivity method.

Author

Yi, Peng, Yuan, Rui-Bo, Long, Wei, and Ba, Shao-nan

Abstract

Abstract: In this paper, we analyzed uncertainty problems for the system of clamping force control on the condition that its model had been established. To oppose the uncertainty problems caused by many reasons, sensitivity method is mixed based on the control theory of H∞ and robust controller. Then, its control effects were studied by MATLAB. The simulation results showed the effectiveness of this method. They manifested that fault-tolerant, robustness and dynamic performance of the system are improved. It will be able to promote the application of pneumatic manipulator in the field of ultra-precision control. [Copyright &y& Elsevier]

Published

2012

34. Robust identification and feedback design: An active noise control case study

Author

Sánchez Peña, R.S., Cugueró, M.A., Masip, A., Quevedo, J., and Puig, V.

Subjects

*ROBUST control, *NOISE control, *ACOUSTICAL engineering, *ENVIRONMENTAL engineering

Abstract

Abstract: In this paper, a systematic control-oriented robust identification procedure which produces a parametric/nonparametric set of models is applied to a duct, in order to design a feedback active noise control (ANC) based on robust analysis and control. In addition, practical problems encountered in applying such a robust identification and feedback control approaches to ANC are pointed out. These are mainly derived from the compromises between identification and control, performance and robustness, the inherent limitations of feedback when applied to ANC, model and controller order, and implementation issues. Theoretical and experimental results on a real duct are compared using two different noise sources, a speaker and a fan. [Copyright &y& Elsevier]

Published

2008

35. H∞ Mixed Sensitivity Control for a Three-Port Converter

Author

Bin Fu, Xingyan Xiong, Jiang You, and Hongsheng Liu

Subjects

parameters change, Control and Optimization, Steady state (electronics), Steady state, Renewable Energy, Sustainability and the Environment, Computer science, lcsh:T, three-port converter, mixed sensitivity, H∞ control, Energy Engineering and Power Technology, PID controller, lcsh:Technology, Power (physics), Control theory, Control system, Point (geometry), Sensitivity (control systems), Electrical and Electronic Engineering, Engineering (miscellaneous), Energy (miscellaneous), Power density

Abstract

The three-port converter (TPC) obtains major attention due to its power density and ability to dispose different electric powers flexibly. Since the control models of the TPC are derived from particular steady state work point through small signal modeling method, the model parameters usually be deviated from their normal values with the change of operation and load conditions. Furthermore, there are couplings and interactions in power delivery between different ports, which have a significant influence in the dynamic control performance of the system. In this paper, the H∞ mixed sensitivity method is employed to design robust controllers for a TPC control system. Simulation results are given to demonstrate the effectiveness of the proposed scheme, and experimental studies are conducted on a prototype circuit to further validate the developed method. Compared to a traditional PI controller, it shows that a mixed sensitivity based robust controller manifest balanced performance in model parameters changes attenuation and dynamic control performance.

Published

2019

36. LPV control of a gyroscope with inverted pendulum attachment

Author

Koelewijn, P.J.W., Cisneros, P.S.G., Werner, H., Tóth, R., Koelewijn, P.J.W., Cisneros, P.S.G., Werner, H., and Tóth, R.

Abstract

A linear parameter varying (LPV) optimal L2 gain controller is designed with mixed-sensitivity shaping to stabilize an inverted pendulum attached to a control moment gyroscope (CMG). Swing-up of the pendulum is achieved by a start-up LPV controller for which the reference is designed by an energy regulator. The LPV performance controller is enabled as soon as the pendulum enters into its operating range of ±0.15 rad. Based on both simulation and experimental results, it is demonstrated that stabilization of the pendulum is achieved for varying gimbal angles and rotational speed of the flywheel.

Published

2018

37. LPV control of a gyroscope with inverted pendulum attachment

Author

Patrick J. W. Koelewijn, Herbert Werner, Roland Tóth, and Pablo S. G. Cisneros

Subjects

0209 industrial biotechnology, 02 engineering and technology, Gimbal, Flywheel, Inverted pendulum, law.invention, Control moment gyroscope, optimal control, Physics::Popular Physics, 020901 industrial engineering & automation, pendulum, Control theory, law, Computer Science::Systems and Control, 11. Sustainability, 0202 electrical engineering, electronic engineering, information engineering, control moment gyroscope, Technik [600], Physics, 020208 electrical & electronic engineering, Pendulum, mixed sensitivity, Gyroscope, Linear parameter-varying, Optimal control, Physics::Classical Physics, Control and Systems Engineering, ddc:600

Abstract

A linear parameter varying (LPV) optimal L2 gain controller is designed with mixed-sensitivity shaping to stabilize an inverted pendulum attached to a control moment gyroscope (CMG). Swing-up of the pendulum is achieved by a start-up LPV controller for which the reference is designed by an energy regulator. The LPV performance controller is enabled as soon as the pendulum enters into its operating range of ±0.15 rad. Based on both simulation and experimental results, it is demonstrated that stabilization of the pendulum is achieved for varying gimbal angles and rotational speed of the flywheel.

Published

2018

38. İnsansız hava araçları için kazanç ayarlamalı gürbüz kontrol

Author

Şahin, İsmail Hakki, Kasnakoğlu, Coşku, TOBB Ekonomi ve Teknoloji Üniversitesi Fen Bilimleri Enstitüsü, Elektrik ve Elektronik Mühendisliği Lisansüstü Programı, TOBB University of Economics and Technology Graduate School of Engineering and Science, Electrical and Electronics Engineering Graduate Programs, and Elektrik-Elektronik Mühendisliği Ana Bilim Dalı

Subjects

Döngü şekillendirme, Parametreye bağımlı kontrol, Elektrik ve Elektronik Mühendisliği, Nonlinear control, Robust control, Linear control, Mixed sensitivity, Modelling, Karma hassasiyet, Output feedback control, Nonlinear control theory, Modelleme Benzetim, Paramater dependent control, Loop shaping, Electrical and Electronics Engineering, Simulation, Gürbüz kontrol

Abstract

Bu tezde insansız hava araçlarının (İHA) kazanç ayarlamalı gürbüz kontrolü incelenmiştir. Temel olarak H_? optimizasyon problemi doğrusal matris eşitsizlikleri (DME) kullanılarak çözülmüştür. Kontrol tasarımında ise H_? karma hassasiyet ve H_? döngü şekillendirme prensiplerine dayalı kontrolcüler elde edilmiştir. İlk olarak, çeşitli uçuş koşullarında küçük bir insansız helikopter için kararlılık ve referans izleme sağlayabilen karma hassasiyet prensibine dayalı kontrolcü tasarımları üzerinde durulmuştur. Öncelikle yerel doğrusal modeller kullanılarak yerel karma hassasiyet H_? denetleyicileri bütün denge koşullarında tasarlanmıştır. Yerel H_? denetleyiciler yerel kararlılık ve performans koşullarını sağlarken, tam zarf üzerinde kararlılık ve referans izlemede başarısız oldukları görülmüştür. Bu problemin önüne geçmek için, kazanç ayarlamalı H_? denetleyiciler ortak Lyapunov fonksiyonu kullanılarak tasarlanmıştır. Bu yöntem daha tutucu bir yöntem olmakla beraber kontrolcü sentezinde tek bir ortak Lyapunov fonksiyonu kullanıldığından kapalı çevrim sistemin kararlılığı ara noktalarda da garanti altına alınmaktadır. Bu şekilde yapılan tasarım ile tüm uçuş zarfında kararlılığı ve performansı garanti eden kazanç ayarlamalı denetleyicileri sentezlenmiştir. Elde edilen kontrolcüler doğrusal olmayan benzetim modelinde test edilmiştir. Daha sonra küçük bir insansız helikopter için kazanç ayarlamalı H_? döngü şekillendirme kontrolcüsü tasarımı incelenmiştir. Teorik olarak garanti edilen bir kontrol yasası için, doğrusal helikopter modellerinin parametreye bağımlılığı kullanılarak, parametre bağımlı bir H_? döngü şekillendirme denetleyicisi tasarlanmıştır. Önerilen tasarım, ortak bir Lyapunov fonksiyonuyla parametreye bağlı değişen parametreye bağımlı bir kontrolcü sentezlemek için kullanılmıştır. Bu kontrolcüler birbirine bağlandığında, pratik bir kazanç ayarlamalı H_? döngü şekillendirme kontrolcüsü elde edilebilir. Bu tasarım yöntemi ile kararlılık ve performans tüm çalışma alanı içinde garanti edilmiş olur. H_? döngü şekillendirme denetleyicileri kazançlarının tüm tasarım zarfında iyi performans ve kararlılık sağladığı görülmektedir. Denge noktalarında düğüm düğüm (noktasal) sentez istenen uçuş zarfında tatmin edici bir performans göstermiştir. Son olarak ise önerilen metodun daha geniş bir perspektifte değerlendirilebilmesi için insansız küçük bir uçak için H_? döngü şekillendirme yöntemi kullanılarak eyleyici arızası durumunda acil iniş pilotu tasarlanmıştır. Bu yöntemde farklı hız ve irtifalarda denge noktaları bulunan uçağın yerel modelleri kullanılarak kontrolcüler tasarlanmış ve bu kontrolcüler birleştirilerek tüm acil durum uçuş zarfını kapsayan kazanç ayarlamalı kontrolcü elde edilmiştir. Daha sonra bu tasarım döngüde donanım testleri ile doğrulanmıştır. Sonuç olarak üç farklı uygulamada önerilen kazanç ayarlama yönteminin başarılı olduğu görülmüştür. Anahtar Kelimeler: H_? Optimizasyon, Karma hassasiyet, Döngü şekillendirme, Gürbüz kontrol, Parametreye bağımlı kontrol, Modelleme, Benzetim., In this thesis, gain scheduled robust control of unmanned aerial vehicles (UAV) is examined. Mathematical H_? optimization problem is solved using Linear Matrix Inequalties (LMIs) to synthesize sub-optimal controllers. Mixed sensitivity H_? optimization and H_? loop shaping methods are used in the controller design. First, a nonlinear helicopter model is built, trimmed and linearized from which an approximate affine-parameter-dependent model is constructed. Then, LMI based mixed sensivity H_? controllers are designed in order to achieve stabilization and reference tracking for a small unmanned helicopter at various flight conditions. Local H_? controllers are designed at trim conditions based on local linear models. The pointwise controllers achieve local stability and performance, but fail in stabilization and tracking over the full envelope. A scheduling controller is built by blending the local controller outputs. In addition, local H_? controllers are designed with common Lyapunov function. This allows controller scheduling between the design points with guaranteed stability and performance across the design envelope. Moreover, a parameter-dependent controller is synthesized to stabilize the affine-parameter-dependent helicopter model attaining stabilization and reference tracking for the family of linear models. All methods except for the local controller approach yield in satisfactory performance over the full flight envelope. Afterwards, H_? loop-shaping controller design is studied. Synthesized controler are scheduled parametrically with guaranteed robust stability over multiple operating points. Synthesis LMIs for state feedback and dynamic output feedback are derived in the parametric H_? loop-shaping framework. The results are extended to parameter-dependent plants to build a parameter-dependent controller utilizing a common Lyapunov function. The developed theory is applied to a small helicopter model, for which the operating region is covered by a family of linear models at a grid of operating points. It is shown through linear and nonlinear simulations that a desired loop shape is attained by the parameter dependent controller. Satisfactory tracking is achieved and stability is retained, even under mass and inertia variations. Moreover, to show the generality of the proposed technique, an autopilot is designed for an UAV where one of the lateral control surfaces, i.e. the aileron, becomes jammed and unusable. The autopilot handles the automatic recovery, autonomous guidance and landing of the disabled UAV. An accurate nonlinear aircraft model is used to build flight control laws for the UAV using loop-shaping theory to decouple longitudinal and lateral channels. The designed autopilot is tested on an example distress scenario involving aileron servoactuator jam. It is confirmed through hardware-in-the-loop (HIL) simulations that the autopilot design is capable of resuming safe flight and autonomous navigation under the fault scenario and is able to safely land the UAV to a target runway. Keywords: H_? Optimization, Mixed sensitivity, Loop shaping, Robust control, Paramater dependent control, Modelling, Simulation.

Published

2018

39. Mixed Sensitivity-Based Robust H ∞ Control Method for Real-Time Hybrid Simulation.

Author

Ning, Xizhan and Awrejcewicz, Jan

Subjects

*HYBRID computer simulation, *REAL-time control, *STRUCTURAL engineering, *ROBUST control, *CIVIL engineering, *SEISMIC response

Abstract

Real-time hybrid simulation (RTHS), dividing the emulated structure into numerical substructures (NS) and physical substructures (PS), is a powerful technique to obtain responses and then to assess the seismic performance of civil engineering structures. A transfer system, a servo-hydraulic actuator or shaking table, is used to apply boundary conditions between the two substructures. However, the servo-hydraulic actuator is inherently a complex system with nonlinearities and may introduce time delays into the RTHS, which will decrease the accuracy and stability of the RTHS. Moreover, there are various uncertainties in RTHS. An accurate and robust actuator control strategy is necessary to guarantee reliable simulation results. Therefore, a mixed sensitivity-based H∞ control method was proposed for RTHS. In H∞ control, the dynamics and robustness of the closed-loop transfer system are realized by performance weighting functions. A form of weighting function was given considering the requirement in RTHS. The influence of the weighting functions on the dynamics was investigated. Numerical simulations and actual RTHSs were carried out under symmetric and asymmetric dynamic loads, namely sinusoidal and earthquake excitation, respectively. Results indicated that the H∞ control method used for RTHS is feasible, and it exhibits an excellent tracking performance and robustness. [ABSTRACT FROM AUTHOR]

Published

2021

40. μ -Synthesis for Fractional-Order Robust Controllers.

Author

Mihaly, Vlad, Şuşcă, Mircea, Morar, Dora, Stănese, Mihai, Dobra, Petru, and Lopes, António M.

Subjects

*AUTOMATION, *ROBUST control, *STABILITY criterion, *NP-hard problems, *BENCHMARK problems (Computer science), *NUMERICAL control of machine tools

Abstract

The current article presents a design procedure for obtaining robust multiple-input and multiple-output (MIMO) fractional-order controllers using a μ -synthesis design procedure with D–K iteration. μ -synthesis uses the generalized Robust Control framework in order to find a controller which meets the stability and performance criteria for a family of plants. Because this control problem is NP-hard, it is usually solved using an approximation, the most common being the D–K iteration algorithm, but, this approximation leads to high-order controllers, which are not practically feasible. If a desired structure is imposed to the controller, the corresponding K step is a non-convex problem. The novelty of the paper consists in an artificial bee colony swarm optimization approach to compute the nearly optimal controller parameters. Further, a mixed-sensitivity μ -synthesis control problem is solved with the proposed approach for a two-axis Computer Numerical Control (CNC) machine benchmark problem. The resulting controller using the described algorithm manages to ensure, with mathematical guarantee, both robust stability and robust performance, while the high-order controller obtained with the classical μ -synthesis approach in MATLAB does not offer this. [ABSTRACT FROM AUTHOR]

Published

2021

41. Design of Robust Control for Single Machine Infinite Bus System

Author

Mircea Dulau and Dorin Bica

Subjects

Engineering, SMIB, business.industry, mixed sensitivity, Stability (learning theory), Control engineering, H infinite synthesis, Permanent magnet synchronous generator, Software, synchronous generator, Control theory, General Earth and Planetary Sciences, Connection (algebraic framework), Robust control, business, MATLAB, computer, robust control, Mechanical energy, General Environmental Science, computer.programming_language

Abstract

There are many considerations to be taken into when choosing a controller for a system. This paper presents the basic concepts of the robust control design, applied on electromechanical mathematical model of the synchronous generator. The second order model of Single Machine Infinite Bus (SMIB) system is used to develop a robust controller, by H-infinite (H ∞ ) synthesis techniques, which guarantee stability and performance. Using Matlab software facilities, the frequency characteristics of sensitivities functions and the mechanical power time response in close-loop connection with the designed controller have been simulated.

Published

2015

42. ДОСЛІДЖЕННЯ МЕТОДІВ H-СИНТЕЗУ СИСТЕМ СТАБІЛІЗАЦІЇ ІНФОРМАЦІЙНО-ВИМІРЮВАЛЬНИХ ПРИСТРОЇВ

Subjects

stabilization systems, information-measuring devices, lcsh:Motor vehicles. Aeronautics. Astronautics, mixed sensitivity, pre- and post-compensator, h-synthesis, lcsh:TL1-4050

Abstract

Розглянуто сучасні методи H-синтезу робастних регуляторів для систем управління широкого класу. Виконано класифікацію цих методів. Зроблено порівняльний аналіз щодо доцільності їх застосування для проектування систем стабілізації інформаційно-вимірювальних пристроїв.

Published

2012

43. Research for the clamping force control of pneumatic manipulator based on the mixed sensitivity method

Author

Rui-Bo Yuan, Peng Yi, Wei Long, and Shao-nan Ba

Subjects

Engineering, business.industry, pneumatic manipulator, mixed sensitivity, Control engineering, General Medicine, Clamping, control of clamping force, Robustness (computer science), Control theory, uncertainty, business, MATLAB, computer, Engineering(all), computer.programming_language

Abstract

In this paper, we analyzed uncertainty problems for the system of clamping force control on the condition that its model had been established. To oppose the uncertainty problems caused by many reasons, sensitivity method is mixed based on the control theory of H∞ and robust controller. Then, its control effects were studied by MATLAB. The simulation results showed the effectiveness of this method. They manifested that fault-tolerant, robustness and dynamic performance of the system are improved. It will be able to promote the application of pneumatic manipulator in the field of ultra-precision control.

Published

2012

44. H∞ Mixed Sensitivity Control for a Three-Port Converter.

Author

You, Jiang, Liu, Hongsheng, Fu, Bin, and Xiong, Xingyan

Subjects

*POWER density, *ELECTRIC power, *HARBOR management, *ROBUST control

Abstract

The three-port converter (TPC) obtains major attention due to its power density and ability to dispose different electric powers flexibly. Since the control models of the TPC are derived from particular steady state work point through small signal modeling method, the model parameters usually be deviated from their normal values with the change of operation and load conditions. Furthermore, there are couplings and interactions in power delivery between different ports, which have a significant influence in the dynamic control performance of the system. In this paper, the H∞ mixed sensitivity method is employed to design robust controllers for a TPC control system. Simulation results are given to demonstrate the effectiveness of the proposed scheme, and experimental studies are conducted on a prototype circuit to further validate the developed method. Compared to a traditional PI controller, it shows that a mixed sensitivity based robust controller manifest balanced performance in model parameters changes attenuation and dynamic control performance. [ABSTRACT FROM AUTHOR]

Published

2019

45. On the H∞ controller design for a magnetic suspension system model

Author

Hitay Özbay, E. Karagül, and Özbay, Hitay

Subjects

Optimization, Engineering, Optimal controller, Magnetic suspension system, business.industry, Fractional-order system, Infinite dimensional, Suspensions (components), Rational function, Effect of time, Controller designs, Achievable performance, Transfer function, Mixed sensitivity, H-infinity methods in control theory, Control theory, Fractional-order systems, Order (group theory), Sensitivity (control systems), business, Time delay, Delay control systems

Abstract

Date of Conference: February 4-6, 2013 Conference name: IFAC Joint conference SSSC, FDA, TDS 11TH Workshop on Time-Delay Systems TDS’13 This paper deals with the H∞ optimal controller design for a magnetic suspension system model derived in Knospe and Zhu [2011], with added input/output delay. The plant is a fractional order system with time delay i.e., the transfer function of the plant involves infinite dimensional terms including a rational function of √/s and e-hs, where h > 0 represents the delay. The H∞ optimal controller is designed by using the recent formulation given in Ozbay [2012] for the mixed sensitivity minimization problem for unstable infinite dimensional plants with low order weights. The effect of time delay on the achievable performance level is illustrated. © 2013 IFAC.

Published

2013

46. Computation of H∞ controllers for infinite dimensional plants using numerical linear algebra

Author

Özbay, Hitay and Özbay, Hitay

Subjects

Numerical linear algebra, Infinite dimensional systems, Mixed sensitivity, H∞ control

Abstract

The mixed sensitivity minimization problem is revisited for a class of single-input-single-output unstable infinite dimensional plants with low order weights. It is shown that H∞ controllers can be computed from the singularity conditions of a parameterized matrix whose dimension is the same as the order of the sensitivity weight. The result is applied to the design of H∞ controllers with integral action. Connections with the so-called Hamiltonian approach are also established.

Published

2012

47. Kızaklı Sarkaç Sisteminin H-sonsuz Optimal Kontrol Yöntemleri İle Salınımsız Kontrolü

Author

Alikoç, Baran, Sümer, Leyla Gören, Kontrol ve Otomasyon Mühendisliği, Control and Otomation Engineering, and Kontrol ve Otomasyon Mühendisliği Ana Bilim Dalı

Subjects

Control systems, Ağırlık Fonksiyonları, H-infinity, Duyarlılık Fonksiyonları, Mixed sensitivity, Computer Engineering and Computer Science and Control, Karma duyarlılık, Pendulum Gantry, Sensitivity, Pendulum system, Weighting Functions, Kızaklı Sarkaç, Sensitivity Functions, Weight functions, Bilgisayar Mühendisliği Bilimleri-Bilgisayar ve Kontrol, H-sonsuz

Abstract

Tez (Yüksek Lisans) -- İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, 2010, Thesis (M.Sc.) -- İstanbul Technical University, Institute of Science and Technology, 2010, Bu çalışmada, karma duyarlılık fonksiyonu optimizasyonu tek giriş tek çıkışlı sistemler için incelenmiş ve bu tasarım yöntemi kızaklı sarkaç sisteminin salınımsız kontrolü problemine uygulanmıştır. Sistemin hedeflenen davranışı göstermesi için ağırlık fonksiyonları ve biçimlendirme filtresi fonksiyonu belirlenmiştir. Tasarlanan H-sonsuz problemin, frekans tanım bölgesi çözümü ve durum uzayı çözümü ile kontrolörler hesaplatılmıştır. Frekans genlik yanıtları iyi ayarlanmış duyarlılık ve tamamlayıcı duyarlılık fonksiyonları ile hesaplanan kontrolörler aracılığıyla, sarkacın bağlı olduğu, dişli kızak üzerinde hareket eden taşıyıcı hareket ettirilerek sarkacın salınım açısı kontrol edilmiştir. Kontrolörlerin başarımı, yapısal model bilinmezlikleri, parametre değişimleri ve bozucu girişler altında sistemin doğrusal olmayan modeli kullanılarak benzetim yolu ile irdelenmiş ve karşılaştırılmıştır., In this study, the mixed sensitivity function optimization is analyzed for the single input single output systems and this approach is applied to control the single pendulum gantry without swing. The weighting functions and the shaping filter function are determined to achieve the desired system attitude. Controllers are calculated by the frequency domain solution and the state space solution of the designed H-infinity problem. By well tuned frequency response of sensitivity and complementary sensitivity functions, the swing angle of the single pendulum rod is controlled by the position of the cart which is mounted to the pendulum. The performance of both controllers under model and parameter uncertainties, and disturbances are investigated and compared by the simulations using non-linear model of the system., Yüksek Lisans, M.Sc.

Published

2010

48. RESEARCH OF H-METHODS FOR STABILIZATION OF INFORMATION-MEASURING DEVICES

Author

Сущенко, О.А. and Сущенко, О.А.

Abstract

The paper is devoted to research of the modern methods for the wide class control systems robust controllers H-synthesis. The classification of these methods was defined in the paper. The comparative analysis of their possibilities for information-measuring stabilization systems design was carried out. The research results are of interest of the field of the information-measuring stabilization systems assigned for exploitation at the vehicles of the wide class., Рассмотрены современные методы H-синтеза робастных регуляторов для систем управления широкого класса. Проведена классификация этих методов. Выполнен сравнительный анализ возможностей их использования для проектирования систем стабилизации информационно-измерительных устройств. Результаты исследования представляют интерес для отрасли систем стабилизации информационно-измерительных устройств, предназначенных для эксплуатации на подвижных объектах широкого класса., Розглянуто сучасні методи H-синтезу робастних регуляторів для систем управління широкого класу. Виконано класифікацію цих методів. Зроблено порівняльний аналіз щодо доцільності їх застосування для проектування систем стабілізації інформаційно-вимірювальних пристроїв.

Published

2012

49. Remarks on H ∞ controller design for SISO plants with time delays

Author

Gümüşsoy, Suat, Özbay, Hitay, and Özbay, Hitay

Subjects

Optimal controller, Time-delay systems, Design, Controllers, Infinite-dimensional system, Impulse response, Robust control, Block structures, Controller designs, H ∞ control, Mixed sensitivity, Mixed sensitivity problem, Time-delay, Skew-Toeplitz approach, Time delay, Finite-impulse response, Delay control systems

Abstract

Date of Conference: 5-7 July, 2006 Conference name: 5th IFAC Symposium on Robust Control Design, 2006 The skew Toeplitz approach is one of the well developed methods to design H ∞ controllers for infinite dimensional systems. In order to be able to use this method the plant needs to be factorized in some special manner. This paper investigates the largest class of SISO time delay systems for which the special factorizations required by the skew Toeplitz approach can be done. Reliable implementation of the optimal controller is also discussed. It is shown that the finite impulse response (FIR) block structure appears in these controllers not only for plants with I/O delays, but also for general time-delay plants.

Published

2006

50. İnsansız hava araçları için kazanç ayarlamalı gürbüz kontrol

Subjects

Döngü şekillendirme, Modelleme Benzetim, Parametreye bağımlı kontrol, Paramater dependent control, Robust control, Loop shaping, Mixed sensitivity, Modelling, Simulation, Karma hassasiyet, Gürbüz kontrol

Abstract

Bu tezde insansız hava araçlarının (İHA) kazanç ayarlamalı gürbüz kontrolü incelenmiştir. Temel olarak H_? optimizasyon problemi doğrusal matris eşitsizlikleri (DME) kullanılarak çözülmüştür. Kontrol tasarımında ise H_? karma hassasiyet ve H_? döngü şekillendirme prensiplerine dayalı kontrolcüler elde edilmiştir. İlk olarak, çeşitli uçuş koşullarında küçük bir insansız helikopter için kararlılık ve referans izleme sağlayabilen karma hassasiyet prensibine dayalı kontrolcü tasarımları üzerinde durulmuştur. Öncelikle yerel doğrusal modeller kullanılarak yerel karma hassasiyet H_? denetleyicileri bütün denge koşullarında tasarlanmıştır. Yerel H_? denetleyiciler yerel kararlılık ve performans koşullarını sağlarken, tam zarf üzerinde kararlılık ve referans izlemede başarısız oldukları görülmüştür. Bu problemin önüne geçmek için, kazanç ayarlamalı H_? denetleyiciler ortak Lyapunov fonksiyonu kullanılarak tasarlanmıştır. Bu yöntem daha tutucu bir yöntem olmakla beraber kontrolcü sentezinde tek bir ortak Lyapunov fonksiyonu kullanıldığından kapalı çevrim sistemin kararlılığı ara noktalarda da garanti altına alınmaktadır. Bu şekilde yapılan tasarım ile tüm uçuş zarfında kararlılığı ve performansı garanti eden kazanç ayarlamalı denetleyicileri sentezlenmiştir. Elde edilen kontrolcüler doğrusal olmayan benzetim modelinde test edilmiştir. Daha sonra küçük bir insansız helikopter için kazanç ayarlamalı H_? döngü şekillendirme kontrolcüsü tasarımı incelenmiştir. Teorik olarak garanti edilen bir kontrol yasası için, doğrusal helikopter modellerinin parametreye bağımlılığı kullanılarak, parametre bağımlı bir H_? döngü şekillendirme denetleyicisi tasarlanmıştır. Önerilen tasarım, ortak bir Lyapunov fonksiyonuyla parametreye bağlı değişen parametreye bağımlı bir kontrolcü sentezlemek için kullanılmıştır. Bu kontrolcüler birbirine bağlandığında, pratik bir kazanç ayarlamalı H_? döngü şekillendirme kontrolcüsü elde edilebilir. Bu tasarım yöntemi ile kararlılık ve performans tüm çalışma alanı içinde garanti edilmiş olur. H_? döngü şekillendirme denetleyicileri kazançlarının tüm tasarım zarfında iyi performans ve kararlılık sağladığı görülmektedir. Denge noktalarında düğüm düğüm (noktasal) sentez istenen uçuş zarfında tatmin edici bir performans göstermiştir. Son olarak ise önerilen metodun daha geniş bir perspektifte değerlendirilebilmesi için insansız küçük bir uçak için H_? döngü şekillendirme yöntemi kullanılarak eyleyici arızası durumunda acil iniş pilotu tasarlanmıştır. Bu yöntemde farklı hız ve irtifalarda denge noktaları bulunan uçağın yerel modelleri kullanılarak kontrolcüler tasarlanmış ve bu kontrolcüler birleştirilerek tüm acil durum uçuş zarfını kapsayan kazanç ayarlamalı kontrolcü elde edilmiştir. Daha sonra bu tasarım döngüde donanım testleri ile doğrulanmıştır. Sonuç olarak üç farklı uygulamada önerilen kazanç ayarlama yönteminin başarılı olduğu görülmüştür. Anahtar Kelimeler: H_? Optimizasyon, Karma hassasiyet, Döngü şekillendirme, Gürbüz kontrol, Parametreye bağımlı kontrol, Modelleme, Benzetim., In this thesis, gain scheduled robust control of unmanned aerial vehicles (UAV) is examined. Mathematical H_? optimization problem is solved using Linear Matrix Inequalties (LMIs) to synthesize sub-optimal controllers. Mixed sensitivity H_? optimization and H_? loop shaping methods are used in the controller design. First, a nonlinear helicopter model is built, trimmed and linearized from which an approximate affine-parameter-dependent model is constructed. Then, LMI based mixed sensivity H_? controllers are designed in order to achieve stabilization and reference tracking for a small unmanned helicopter at various flight conditions. Local H_? controllers are designed at trim conditions based on local linear models. The pointwise controllers achieve local stability and performance, but fail in stabilization and tracking over the full envelope. A scheduling controller is built by blending the local controller outputs. In addition, local H_? controllers are designed with common Lyapunov function. This allows controller scheduling between the design points with guaranteed stability and performance across the design envelope. Moreover, a parameter-dependent controller is synthesized to stabilize the affine-parameter-dependent helicopter model attaining stabilization and reference tracking for the family of linear models. All methods except for the local controller approach yield in satisfactory performance over the full flight envelope. Afterwards, H_? loop-shaping controller design is studied. Synthesized controler are scheduled parametrically with guaranteed robust stability over multiple operating points. Synthesis LMIs for state feedback and dynamic output feedback are derived in the parametric H_? loop-shaping framework. The results are extended to parameter-dependent plants to build a parameter-dependent controller utilizing a common Lyapunov function. The developed theory is applied to a small helicopter model, for which the operating region is covered by a family of linear models at a grid of operating points. It is shown through linear and nonlinear simulations that a desired loop shape is attained by the parameter dependent controller. Satisfactory tracking is achieved and stability is retained, even under mass and inertia variations. Moreover, to show the generality of the proposed technique, an autopilot is designed for an UAV where one of the lateral control surfaces, i.e. the aileron, becomes jammed and unusable. The autopilot handles the automatic recovery, autonomous guidance and landing of the disabled UAV. An accurate nonlinear aircraft model is used to build flight control laws for the UAV using loop-shaping theory to decouple longitudinal and lateral channels. The designed autopilot is tested on an example distress scenario involving aileron servoactuator jam. It is confirmed through hardware-in-the-loop (HIL) simulations that the autopilot design is capable of resuming safe flight and autonomous navigation under the fault scenario and is able to safely land the UAV to a target runway. Keywords: H_? Optimization, Mixed sensitivity, Loop shaping, Robust control, Paramater dependent control, Modelling, Simulation.