104 research outputs found

    Extended Dissipative Filter for Delayed T-S Fuzzy Network of Stochastic System with Packet Loss

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    This research investigates a time-varying delay-based adaptive event-triggered dissipative filtering problem for the interval type-2 (IT-2) Takagi-Sugeno (T-S) fuzzy networked stochastic system. The concept of extended dissipativity is used to solve the ,  and dissipative performances for (IT-2) T-S fuzzy stochastic systems in a unified manner. Data packet failures and latency difficulties are taken into account while designing fuzzy filters. An adaptive event-triggered mechanism is presented to efficiently control network resources and minimise excessive continuous monitoring while assuring the system’s efficiency with extended dissipativity. A new adaptive event triggering scheme is proposed which depends on the dynamic error rather than pre-determined constant threshold. A new fuzzy stochastic Lyapunov-Krasovskii Functional (LKF) using fuzzy matrices with higher order integrals is built based on the Lyapunov stability principle for mode-dependent filters. Solvability of such LKF leads to the formation of appropriate conditions in the form of linear matrix inequalities, ensuring that the resulting error mechanism is stable. In order to highlight the utility and perfection of the proposed technique, an example is presented

    Gain-Scheduled Fault Detection Filter For Discrete-time LPV Systems

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    The present work investigates a fault detection problem using a gain-scheduled filter for discrete-time Linear Parameter Varying systems. We assume that we cannot directly measure the scheduling parameter but, instead, it is estimated. On the one hand, this assumption imposes the challenge that the fault detection filter should perform properly even when using an inexact parameter. On the other, it avoids the burden associated with designing a complex estimation process for this parameter. We propose three design approaches: the H2{\mathcal {H}_{2}} , H∞{\mathcal {H}_{\infty }} , and mixed H2/H∞{\mathcal {H}_{2}} / {\mathcal {H}_{\infty }} gain-scheduled Fault Detection Filters designed via Linear Matrix Inequalities. We also provide numerical simulations to illustrate the applicability and performance of the proposed novel methods

    Fourth SIAM Conference on Applications of Dynamical Systems

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    Research on Advanced Control Strategies for Vehicle Active Seat Suspension Systems

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    Vehicle seat suspensions play a very important role in vibration reduction for vehicle drivers, especially for some heavy vehicles. Compared with small vehicles, these heavy vehicle drivers suffer much more from vibrations, which influence driving comfort and may cause health problems, so seat suspensions are necessary for those heavy vehicle drivers to reduce vibrations and improve driving comfort. Advanced control systems and control strategies are investigated for vehicle seat suspensions in this project. Firstly, for an active single-degree of freedom (single-DOF) seat suspension, a singular system-based approach for active vibration control of vehicle seat suspensions is proposed, where the drivers’ acceleration is augmented into the conventional seat suspension model together with seat suspension deflection and relative velocity as system states to make the suspen- sion model as a singular system. Then, an event-triggered H∞ controller is designed for an active seat suspension, where both the continuous and discrete-time event-triggered schemes are considered, respectively. The proposed control method can reduce the work- load of data transmission of the seat suspension system and work as a filter to remove the effect of noise, so it can decrease the precision requirement of the actuator, which can help to reduce the cost of the seat suspension. For complicated seat suspension systems, a singular active seat suspension system with a human body model is also established and an output-feedback event-triggered H∞ controller is designed. The accelerations of each part are considered as part of the system states, which makes the system a singular sys- tem. The seat suspension deflection, relative velocity, the accelerations of the seat frame, body torso, and head are defined as the system outputs. At last, to deal with whole-body vibration, a control system and a robust H∞ control strategy are designed for a 2-DOF seat suspension system. Two H∞ controllers are designed to reduce vertical and rotational vibrations simultaneously. All the proposed seat suspension systems and control methods are verified by simulations and some are also tested by experiments. These simulation and experimental results show their effectiveness and advantages of the proposed methods to improve the driving comfort and some can reduce the workload of data transmission

    Adapt-to-learn policy transfer in reinforcement learning and deep model reference adaptive control

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    Adaptation and Learning from exploration have been a key in biological learning; Humans and animals do not learn every task in isolation; rather are able to quickly adapt the learned behaviors between similar tasks and learn new skills when presented with new situations. Inspired by this, adaptation has been an important direction of research in control as Adaptive Controllers. However, the Adaptive Controllers like Model Reference Adaptive Controller are mainly model-based controllers and do not rely on exploration instead make informed decisions exploiting the model's structure. Therefore such controllers are characterized by high sample efficiency and stability conditions and, therefore, suitable for safety-critical systems. On the other hand, we have Learning-based optimal control algorithms like Reinforcement Learning. Reinforcement learning is a trial and error method, where an agent explores the environment by taking random action and maximizing the likelihood of those particular actions that result in a higher return. However, these exploration techniques are expected to fail many times before exploring optimal policy. Therefore, they are highly sample-expensive and lack stability guarantees and hence not suitable for safety-critical systems. This thesis presents control algorithms for robotics where the best of both worlds that is ``Adaptation'' and ``Learning from exploration'' are brought together to propose new algorithms that can perform better than their conventional counterparts. In this effort, we first present an Adapt to learn policy transfer Algorithm, where we use control theoretical ideas of adaptation to transfer policy between two related but different tasks using the policy gradient method of reinforcement learning. Efficient and robust policy transfer remains a key challenge in reinforcement learning. Policy transfer through warm initialization, imitation, or interacting over a large set of agents with randomized instances, have been commonly applied to solve a variety of Reinforcement Learning (RL) tasks. However, this is far from how behavior transfer happens in the biological world: Here, we seek to answer the question: Will learning to combine adaptation reward with environmental reward lead to a more efficient transfer of policies between domains? We introduce a principled mechanism that can ``Adapt-to-Learn", which is adapt the source policy to learn to solve a target task with significant transition differences and uncertainties. Through theory and experiments, we show that our method leads to a significantly reduced sample complexity of transferring the policies between the tasks. In the second part of this thesis, information-enabled learning-based adaptive controllers like ``Gaussian Process adaptive controller using Model Reference Generative Network'' (GP-MRGeN), ``Deep Model Reference Adaptive Controller'' (DMRAC) are presented. Model reference adaptive control (MRAC) is a widely studied adaptive control methodology that aims to ensure that a nonlinear plant with significant model uncertainty behaves like a chosen reference model. MRAC methods try to adapt the system to changes by representing the system uncertainties as weighted combinations of known nonlinear functions and using weight update law that ensures that network weights are moved in the direction of minimizing the instantaneous tracking error. However, most MRAC adaptive controllers use a shallow network and only the instantaneous data for adaptation, restricting their representation capability and limiting their performance under fast-changing uncertainties and faults in the system. In this thesis, we propose a Gaussian process based adaptive controller called GP-MRGeN. We present a new approach to the online supervised training of GP models using a new architecture termed as Model Reference Generative Network (MRGeN). Our architecture is very loosely inspired by the recent success of generative neural network models. Nevertheless, our contributions ensure that the inclusion of such a model in closed-loop control does not affect the stability properties. The GP-MRGeN controller, through using a generative network, is capable of achieving higher adaptation rates without losing robustness properties of the controller, hence suitable for mitigating faults in fast-evolving systems. Further, in this thesis, we present a new neuroadaptive architecture: Deep Neural Network-based Model Reference Adaptive Control. This architecture utilizes deep neural network representations for modeling significant nonlinearities while marrying it with the boundedness guarantees that characterize MRAC based controllers. We demonstrate through simulations and analysis that DMRAC can subsume previously studied learning-based MRAC methods, such as concurrent learning and GP-MRAC. This makes DMRAC a highly powerful architecture for high-performance control of nonlinear systems with long-term learning properties. Theoretical proofs of the controller generalizing capability over unseen data points and boundedness properties of the tracking error are also presented. Experiments with the quadrotor vehicle demonstrate the controller performance in achieving reference model tracking in the presence of significant matched uncertainties. A software+communication architecture is designed to ensure online real-time inference of the deep network on a high-bandwidth computation-limited platform to achieve these results. These results demonstrate the efficacy of deep networks for high bandwidth closed-loop attitude control of unstable and nonlinear robots operating in adverse situations. We expect that this work will benefit other closed-loop deep-learning control architectures for robotics

    Computer Aided Verification

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    This open access two-volume set LNCS 11561 and 11562 constitutes the refereed proceedings of the 31st International Conference on Computer Aided Verification, CAV 2019, held in New York City, USA, in July 2019. The 52 full papers presented together with 13 tool papers and 2 case studies, were carefully reviewed and selected from 258 submissions. The papers were organized in the following topical sections: Part I: automata and timed systems; security and hyperproperties; synthesis; model checking; cyber-physical systems and machine learning; probabilistic systems, runtime techniques; dynamical, hybrid, and reactive systems; Part II: logics, decision procedures; and solvers; numerical programs; verification; distributed systems and networks; verification and invariants; and concurrency

    Computer Aided Verification

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    This open access two-volume set LNCS 11561 and 11562 constitutes the refereed proceedings of the 31st International Conference on Computer Aided Verification, CAV 2019, held in New York City, USA, in July 2019. The 52 full papers presented together with 13 tool papers and 2 case studies, were carefully reviewed and selected from 258 submissions. The papers were organized in the following topical sections: Part I: automata and timed systems; security and hyperproperties; synthesis; model checking; cyber-physical systems and machine learning; probabilistic systems, runtime techniques; dynamical, hybrid, and reactive systems; Part II: logics, decision procedures; and solvers; numerical programs; verification; distributed systems and networks; verification and invariants; and concurrency

    Optimal control and approximations

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