Your search keyword '"Multicompartment lung mechanics"' showing total 2 results

1. Robust PID Control of Multicompartment Lung Mechanics Model Using Runge-Kutta Neural Disturbance Observer

Author

Erdem Dilmen

Subjects

0209 industrial biotechnology, Disturbance (geology), Observer (quantum physics), Artificial neural network, Computer science, 020208 electrical & electronic engineering, PID controller, 02 engineering and technology, 020901 industrial engineering & automation, Control and Systems Engineering, Robustness (computer science), Control theory, Integrator, 0202 electrical engineering, electronic engineering, information engineering, Multicompartment lung mechanics, PID, artificial neural network, disturbance observer, robust control, Runge-Kutta discretization, Gradient descent, Parametric statistics

Abstract

This paper proposes Runge-Kutta neural disturbance observer to enhance the robustness of PID control of a system with general multicompartment lung mechanics. It is designed to observe the states of a particular type continous time, single-input single-output system where the states cannot be measured but can be observed through the single output and there exists parametric uncertainity or disturbance affecting the underlying system. It utilizes artificial neural network to estimate the disturbance online. Once an accurate disturbance estimation is obtained, it is incorporated in the system state equation and passed through the well-known Runge-Kutta integrator to predict the state values. Hence, the predicted states are obtained considering the disturbance and more robust state observation is achieved. The proposed observer is simple and easy to implement. Adaptation of the neural network is performed using gradient descent with an adaptive learning rate which guarantees convergence. The simulation results demonstrate that the proposed observer gains a significant success in enhancing the robustness of PID control at even high level of disturbance. Note that, multicompartment lung mechanics system is a stand-in model that can mimic the behavior of human lung. Thus, it is appropriate for hardware-in-the-loop simulation which opens a path to the real-patient-tests of mechanical respiratory systems in the future. Copyright (C) 2020 The Authors.

Published

2020

2. UKF-SVM Based Generalized Predictive Control of Multicompartment Lung Mechanics Model

Author

Erdem Dilmen

Subjects

0209 industrial biotechnology, Computer science, Multicompartment lung mechanics, robust control, LS-SVM, UKF, 020208 electrical & electronic engineering, 02 engineering and technology, Kalman filter, Support vector machine, Extended Kalman filter, symbols.namesake, Model predictive control, 020901 industrial engineering & automation, ComputingMethodologies_PATTERNRECOGNITION, Control and Systems Engineering, Linearization, generalized predictive control, Black box, 0202 electrical engineering, electronic engineering, information engineering, Gaussian function, symbols, Algorithm, Linear least squares

Abstract

In this paper, least-squares support vector machine (LS-SVM), whose parameters are updated by unscented Kalman filter (UKF), is adopted in the generalized predictive control (GPC) of a system with general multicompartment lung mechanics. Gaussian kernel function is employed since it presents a good approximation to the inner product of nonlinear mapping possessed in the SVM formulation. In the SVM literature, it is well known that the width parameter a of the Gaussian kernel function has an important effect on the performance. However, it is not possible to train that parameter together with the other parameters of SVM when using linear least squares. This is why we use UKF for parameter adaptation in the SVM formulation. At each time instant of the control task, all parameters of the LS-SVM model, including a, are tuned simultaneously. Another reason to employ UKF is; it avoids the suboptimal solutions caused by linearization based filters, e.g., extended Kalman filter. Due to these facts, we train the SVM model using UKF and it will be referred to as the UKF-SVM model. Simulation results concerning the application of UKF-SVM based GPC to a multicompartment lung mechanics model yields plausible performance using small amount of support vectors even when there are time-varying lung parameters and disturbance of high level affecting the system. The adopted approach can also be useful when there is not any knowledge of the system dynamics, i.e., black box. Note that, multicompartment lung mechanics system is a stand-in model that can mimic the behavior of human lung. Thus, it is appropriate for hardware-in-the-loop simulation which opens a path to the real-patient-tests of mechanical respiratory systems in the future. Copyright (C) 2020 The Authors.

Published

2020