论文信息 - Multilayer neural networks for solving a class of partial differential equations

Multilayer neural networks for solving a class of partial differential equations

In this paper, training the derivative of a feedforward neural network with the extended backpropagation algorithm is presented. The method is used to solve a class of first-order partial differential equations for input-to-state linearizable or approximate linearizable systems. The solution of the differential equation, together with the Lie derivatives, yields a change of coordinates. A feedback control law is then designed to keep the system in a desired behavior. The examination of the proposed method, through simulations, exhibits the advantages of it. They include easily and quickly finding approximate solutions for complicated first-order partial differential equations. Therefore, the work presented here can benefit the design of the class of nonlinear control systems, where the nontrivial solutions of the partial differential equations are difficult to find.

[1] J. Hauser. Nonlinear control via uniform system approximation , 1991 .

[2] A. Krener. Approximate linearization by state feedback and coordinate change , 1984 .

[3] Hossam A. Abdel Fattah,et al. Nonlinear system control via feedback linearization using neural networks , 1996, Proceedings of International Conference on Neural Networks (ICNN'96).

[4] P. Kokotovic,et al. Nonlinear control via approximate input-output linearization: the ball and beam example , 1992 .

[5] A. Isidori. Nonlinear Control Systems , 1985 .

[6] W. Baumann,et al. Feedback control of nonlinear systems by extended linearization , 1986 .

[7] W. Rugh,et al. On the pseudo-linearization problem for nonlinear systems , 1989 .

[8] Frank L. Lewis,et al. Optimal Control , 1986 .

[9] Mohammad Bagher Menhaj,et al. Training feedforward networks with the Marquardt algorithm , 1994, IEEE Trans. Neural Networks.