Yusuke Yoshioka scite author profile

The efforts on boundary control of general classes of nonlinear parabolic PDEs with nonlinearities of superlinear growth have so far only resulted in counterexamples-results that show that finite time blow up occurs for large initial conditions even for simple cases like quadratic nonlinearities, with or without control. In this paper we present results identifying a class of systems that is stabilizable. Our approach is a direct infinite dimensional extension of the feedback linearization/backstepping approach and employs Volterra series nonlinear operators both in the transformation to a stable linear PDE and in the feedback law. While the full detail of our general approach is left for a future publication without a page limit, in this paper we give an example with explicit solutions for the plant/controller pair, including an explicit construction of the inverse of the feedback linearizing Volterra transformation. This, in turn, allows us to explicitly construct the exponentially decaying closed loop solutions. We include also a numerical illustration, showing blow up in open loop, and stabilization for large initial conditions in closed loop. Copyright c 2004 IFAC

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Grid Connection Point Power Factor Control based on the Level of Reverse Power Flow with a PV and Battery Power Conditioner

Endo

Yoshioka

Inoue

et al. 2019

IEEJ Trans. IA

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Model predictive control for hot strip mill cooling system

Hashimoto

Yoshioka

Ohtsuka

2010

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Yusuke Yoshioka

Receding Horizon Control With Numerical Solution for Nonlinear Parabolic Partial Differential Equations

Receding Horizon Control for Hot Strip Mill Cooling Systems

Receding horizon control for nonlinear parabolic partial differential equations with boundary control inputs

Grid Connection Point Power Factor Control based on the Level of Reverse Power Flow with a PV and Battery Power Conditioner

Model predictive control for hot strip mill cooling system

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