Control of Heat Equation with Actuator Placement: Difference between revisions

Control of Heat Equation with Actuator Placement
State dimension:	1
Differential states:	1
Continuous control functions:	L
Discrete control functions:	L
Interior point equalities:	3

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Revision as of 15:09, 23 February 2016

This problem is governed by the heat equation and is adapted from Iftime and Demetriou ([Iftime2009]Author: Orest V. Iftime; Michael A. Demetriou
Journal: {A}utomatica
Number: 2
Pages: 312--323
Title: {O}ptimal control of switched distributed parameter systems with spatially scheduled actuators
Volume: 45
Year: 2009
). Its goal is to choose a place to apply an actuator in a given area depending on time. We consider a rectangle $Ω = [0, 1] \times [0, 2]$ with the boundary $\partial Ω$ and the time horizon $T = [0, 10]$ as the domains. The objective function is quadratic, its first term captures the desired final state $\bar{u} \equiv 0$ , the second term regularize the state over time and the third term regularize the continuous controls. The constraints are a source budget, which limits the quantity of placed actuators, and the two-dimensional heat equation with some source function. Additionally, we assume Dirichlet boundary conditions and initial conditions.

Mathematical formulation

Parameters

Reference solution

Source Code

References

[Iftime2009]

Orest V. Iftime; Michael A. Demetriou (2009): {O}ptimal control of switched distributed parameter systems with spatially scheduled actuators . {A}utomatica, 45, 312--323

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 {{Dimensions
 |nd        = 1
-|nx        = 3
+|nx        = 1
-|nw        = 1
+|nu        = <math>L</math>
+|nw        = <math>L</math>
 |nre       = 3
 }}<!-- Do not insert line break here or Dimensions Box moves up in the layout...