Three Tank multimode problem: Difference between revisions

Three Tank multimode problem
State dimension:	1
Differential states:	3
Discrete control functions:	3
Interior point equalities:	2

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Latest revision as of 07:16, 14 October 2025

This site describes a Double tank problem variant with three binary controls instead of only one control and three tanks, i.e., three differential states representing different compartments.

Mathematical formulation

The mixed-integer optimal control problem is given by

$\begin{array}{llll} \min_{x, w} & \int_{0}^{T} & k_{1} (x_{2} - k_{2})^{2} + k_{3} (x_{3} - k_{4})^{2} d t \\ s.t. & {\dot{x}}_{1} & = - \sqrt{x_{1}} + c_{1} w_{1} + c_{2} w_{2} - w_{3} \sqrt{c_{3} x_{1}}, \\ {\dot{x}}_{2} & = \sqrt{x_{1}} - \sqrt{x_{2}}, \\ {\dot{x}}_{3} & = \sqrt{x_{2}} - \sqrt{x_{3}} + w_{3} \sqrt{c_{3} x_{1}}, \\ x (0) & = (2, 2, 2)^{T}, \\ 1 & = \sum_{i = 1}^{3} w_{i} (t), \\ w_{i} (t) & \in {0, 1}, i = 1 \dots 3 . \end{array}$

Parameters

These fixed values are used within the model.

$T = 12, c_{1} = 1, c_{2} = 2, c_{3} = 0.8, k_{1} = 2, k_{2} = 3, k_{3} = 1, k_{4} = 3 .$

Reference Solutions

If the problem is relaxed, i.e., we demand that $w (t)$ be in the continuous interval $[0, 1]$ instead of the binary choice ${0, 1}$ , the optimal solution can be determined by means of direct optimal control and the CIA decomposition. We denote the relaxed control values with $a (t) \in [0, 1]$ .

The optimal objective value of the relaxed problem with $n_{t} = 100, n_{u} = 100$ is $8.775979$ . The objective value of the binary controls obtained by Combinatorial Integral Approimation (CIA) is $8.789487$ .

Reference solution plots
Optimal relaxed controls and states determined by an direct approach with python 3.6 and CasADi, applied Multiple Shooting, 4th order Runge Kutta scheme and 100 discretization intervals.
According optimal binary controls and states determined by the direct approach. The relaxed controls were approximated by Combinatorial Integral Approximation.
Binary and relaxed control values as part of the Combinatorial Integral Approximation problem

Source Code

Model description is available in (using pycombina for solving the (CIA) rounding problem step):

Casadi code at Three Tank multimode problem (python/casadi)

@@ Line 15: / Line 15: @@
 \begin{array}{llll}
   \displaystyle \min_{x,w} &  \displaystyle \int_{0}^{T} & k_1(x_2-k_2)^2 + k_3(x_3-k_4)^2  \; \text{d}t\\[1.5ex]
-  \mbox{s.t.} &  \dot{x}_1 & = -\sqrt{x_1}+c_1 w_1 + c_2 w_2 - w_3 \sqrt{c_3 x_3}, \\[1.5ex]
+  \mbox{s.t.} &  \dot{x}_1 & = -\sqrt{x_1}+c_1 w_1 + c_2 w_2 - w_3 \sqrt{c_3 x_1}, \\[1.5ex]
   &  \dot{x}_2 & = \sqrt{x_1}-\sqrt{x_2}, \\[1.5ex]
-  &  \dot{x}_3 & = \sqrt{x_2}-\sqrt{x_3}+w_3 \sqrt{c_3 x_3}, \\[1.5ex]
+  &  \dot{x}_3 & = \sqrt{x_2}-\sqrt{x_3}+w_3 \sqrt{c_3 x_1}, \\[1.5ex]
   &  x(0) & = (2,2,2)^T, \\[1.5ex]
 & 1 & = \sum\limits_{i=1}^{3}w_i(t), \\
@@ Line 23: / Line 23: @@
 \end{array}
 </math>
 == Parameters ==
@@ Line 43: / Line 42: @@
 </gallery>
+== Source Code ==
+Model description is available in (using pycombina for solving the (CIA) rounding problem step):
+* [[:Category:Casadi | Casadi code]] at [[Three Tank multimode problem (python/casadi)]]