Jackson OED: Difference between revisions

Jackson OED
State dimension:	1
Differential states:	13
Discrete control functions:	3

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Revision as of 07:45, 27 January 2026

The Jackson OED problem is a variation of the Jackson problem. It looks for optimal time intervals to measure the three states in order to minimize the uncertainty of a follow-up parameter estimation problem for the two unknown parameters.

The mathematical equations form a small-scale ODE model. It also includes state sensitivities, the Fisher information matrix entries and integrated sampling states.

Mathematical formulation

We are interested in estimating the parameters $k_{1}$ and $k_{2}$ of the initial value problem

$\begin{array}{rcl} \dot{x_{1}} (t) & = & - u (t) (k_{1} x_{1} (t) - k_{2} x_{2} (t)), & t \in [0, t_{f}], x_{1} (0) = 1, \\ \dot{x_{2}} (t) & = & u (t) (k_{1} x_{1} (t) - k_{2} x_{2} (t)) - (1 - u (t)) k_{3} x_{2} (t), & t \in [0, t_{f}], x_{2} (0) = 0, \\ \dot{x_{3}} (t) & = & (1 - u (t)) k_{3} x_{2} (t), & t \in [0, t_{f}], x_{3} (0) = 0 . \end{array}$

The initial values and $t_{f} = 1$ are fixed. We are interested in how to choose the control $u$ and when to measure, with an upper bound $M$ on the measuring time. We can measure the states $x_{1}$ and $x_{2}$ directly, $h^{1} (x (t)) = x_{1} (t)$ and $h^{2} (x (t)) = x_{2} (t)$ . We use two different sampling functions, $w^{1} (\cdot)$ and $w^{2} (\cdot)$ in the same experimental setting. This can be seen either as a two-dimensional measurement function $h (x (t))$ , or as a special case of a multiple experiment, in which $u (\cdot), x (\cdot)$ , and $G (\cdot)$ are identical.

Now we formulate the OED problem:

$\begin{array}{lll} \min_{x, G, F, z, w, u} & trace (F^{- 1} (t_{f})) \\ subject to \\ \dot{x} (t) & = & f (x (t), θ) \\ \dot{G} (t) & = & f_{x} (x (t), θ) G (t) + f_{θ} (x (t), θ) \\ \dot{F} (t) & = & \sum_{i = 1}^{n_{o}} w_{i} (t) (h_{x}^{i} (x (t)) G (t))^{T} (h_{x}^{i} (x (t)) G (t)) \\ \dot{z} (t) & = & w (t), \\ x (0) & = & x_{0} \\ G (0) & = & \frac{\partial x (0)}{\partial θ} \\ F (0) & = & 0, \\ z (0) & = & 0 \\ u (t) & \in & 𝒰 \\ w (t) & \in & 𝒲 \\ z_{i} (t_{f}) & \leq & M_{i} \end{array}$

The evolution of the symmetric matrix $F : [0, t_{f}] \to ℝ^{2 \times 2}$ is given by the weighted sum of observability Gramians $h_{x}^{i} (x (t)) G (t), i = 1, 2$ for each observed function of states.

Parameters

These fixed values are used within the model:

Symbol	Value	Description
$k_{1}$	1	Interaction between $x_{1}$ and $x_{2}$
$k_{2}$	10	Interaction between $x_{1}$ and $x_{2}$
$k_{3}$	1	Growth of $x_{3}$ under complementary control
$t_{f}$	1	Horizon of the control problem
$𝒰$	[0,1]	Bounds of control function
$𝒲$	[0,1]	Bounds of measurement function
$ℳ$	0.2	Maximum measurement time

Reference Solutions

Here is one local solution to the above control problem.

Reference solution plots
States, control, and sampling functions for a local optimum.

References

There were no citations found in the article.

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 | align=center | <math>\mathcal{U}</math> || align=right | [0,1] || Bounds of control function
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+| align=center | <math>\mathcal{W}</math> || align=right | [0,1] || Bounds of measurement function
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 | align=center | <math>\mathcal{M}</math> || align=right | 0.2 || Maximum measurement time