Double Oscillator

The Double Oscillator problem is a benchmark in constrained optimal control illustrating the control of coupled mechanical systems with damping and stiffness effects. This description is taken from [1]

It consists of two masses connected by springs and a damper, with one mass directly influenced by an external periodic force and the other influenced indirectly through the coupling and a controlled damping term. Both the state trajectory ${\displaystyle x(\cdot )}$ and the control ${\displaystyle u(\cdot )}$ are decision variables. The aim is to minimise a quadratic cost that balances state deviations and control effort, subject to input constraints and the system dynamics.

Mathematical formulation

${\displaystyle \begin{array}{lll}{\displaystyle \underset{u}{\min }}& & \frac{1}{2}{\displaystyle \underset{0}{\overset{T}{\int }}}(x_0(t{)}^2+x_1(t{)}^2+u(t{)}^2)\\ \text{subject to}\\ \dot{x_0}(t)& =& x_2(t),\\ \dot{x_1}(t)& =& x_3(t),\\ \dot{x_2}(t)& =& -\frac{k_1+k_2}{m_1}\cdot x_0+\frac{k_2}{m_1}\cdot x_1+\frac{1}{m_1}\sin (\frac{2\pi }{T}\cdot t),\\ \dot{x_3}(t)& =& \frac{k_2}{m_2}{x}_0(t)-\frac{k_2}{m_2}{x}_1(t)-\frac{c(1-u)}{m_2}{x}_3(t),\\ x_1(0)& =& 0,\\ x_2(0)& =& 0,\\ u(t)& \in & [-1,1]\mathrm{\forall }t\in [0,t_f]\end{array}}$

Parameters

These fixed values are used within the model:

Reference Solutions

Here is one local solution to the above control problem.

• Reference solution plots
• 
  States and discretized control for a local optimum. The control ${\displaystyle t_f}$ represents the scaling of the time interval, where the base time interval is [0,5].

Miscellaneous and Further Reading

This formulation and a detailed description can be found in [1].

References

[1] Caillau, J.-B., Cots, O., Gergaud, J., & Martinon, P. OptimalControlProblems.jl: a collection of optimal control problems with ODE's in Julia. https://github.com/control-toolbox/OptimalControlProblems.jl/blob/main/ext/Descriptions/dielectrophoretic_particle.md