D'Onofrio model (binary variant)

This site describes a D'Onofrio model variant with four binary controls instead which of only two continuous controls. The continuous controls are replaced via the outer convexifacation method.

Mathematical formulation

For the optimal control problem is given by

Failed to parse (PNG conversion failed; check for correct installation of latex and dvipng (or dvips + gs + convert)): {\begin{array}{llcl}\displaystyle \min _{{x,u}}&x_{0}(t_{f})&+&\alpha \int _{{t_{0}}}^{{t_{f}}}u_{0}(t)^{2}{\text{d}}t\\[1.5ex]{\mbox{s.t.}}&{\dot {x}}_{0}&=&-\zeta x_{0}{\text{ln}}\left({\frac {x_{0}}{x_{1}}}\right)-\sum \limits _{{i=1}}^{{4}}w_{i}\;c_{{1,i}}\;F\;x_{0},\\&{\dot {x}}_{1}&=&bx_{0}-\mu x_{1}-dx_{0}^{{{\frac {2}{3}}}}x_{1}-\sum \limits _{{i=1}}^{{4}}w_{i}c_{{0,i}}Gx_{1}-\sum \limits _{{i=1}}^{{4}}w_{i}\;c_{{1,i}}\eta x_{1},\\&{\dot {x}}_{2}&=&\sum \limits _{{i=1}}^{{4}}w_{i}\;c_{{0,i}},\\&{\dot {x}}_{3}&=&\sum \limits _{{i=1}}^{{4}}w_{i}\;c_{{1,i}},\\[1.5ex]&x_{2}&\leq &x_{2}^{{max}},\\&x_{3}&\leq &x_{3}^{{max}},&1&=&\sum \limits _{{i=1}}^{{3}}w_{i}(t),\\&w_{i}(t)&\in &\{0,1\},\quad i=1\ldots 4.\end{array}}

Parameters

These fixed values are used within the model:

Reference Solutions

If the problem is relaxed, i.e., we demand that be in the continuous interval instead of the binary choice , the optimal solution can be determined by means of direct optimal control.

The optimal objective value of the relaxed problem with is . The objective value of the binary controls obtained by Combinatorial Integral Approimation (CIA) is .

• Reference solution plots
• 

  Optimal relaxed controls and states determined by an direct approach with ampl_mintoc (Radau collocation) and .

• 

  Optimal binary controls and states determined by an direct approach (Radau collocation) with ampl_mintoc and . The relaxed controls were approximated by Combinatorial Integral Approximation.

Source Code

Model description is available in

• AMPL code at Van der Pol Oscillator binary variant(AMPL)