Difference between revisions of "Cushioned Oscillation (PROPT)"
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− | Below you can find the MATLAB file that was used to create the reference solution and its plot. | + | Below you can find the MATLAB file that was used in [[:Category: TomDyn/PROPT | TomDyn/PROPT]] to create the reference solution and its plot for the [[Cushioned Oscillation]] problem. |
<source lang="matlab"> | <source lang="matlab"> | ||
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v_0 = 5; %starting velocity in m/s | v_0 = 5; %starting velocity in m/s | ||
umm = 5; %control constraint | umm = 5; %control constraint | ||
− | m = | + | m = 5; %mass in kg |
c = 10; %spring stiffness in N/m | c = 10; %spring stiffness in N/m | ||
Line 25: | Line 25: | ||
%Setup | %Setup | ||
− | toms t t_f % | + | toms t t_f %independent variables |
p = tomPhase('p', t, t_0, t_f, n); | p = tomPhase('p', t, t_0, t_f, n); | ||
setPhase(p); | setPhase(p); | ||
Line 38: | Line 38: | ||
collocate({u == 0 | collocate({u == 0 | ||
}) | }) | ||
− | icollocate({ | + | icollocate({x == xi(1) |
− | + | v == xi(2) | |
})}; | })}; | ||
Line 74: | Line 74: | ||
tfopt = subs(t_f,solution); | tfopt = subs(t_f,solution); | ||
− | xopt = subs( | + | xopt = subs(x,solution); |
vopt = subs(v,solution); | vopt = subs(v,solution); | ||
uopt = subs(u,solution); | uopt = subs(u,solution); |
Latest revision as of 18:49, 31 January 2016
Below you can find the MATLAB file that was used in TomDyn/PROPT to create the reference solution and its plot for the Cushioned Oscillation problem.
%% Cushioned Oscillation % (c) Maximilian von Wolff % %% Problem Setup % % % %Problem Parameters t_0 = 0; x_0 = 2; %starting position v_0 = 5; %starting velocity in m/s umm = 5; %control constraint m = 5; %mass in kg c = 10; %spring stiffness in N/m n=80; %Number of collocation points %Setup toms t t_f %independent variables p = tomPhase('p', t, t_0, t_f, n); setPhase(p); tomStates x v tomControls u %initial states xi = [x_0; v_0]; %initial guess x0 = {t_f == 10 collocate({u == 0 }) icollocate({x == xi(1) v == xi(2) })}; %Box constraints cbox = {-umm <= collocate(u) <= umm }; %Boundary constraints cbnd = {initial({ x == xi(1); v == xi(2); }) final({ x == 0; v == 0; })}; % ODE's dx = v; dv = 1./m.*(u-c*x); ceq = collocate({ dot(x) == dx dot(v) == dv }); objective = t_f; %% Solve the problem options = struct; options.name = 'cushioned oscillation'; solution = ezsolve(objective, {cbox, cbnd, ceq}, x0, options); tfopt = subs(t_f,solution); xopt = subs(x,solution); vopt = subs(v,solution); uopt = subs(u,solution); %Plotting solution figure(1) subplot(3,1,1); ezplot(x); legend('x'); xlabel('time'); ylabel('position in m'); title('Position'); subplot(3,1,2); ezplot(v); legend('v'); xlabel('time'); ylabel('velocity in m/s'); title('Velocity'); subplot(3,1,3); ezplot(u); legend('u'); xlabel('time'); title('Control'); disp('Final Time'); disp(solution.t_f)