# Error in solving a nonlinear optimization system with dynamic constraint using openopt and scipy

I'm trying to solve an nonlinear optimal control problem subject to dynamic ( h(x, x', u) = 0 ) constraint.
given:
f(x) = (u(t) - u(0)(t))^2 # u0(t) is the initial input provided to the system
h(x) = y'(t) - integral(sqrt(u(t))*y(t) + y(t)) = 0 # a nonlinear differential equation
-2 < y(t) < 10 # system state is bounded to this range
-2 < u(t) < 10 # system state is bounded to this range
u0(t) # will be defined as an arbitrary piecewise-linear function

I've tried to translate the problem into python code using openopt and scipy:

``````import numpy as np
from scipy.integrate import *
from openopt import NLP
import matplotlib.pyplot as plt
from operator import and_

N = 15*4
y0 = 10
t0 = 0
tf = 10
lb, ub = np.ones(2)*-2, np.ones(2)*10

t = np.linspace(t0, tf, N)
u0 = np.piecewise(t, [t < 3, and_(3 <= t, t < 6), 6 <= t], [2, lambda t: t - 3, lambda t: -t + 9])

p = np.empty(N, dtype=np.object)
r = np.empty(N, dtype=np.object)
y = np.empty(N, dtype=np.object)
u = np.empty(N, dtype=np.object)
ff = np.empty(N, dtype=np.object)
for i in range(N):
t = np.linspace(t0, tf, N)
b, a = t[i], t[i - 1]
integrand = lambda t, u1, y1 : np.sqrt(u1)*y1 + y1
integral = lambda u1, y1 : fixed_quad(integrand, a, b, args=(u1, y1))[0]
f = lambda x1: ((x1[1] - u0[i])**2).sum()
h = lambda x1: x1[0] - y0 - integral(x1[0], x1[1])
p[i] = NLP(f, (y0, u0[i]), h=h, lb=lb, ub=ub)
r[i] = p[i].solve('scipy_slsqp')
y0 = r[i].xf[0]
y[i] = r[i].xf[0]
u[i] = r[i].xf[1]
ff[i] = r[i].ff

figure1 = plt.figure()
plt.plot(u0)
plt.plot(u)
plt.plot(y)
plt.show()
``````

Now the problem is, running the code with a positive initial y0 like y0 = 10 , the code will result satisfying results. But giving y0 = 0 or a negative one y0 = -1, nlp problem will be deficient, saying:
"NO FEASIBLE SOLUTION has been obtained (1 constraint is equal to NaN, MaxResidual = 0, objFunc = nan)"
Also, considering the piecewise-linear initial u0, if you put any number other than 0 at the first range of the function at `t < 3`, meaning:
`u0 = np.piecewise(t, [t < 3, and_(3 <= t, t < 6), 6 <= t], [2, lambda t: t - 3, lambda t: -t + 9])`
`u0 = np.piecewise(t, [t < 3, and_(3 <= t, t < 6), 6 <= t], [0, lambda t: t - 3, lambda t: -t + 9])`
This will result in the same error again.
Any ideas ?

-

My first thought is that you seem to be solving a 2-dimensional Optimal Control problem as if it were a 1-Dimensional problem.

The constraint dynamics \$h(x, x', t)\$ are really a second order ODE.

y''(t) - sqrt(u(t))*y(t) + y(t)) = 0

Starting from this I would reword my system as a 2-dimensional, 1st order system in the standard way.

My second thought is that you seem to be optimizing independently, for \$u(t)\$, at each time step, whereas the problem is to optimize globally for \$u(.)\$, the entire function. So if anything, the call to NLP should be outside the for loop...

There are dedicated Optimal Control Open Source toolboxes:

Pythonically, there is JModellica: http://www.jmodelica.org/.