forked from Telos4/RoboRally
started working on optimization based controller
This commit is contained in:
parent
0d14738671
commit
f100f21162
|
@ -2,9 +2,12 @@ from casadi import *
|
|||
|
||||
# look at: https://github.com/casadi/casadi/blob/master/docs/examples/python/vdp_indirect_multiple_shooting.py
|
||||
|
||||
T = 3.0
|
||||
N = 30
|
||||
class OpenLoopSolver:
|
||||
def __init__(self, N=60, T=6.0):
|
||||
self.T = T
|
||||
self.N = N
|
||||
|
||||
def solve(self, x0):
|
||||
x = SX.sym('x')
|
||||
y = SX.sym('y')
|
||||
theta = SX.sym('theta')
|
||||
|
@ -12,24 +15,27 @@ state = vertcat(x, y, theta)
|
|||
r = 0.03
|
||||
R = 0.05
|
||||
d = 0.02
|
||||
#r = SX.sym('r')
|
||||
#R = SX.sym('R')
|
||||
#d = SX.sym('d')
|
||||
|
||||
omegar = SX.sym('omegar')
|
||||
omegal = SX.sym('omegal')
|
||||
control = vertcat(omegar, omegal)
|
||||
f1 = (r/2 * cos(theta) - r*d/(2*R) * sin(theta)) * omegar + (r/2 * cos(theta) + r*d/(2*R) * sin(theta)) * omegal
|
||||
f2 = (r/2 * sin(theta) + r*d/(2*R) * cos(theta)) * omegar + (r/2 * sin(theta) - r*d/(2*R) * cos(theta)) * omegal
|
||||
|
||||
# model equation
|
||||
f1 = (r / 2 * cos(theta) - r * d / (2 * R) * sin(theta)) * omegar + (r / 2 * cos(theta) + r * d / (2 * R) * sin(
|
||||
theta)) * omegal
|
||||
f2 = (r / 2 * sin(theta) + r * d / (2 * R) * cos(theta)) * omegar + (r / 2 * sin(theta) - r * d / (2 * R) * cos(
|
||||
theta)) * omegal
|
||||
f3 = r / (2 * R) * omegar - r / (2 * R) * omegal
|
||||
xdot = vertcat(f1, f2, f3)
|
||||
f = Function('f', [x, y, theta, omegar, omegal], [f1, f2, f3])
|
||||
print("f = {}".format(f))
|
||||
|
||||
# cost functional
|
||||
L = x ** 2 + y ** 2 + 1e-2 * theta ** 2 + 1e-4 * (omegar ** 2 + omegal ** 2)
|
||||
|
||||
# Fixed step Runge-Kutta 4 integrator
|
||||
M = 4 # RK4 steps per interval
|
||||
DT = T/N/M
|
||||
DT = self.T / self.N / M
|
||||
print("DT = {}".format(DT))
|
||||
f = Function('f', [state, control], [xdot, L])
|
||||
X0 = MX.sym('X0', 3)
|
||||
|
@ -46,7 +52,7 @@ if runge_kutta:
|
|||
X = X + DT / 6 * (k1 + 2 * k2 + 2 * k3 + k4)
|
||||
Q = Q + DT / 6 * (k1_q + 2 * k2_q + 2 * k3_q + k4_q)
|
||||
else:
|
||||
DT = T/N
|
||||
DT = self.T / self.N
|
||||
k1, k1_q = f(X, U)
|
||||
X = X + DT * k1
|
||||
Q = Q + DT * k1_q
|
||||
|
@ -69,8 +75,8 @@ lbg = []
|
|||
ubg = []
|
||||
|
||||
# Formulate the NLP
|
||||
Xk = MX([1.1, 1.1, 0.0])
|
||||
for k in range(N):
|
||||
Xk = MX(x0)
|
||||
for k in range(self.N):
|
||||
# New NLP variable for the control
|
||||
U1k = MX.sym('U1_' + str(k), 2)
|
||||
# U2k = MX.sym('U2_' + str(k))
|
||||
|
@ -91,25 +97,25 @@ for k in range(N):
|
|||
|
||||
# Create an NLP solver
|
||||
prob = {'f': J, 'x': vertcat(*w), 'g': vertcat(*g)}
|
||||
solver = nlpsol('solver', 'ipopt', prob);
|
||||
self.solver = nlpsol('solver', 'ipopt', prob)
|
||||
|
||||
# Solve the NLP
|
||||
sol = solver(x0=w0, lbx=lbw, ubx=ubw, lbg=lbg, ubg=ubg)
|
||||
sol = self.solver(x0=w0, lbx=lbw, ubx=ubw, lbg=lbg, ubg=ubg)
|
||||
w_opt = sol['x']
|
||||
|
||||
# Plot the solution
|
||||
u_opt = w_opt
|
||||
x_opt = [[1.1, 1.1, -0.0]]
|
||||
for k in range(N):
|
||||
x_opt = [x0]
|
||||
for k in range(self.N):
|
||||
Fk = F(x0=x_opt[-1], p=u_opt[2*k:2*k+2])
|
||||
x_opt += [Fk['xf'].full()]
|
||||
x1_opt = [r[0] for r in x_opt]
|
||||
x2_opt = [r[1] for r in x_opt]
|
||||
x3_opt = [r[2] for r in x_opt]
|
||||
|
||||
tgrid = [T/N*k for k in range(N+1)]
|
||||
tgrid = [self.T/self.N*k for k in range(self.N+1)]
|
||||
import matplotlib.pyplot as plt
|
||||
plt.figure(1)
|
||||
plt.figure(2)
|
||||
plt.clf()
|
||||
plt.plot(tgrid, x1_opt, '--')
|
||||
plt.plot(tgrid, x2_opt, '-')
|
||||
|
@ -119,17 +125,18 @@ plt.xlabel('t')
|
|||
plt.legend(['x1','x2','x3','u'])
|
||||
plt.grid()
|
||||
#plt.show()
|
||||
#return
|
||||
|
||||
# alternative solution using multiple shooting (way faster!)
|
||||
opti = Opti() # Optimization problem
|
||||
|
||||
# ---- decision variables ---------
|
||||
X = opti.variable(3,N+1) # state trajectory
|
||||
Q = opti.variable(1,N+1) # state trajectory
|
||||
X = opti.variable(3,self.N+1) # state trajectory
|
||||
Q = opti.variable(1,self.N+1) # state trajectory
|
||||
posx = X[0,:]
|
||||
posy = X[1,:]
|
||||
angle = X[2,:]
|
||||
U = opti.variable(2,N) # control trajectory (throttle)
|
||||
U = opti.variable(2,self.N) # control trajectory (throttle)
|
||||
#T = opti.variable() # final time
|
||||
|
||||
# ---- objective ---------
|
||||
|
@ -138,8 +145,8 @@ U = opti.variable(2,N) # control trajectory (throttle)
|
|||
# ---- dynamic constraints --------
|
||||
#f = lambda x,u: vertcat(f1, f2, f3) # dx/dt = f(x,u)
|
||||
|
||||
dt = T/N # length of a control interval
|
||||
for k in range(N): # loop over control intervals
|
||||
dt = self.T/self.N # length of a control interval
|
||||
for k in range(self.N): # loop over control intervals
|
||||
# Runge-Kutta 4 integration
|
||||
k1, k1_q = f(X[:,k], U[:,k])
|
||||
k2, k2_q = f(X[:,k]+dt/2*k1, U[:,k])
|
||||
|
@ -149,7 +156,7 @@ for k in range(N): # loop over control intervals
|
|||
q_next = Q[:,k] + dt/6*(k1_q + 2 * k2_q + 2 * k3_q + k4_q)
|
||||
opti.subject_to(X[:,k+1]==x_next) # close the gaps
|
||||
opti.subject_to(Q[:,k+1]==q_next) # close the gaps
|
||||
opti.minimize(Q[:,N])
|
||||
opti.minimize(Q[:,self.N])
|
||||
|
||||
# ---- path constraints -----------
|
||||
#limit = lambda pos: 1-sin(2*pi*pos)/2
|
||||
|
@ -157,9 +164,9 @@ opti.minimize(Q[:,N])
|
|||
opti.subject_to(opti.bounded(-10,U,10)) # control is limited
|
||||
|
||||
# ---- boundary conditions --------
|
||||
opti.subject_to(posx[0]==1.10) # start at position 0 ...
|
||||
opti.subject_to(posy[0]==1.10) # ... from stand-still
|
||||
opti.subject_to(angle[0]==0.0) # finish line at position 1
|
||||
opti.subject_to(posx[0]==x0[0]) # start at position 0 ...
|
||||
opti.subject_to(posy[0]==x0[1]) # ... from stand-still
|
||||
opti.subject_to(angle[0]==x0[2]) # finish line at position 1
|
||||
#opti.subject_to(speed[-1]==0) # .. with speed 0
|
||||
opti.subject_to(Q[:,0]==0.0)
|
||||
|
||||
|
@ -168,11 +175,12 @@ opti.subject_to(Q[:,0]==0.0)
|
|||
#opti.subject_to(X[2,:]<=4) # Time must be positive
|
||||
#opti.subject_to(X[2,:]>=-2) # Time must be positive
|
||||
|
||||
r = 0.25
|
||||
p = (0.5, 0.5)
|
||||
for k in range(N):
|
||||
opti.subject_to((X[0,k]-p[0])**2 + (X[1,k]-p[1])**2 > r**2)
|
||||
pass
|
||||
# avoid obstacle
|
||||
#r = 0.25
|
||||
#p = (0.5, 0.5)
|
||||
#for k in range(self.N):
|
||||
# opti.subject_to((X[0,k]-p[0])**2 + (X[1,k]-p[1])**2 > r**2)
|
||||
# pass
|
||||
|
||||
|
||||
# ---- initial values for solver ---
|
||||
|
@ -195,7 +203,7 @@ plot(sol.value(posx),label="posx")
|
|||
plot(sol.value(posy),label="posy")
|
||||
plot(sol.value(angle),label="angle")
|
||||
|
||||
plt.figure()
|
||||
plt.figure(3)
|
||||
plot(sol.value(posx), sol.value(posy))
|
||||
ax = plt.gca()
|
||||
circle = plt.Circle(p, r)
|
||||
|
|
|
@ -20,6 +20,8 @@ import matplotlib.animation as anim
|
|||
|
||||
import time
|
||||
|
||||
from casadi_opt import OpenLoopSolver
|
||||
|
||||
from marker_pos_angle.msg import id_pos_angle
|
||||
|
||||
class Robot:
|
||||
|
@ -59,7 +61,7 @@ def f_ode(t, x, u):
|
|||
class RemoteController:
|
||||
def __init__(self):
|
||||
|
||||
self.robots = [Robot(3)]
|
||||
self.robots = [Robot(5)]
|
||||
|
||||
self.robot_ids = {}
|
||||
for r in self.robots:
|
||||
|
@ -69,7 +71,7 @@ class RemoteController:
|
|||
self.rc_socket = socket.socket()
|
||||
try:
|
||||
pass
|
||||
self.rc_socket.connect(('192.168.1.101', 1234)) # connect to robot
|
||||
self.rc_socket.connect(('192.168.1.103', 1234)) # connect to robot
|
||||
except socket.error:
|
||||
print("could not connect to socket")
|
||||
|
||||
|
@ -117,6 +119,8 @@ class RemoteController:
|
|||
plt.xlabel('x-position')
|
||||
plt.ylabel('y-position')
|
||||
|
||||
self.ols = OpenLoopSolver()
|
||||
|
||||
def ani(self):
|
||||
self.ani = anim.FuncAnimation(self.fig, init_func=self.ani_init, func=self.ani_update, interval=10, blit=True)
|
||||
plt.ion()
|
||||
|
@ -208,7 +212,8 @@ class RemoteController:
|
|||
|
||||
keyboard_control = False
|
||||
keyboard_control_speed_test = False
|
||||
pid = True
|
||||
pid = False
|
||||
open_loop_solve = True
|
||||
|
||||
if keyboard_control: # keyboard controller
|
||||
events = pygame.event.get()
|
||||
|
@ -330,6 +335,15 @@ class RemoteController:
|
|||
|
||||
time.sleep(dt)
|
||||
|
||||
elif open_loop_solve:
|
||||
# open loop controller
|
||||
|
||||
events = pygame.event.get()
|
||||
for event in events:
|
||||
if event.type == pygame.KEYDOWN:
|
||||
if event.key == pygame.K_UP:
|
||||
self.ols.solve(self.xms[-1])
|
||||
|
||||
def main(args):
|
||||
rospy.init_node('controller_node', anonymous=True)
|
||||
|
||||
|
|
Loading…
Reference in New Issue
Block a user