92 lines
2.4 KiB
Python
Executable File
92 lines
2.4 KiB
Python
Executable File
#! /usr/bin/env python
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import numpy as np
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import matplotlib.pyplot as plt
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from matplotlib import animation
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from utils import compute_path_from_wp
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from cvxpy_mpc import optimize
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import sys
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import time
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# classes
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class MPC():
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def __init__(self):
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# State for the robot mathematical model [x,y,heading]
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self.state = np.zeros(3)
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# Sim step
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self.dt = 0.25
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# starting guess output
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N = 5 #number of state variables
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M = 2 #number of control variables
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T = 20 #Prediction Horizon
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self.opt_u = np.zeros((M,T))
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self.opt_u[0,:] = 1 #m/s
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self.opt_u[1,:] = np.radians(0) #rad/s
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# Interpolated Path to follow given waypoints
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self.path = compute_path_from_wp([0,20,30,30],[0,0,10,20])
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#Initialise plot
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# First set up the figure, the axis, and the plot element we want to animate
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plt.style.use("ggplot")
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self.fig = plt.figure()
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plt.ion()
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plt.show()
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def run(self):
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'''
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'''
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while 1:
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if self.state is not None:
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#optimization loop
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start=time.time()
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self.opt_u = optimize(self.state,
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self.opt_u,
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self.path)
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print("CVXPY Optimization Time: {:.4f}s".format(time.time()-start))
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self.update_sim(self.opt_u[0,1],self.opt_u[1,1])
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self.plot_sim()
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def update_sim(self,lin_v,ang_v):
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'''
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Updates state.
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:param lin_v: float
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:param ang_v: float
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'''
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self.state[0] = self.state[0] +lin_v*np.cos(self.state[2])*self.dt
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self.state[1] = self.state[1] +lin_v*np.sin(self.state[2])*self.dt
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self.state[2] = self.state[2] +ang_v*self.dt
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def plot_sim(self):
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plt.clf()
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self.ax = plt.axes(xlim=(np.min(self.path[0,:])-1, np.max(self.path[0,:])+1),
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ylim=(np.min(self.path[1,:])-1, np.max(self.path[1,:])+1))
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self.track, = self.ax.plot(self.path[0,:],self.path[1,:], "g-", label="reference track")
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self.vehicle, = self.ax.plot([self.state[0]], [self.state[1]], "r*", label="vehicle path")
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plt.legend()
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plt.draw()
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plt.pause(0.1)
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def do_sim():
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sim=MPC()
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try:
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sim.run()
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except Exception as e:
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sys.exit(e)
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if __name__ == '__main__':
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do_sim()
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