updated pybullet mpc demo to latest version
parent
cac053410c
commit
ef175816d8
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@ -5,7 +5,7 @@ from scipy.integrate import odeint
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from scipy.interpolate import interp1d
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from scipy.interpolate import interp1d
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import cvxpy as cp
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import cvxpy as cp
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from utils import road_curve, f, df
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from utils import *
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from mpc_config import Params
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from mpc_config import Params
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P=Params()
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P=Params()
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@ -50,16 +50,17 @@ def optimize(state,u_bar,track,ref_vel=1.):
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:returns:
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:returns:
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'''
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'''
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MAX_SPEED = ref_vel*1.5
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MAX_SPEED = 1.5 #m/s
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MAX_STEER = np.pi/4
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MAX_ACC = 1.0 #m/ss
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MAX_ACC = 1.0
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MAX_D_ACC = 1.0 #m/sss
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MAX_STEER = np.radians(30) #rad
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MAX_D_STEER = np.radians(30) #rad/s
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# compute polynomial coefficients of the track
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REF_VEL = ref_vel #m/s
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K=road_curve(state,track)
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# dynamics starting state w.r.t vehicle frame
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# dynamics starting state
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x_bar=np.zeros((P.N,P.T+1))
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x_bar = np.zeros((P.N,P.T+1))
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x_bar[2,0]=state[2]
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x_bar[:,0] = state
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#prediction for linearization of costrains
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#prediction for linearization of costrains
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for t in range (1,P.T+1):
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for t in range (1,P.T+1):
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@ -75,29 +76,40 @@ def optimize(state,u_bar,track,ref_vel=1.):
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x = cp.Variable((P.N, P.T+1))
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x = cp.Variable((P.N, P.T+1))
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u = cp.Variable((P.M, P.T))
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u = cp.Variable((P.M, P.T))
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# Cost Matrices
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Q = np.diag([20,20,10,0]) #state error cost
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Qf = np.diag([10,10,10,10]) #state final error cost
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R = np.diag([10,10]) #input cost
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R_ = np.diag([10,10]) #input rate of change cost
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#Get Reference_traj
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x_ref, d_ref = get_ref_trajectory(x_bar[:,0] ,track, REF_VEL)
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#Prediction Horizon
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for t in range(P.T):
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for t in range(P.T):
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cost += 20*cp.sum_squares(x[3,t]-np.clip(np.arctan(df(x_bar[0,t],K)),-np.pi,np.pi) ) # psi
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# Tracking Error
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cost += 40*cp.sum_squares(f(x_bar[0,t],K)-x[1,t]) # cte
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cost += cp.quad_form(x[:,t] - x_ref[:,t], Q)
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cost += 20*cp.sum_squares(ref_vel-x[2,t]) # desired v
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# Actuation effort
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cost += cp.quad_form(u[:,t], R)
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# Actuation rate of change
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# Actuation rate of change
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if t < (P.T - 1):
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if t < (P.T - 1):
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cost += cp.quad_form(u[:, t + 1] - u[:, t], 10*np.eye(P.M))
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cost += cp.quad_form(u[:,t+1] - u[:,t], R_)
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constr+= [cp.abs(u[0, t + 1] - u[0, t])/P.dt <= MAX_D_ACC] #max acc rate of change
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# Actuation effort
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constr += [cp.abs(u[1, t + 1] - u[1, t])/P.dt <= MAX_D_STEER] #max steer rate of change
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cost += cp.quad_form( u[:, t],10*np.eye(P.M))
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# Kinrmatics Constrains (Linearized model)
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# Kinrmatics Constrains (Linearized model)
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A,B,C=get_linear_model(x_bar[:,t],u_bar[:,t])
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A,B,C = get_linear_model(x_bar[:,t], u_bar[:,t])
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constr += [x[:,t+1] == A@x[:,t] + B@u[:,t] + C.flatten()]
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constr += [x[:,t+1] == A@x[:,t] + B@u[:,t] + C.flatten()]
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# sums problem objectives and concatenates constraints.
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# sums problem objectives and concatenates constraints.
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constr += [x[:,0] == x_bar[:,0]] #<--watch out the start condition
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constr += [x[:,0] == x_bar[:,0]] #starting condition
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constr += [x[2, :] <= MAX_SPEED]
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constr += [x[2,:] <= MAX_SPEED] #max speed
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constr += [x[2, :] >= 0.0]
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constr += [x[2,:] >= 0.0] #min_speed (not really needed)
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constr += [cp.abs(u[0, :]) <= MAX_ACC]
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constr += [cp.abs(u[0,:]) <= MAX_ACC] #max acc
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constr += [cp.abs(u[1, :]) <= MAX_STEER]
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constr += [cp.abs(u[1,:]) <= MAX_STEER] #max steer
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# Solve
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# Solve
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prob = cp.Problem(cp.Minimize(cost), constr)
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prob = cp.Problem(cp.Minimize(cost), constr)
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@ -4,3 +4,4 @@ class Params():
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self.M = 2 #number of control variables
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self.M = 2 #number of control variables
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self.T = 10 #Prediction Horizon
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self.T = 10 #Prediction Horizon
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self.dt = 0.25 #discretization step
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self.dt = 0.25 #discretization step
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self.path_tick = 0.05
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@ -35,7 +35,7 @@ class MPC():
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# Interpolated Path to follow given waypoints
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# Interpolated Path to follow given waypoints
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#self.path = compute_path_from_wp([0,10,12,2,4,14],[0,0,2,10,12,12])
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#self.path = compute_path_from_wp([0,10,12,2,4,14],[0,0,2,10,12,12])
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self.path = compute_path_from_wp([0,3,4,6,10,12,13,13,6,1,0],
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self.path = compute_path_from_wp([0,3,4,6,10,12,13,13,6,1,0],
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[0,0,2,4,3,3,-1,-2,-6,-2,-2],0.5)
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[0,0,2,4,3,3,-1,-2,-6,-2,-2],P.path_tick)
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# Sim help vars
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# Sim help vars
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self.sim_time=0
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self.sim_time=0
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@ -20,7 +20,7 @@ def get_state(robotId):
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robPos, robOrn = p.getBasePositionAndOrientation(robotId)
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robPos, robOrn = p.getBasePositionAndOrientation(robotId)
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linVel,angVel = p.getBaseVelocity(robotId)
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linVel,angVel = p.getBaseVelocity(robotId)
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return[robPos[0], robPos[1], linVel[0], p.getEulerFromQuaternion(robOrn)[2]]
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return[robPos[0], robPos[1], np.sqrt(linVel[0]**2 + linVel[1]**2), p.getEulerFromQuaternion(robOrn)[2]]
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def set_ctrl(robotId,currVel,acceleration,steeringAngle):
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def set_ctrl(robotId,currVel,acceleration,steeringAngle):
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@ -105,7 +105,7 @@ def run_sim():
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# Interpolated Path to follow given waypoints
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# Interpolated Path to follow given waypoints
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path = compute_path_from_wp([0,3,4,6,10,11,12,6,1,0],
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path = compute_path_from_wp([0,3,4,6,10,11,12,6,1,0],
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[0,0,2,4,3,3,-1,-6,-2,-2],0.5)
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[0,0,2,4,3,3,-1,-6,-2,-2],P.path_tick)
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for x_,y_ in zip(path[0,:],path[1,:]):
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for x_,y_ in zip(path[0,:],path[1,:]):
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p.addUserDebugLine([x_,y_,0],[x_,y_,0.33],[0,0,1])
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p.addUserDebugLine([x_,y_,0],[x_,y_,0.33],[0,0,1])
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@ -1,16 +1,22 @@
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import numpy as np
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import numpy as np
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from scipy.interpolate import interp1d
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from scipy.interpolate import interp1d
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from mpc_config import Params
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P=Params()
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def compute_path_from_wp(start_xp, start_yp, step = 0.1):
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def compute_path_from_wp(start_xp, start_yp, step = 0.1):
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"""
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"""
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Computes a reference path given a set of waypoints
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"""
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"""
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final_xp=[]
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final_xp=[]
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final_yp=[]
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final_yp=[]
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delta = step #[m]
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delta = step #[m]
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for idx in range(len(start_xp)-1):
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for idx in range(len(start_xp)-1):
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section_len = np.sqrt(np.sum(np.power(np.diff(start_xp[idx:idx+2]),2)+np.power(np.diff(start_yp[idx:idx+2]),2)))
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section_len = np.sum(np.sqrt(np.power(np.diff(start_xp[idx:idx+2]),2)+np.power(np.diff(start_yp[idx:idx+2]),2)))
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interp_range = np.linspace(0,1, int(1+section_len/delta))
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interp_range = np.linspace(0,1,np.floor(section_len/delta).astype(int))
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fx=interp1d(np.linspace(0,1,2),start_xp[idx:idx+2],kind=1)
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fx=interp1d(np.linspace(0,1,2),start_xp[idx:idx+2],kind=1)
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fy=interp1d(np.linspace(0,1,2),start_yp[idx:idx+2],kind=1)
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fy=interp1d(np.linspace(0,1,2),start_yp[idx:idx+2],kind=1)
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@ -18,14 +24,21 @@ def compute_path_from_wp(start_xp, start_yp, step = 0.1):
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final_xp=np.append(final_xp,fx(interp_range))
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final_xp=np.append(final_xp,fx(interp_range))
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final_yp=np.append(final_yp,fy(interp_range))
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final_yp=np.append(final_yp,fy(interp_range))
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return np.vstack((final_xp,final_yp))
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dx = np.append(0, np.diff(final_xp))
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dy = np.append(0, np.diff(final_yp))
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theta = np.arctan2(dy, dx)
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return np.vstack((final_xp,final_yp,theta))
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def get_nn_idx(state,path):
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def get_nn_idx(state,path):
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"""
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"""
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Computes the index of the waypoint closest to vehicle
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"""
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"""
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dx = state[0]-path[0,:]
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dx = state[0]-path[0,:]
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dy = state[1]-path[1,:]
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dy = state[1]-path[1,:]
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dist = np.sqrt(dx**2 + dy**2)
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dist = np.hypot(dx,dy)
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nn_idx = np.argmin(dist)
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nn_idx = np.argmin(dist)
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try:
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try:
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@ -46,53 +59,42 @@ def get_nn_idx(state,path):
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return target_idx
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return target_idx
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def road_curve(state,track):
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def get_ref_trajectory(state, path, target_v):
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"""
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"""
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"""
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"""
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xref = np.zeros((P.N, P.T + 1))
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dref = np.zeros((1, P.T + 1))
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POLY_RANK = 3
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#sp = np.ones((1,T +1))*target_v #speed profile
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#given vehicle pos find lookahead waypoints
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ncourse = path.shape[1]
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nn_idx=get_nn_idx(state,track)
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LOOKAHED = POLY_RANK*2
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lk_wp=track[:,max(0,nn_idx-1):nn_idx+LOOKAHED]
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#trasform lookahead waypoints to vehicle ref frame
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ind = get_nn_idx(state, path)
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dx = lk_wp[0,:] - state[0]
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dy = lk_wp[1,:] - state[1]
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wp_vehicle_frame = np.vstack(( dx * np.cos(-state[3]) - dy * np.sin(-state[3]),
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xref[0, 0] = path[0,ind] #X
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dy * np.cos(-state[3]) + dx * np.sin(-state[3]) ))
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xref[1, 0] = path[1,ind] #Y
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xref[2, 0] = target_v #sp[ind] #V
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xref[3, 0] = path[2,ind] #Theta
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dref[0, 0] = 0.0 # steer operational point should be 0
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#fit poly
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dl = P.path_tick # Waypoints spacing [m]
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return np.polyfit(wp_vehicle_frame[0,:], wp_vehicle_frame[1,:], POLY_RANK, rcond=None, full=False, w=None, cov=False)
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travel = 0.0
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# def f(x,coeff):
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for i in range(P.T + 1):
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# """
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travel += abs(target_v) * P.dt #current V or target V?
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# """
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dind = int(round(travel / dl))
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# return round(coeff[0]*x**3 + coeff[1]*x**2 + coeff[2]*x**1 + coeff[3]*x**0,6)
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# def f(x,coeff):
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if (ind + dind) < ncourse:
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# return round(coeff[0]*x**5+coeff[1]*x**4+coeff[2]*x**3+coeff[3]*x**2+coeff[4]*x**1+coeff[5]*x**0,6)
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xref[0, i] = path[0,ind + dind]
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xref[1, i] = path[1,ind + dind]
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xref[2, i] = target_v #sp[ind + dind]
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xref[3, i] = path[2,ind + dind]
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dref[0, i] = 0.0
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else:
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xref[0, i] = path[0,ncourse - 1]
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xref[1, i] = path[1,ncourse - 1]
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xref[2, i] = 0.0 #stop? #sp[ncourse - 1]
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xref[3, i] = path[2,ncourse - 1]
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dref[0, i] = 0.0
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def f(x,coeff):
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return xref, dref
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y=0
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j=len(coeff)
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for k in range(j):
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y += coeff[k]*x**(j-k-1)
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return round(y,6)
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# def df(x,coeff):
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# """
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# """
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# return round(3*coeff[0]*x**2 + 2*coeff[1]*x**1 + coeff[2]*x**0,6)
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# def df(x,coeff):
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# return round(5*coeff[0]*x**4 + 4*coeff[1]*x**3 +3*coeff[2]*x**2 + 2*coeff[3]*x**1 + coeff[4]*x**0,6)
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def df(x,coeff):
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y=0
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j=len(coeff)
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for k in range(j-1):
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y += (j-k-1)*coeff[k]*x**(j-k-2)
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return round(y,6)
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