def test_triple_int_optimizer(self): params = Parameter() params.set("dt", 0.2) params.set("function_tolerance", 1e-6) params.set("max_num_iterations", 1000) initial_state = np.array([[0., 10., 0., 0., 10., 0., 0., 1., 0.], [2., 10., 0., 2., 10., 0., 0.2, 1., 0.], [4., 10., 0., 4., 10., 0., 0.4, 1., 0.], [6., 10., 0., 6., 10., 0., 0.6, 1., 0.]]) opt_vec = np.zeros(shape=(30, 3)) ref_line = np.array([[10., -100.], [50.1, 100.1]]) # optimizer opt = Optimizer(params) opt.SetOptimizationVector(opt_vec) # costs ref_cost = ReferenceLineCost(params, 10.) ref_cost.SetReferenceLine(ref_line) jerk_cost = JerkCost(params, 100.) speed_cost = SpeedCost(params, 10.) speed_cost.SetDesiredSpeed(20.) # optimization problem functor = opt.AddTripleIntFunctor(initial_state, params, [ref_cost, jerk_cost, speed_cost]) opt.FixOptimizationVector(0, 1) opt.Solve() opt.Report() inputs = opt.Result() trajectory = GenerateTrajectoryTripleInt(initial_state, inputs, params) fig = plt.figure() plt.subplot(144) ax = fig.add_subplot(144, projection='3d') plt.plot(trajectory[:, 0], trajectory[:, 3], trajectory[:, 6], marker='o') plt.plot([10, 50.1], [-100, 100], [0., 0.], marker='o') plt.axis("equal") plt.subplot(141) plt.plot(trajectory[:-3, 1], label="vx", marker='o') plt.plot(trajectory[:-3, 4], label="vy", marker='o', color="green") plt.plot(trajectory[:-3, 7], label="vz", marker='o', color="red") plt.xlabel("v [m/s]") plt.legend() plt.subplot(142) plt.plot(trajectory[:, 0], trajectory[:, 3], marker='o') plt.plot([10, 50.1], [-100, 100], marker='o') plt.axis("equal") plt.xlabel("x [m]") plt.ylabel("y [m]") plt.subplot(143) plt.plot(trajectory[:, 3], trajectory[:, 6], marker='o') plt.axis("equal") plt.xlabel("y [m]") plt.ylabel("z [m]") # fig, ax = plt.subplots(nrows=1, ncols=2) # colorbar_axis = ax[0].plot(trajectory[:, 0], trajectory[:, 3]) # ax[0].axis("equal") # ax[1].plot(inputs[:-1, 0], label="ax", marker='o') # ax[1].plot(inputs[:-1, 1], label="ay", marker='o', color="green") # ax[1].plot(inputs[:-1, 2], label="az", marker='o', color="red") # ax[1].legend() plt.show() print(repr(trajectory)) print(repr(inputs))
def test_single_track_optimizer(self): params = Parameter() params.set("wheel_base", 2.7) params.set("dt", 0.2) params.set("function_tolerance", 1e-8) params.set("max_num_iterations", 1000) initial_state = np.array([[0., 0., 0., 10.], [2., 0., 0., 10.], [4., 0., 0., 10.], [6., 0., 0., 10.]]) opt_vec = np.array([[ 0. , 0. ], [-0.00581466, -0.02969236], [-0.0100573 , -0.05063586], [-0.01290205, -0.06336555], [-0.0145111 , -0.06958468], [-0.01504364, -0.07147759], [-0.01466189, -0.0712203 ], [-0.01353391, -0.07066254], [-0.01183398, -0.0711591 ], [-0.00974178, -0.0735261 ], [-0.00744058, -0.07806701], [-0.00509113, -0.08413195], [-0.0028139 , -0.09089476], [-0.00069383, -0.0976187 ], [ 0.00121458, -0.10373539], [ 0.00288213, -0.10887319], [ 0.00430011, -0.11284776], [ 0.00547573, -0.11562908], [ 0.00642782, -0.11729807], [ 0.00718276, -0.11800159], [ 0.0077706 , -0.11791354], [ 0.00821974, -0.11720583], [ 0.00855625, -0.11603267], [ 0.0088038 , -0.11452536], [ 0.0089836 , -0.11278997], [ 0.00911419, -0.11090794], [ 0.00921137, -0.10893774], [ 0.00928801, -0.10691821], [ 0.00935393, -0.10487191], [ 0. , 0.00059502]]) ref_line = np.array([[ 0.00000000e+00, 0.00000000e+00, 0.00000000e+00, 1.00000000e+01], [ 2.00000000e+00, 0.00000000e+00, 0.00000000e+00, 1.00000000e+01], [ 4.00000000e+00, 0.00000000e+00, 0.00000000e+00, 1.00000000e+01], [ 6.00000000e+00, 0.00000000e+00, 0.00000000e+00, 1.00000000e+01], [ 8.00000000e+00, 0.00000000e+00, 0.00000000e+00, 1.00000000e+01], [ 9.99939997e+00, -4.30463875e-03, -4.30592393e-03, 9.99406153e+00], [ 1.19971306e+01, -2.03405218e-02, -1.17478308e-02, 9.98393436e+00], [ 1.39923704e+01, -5.32967584e-02, -2.12840277e-02, 9.97126125e+00], [ 1.59845144e+01, -1.06379431e-01, -3.19953707e-02, 9.95734431e+00], [ 1.79731414e+01, -1.81067097e-01, -4.30841450e-02, 9.94304879e+00], [ 1.99579824e+01, -2.77367780e-01, -5.38759931e-02, 9.92880473e+00], [ 2.19388867e+01, -3.94078028e-01, -6.38232626e-02, 9.91467222e+00], [ 2.39157899e+01, -5.29044532e-01, -7.25085470e-02, 9.90044040e+00], [ 2.58886800e+01, -6.79428615e-01, -7.96477572e-02, 9.88573518e+00], [ 2.78575651e+01, -8.41973335e-01, -8.50921200e-02, 9.87012178e+00], [ 2.98224543e+01, -1.01325561e+00, -8.88112060e-02, 9.85329539e+00], [ 3.17833555e+01, -1.18989285e+00, -9.08631109e-02, 9.83511644e+00], [ 3.37402750e+01, -1.36869381e+00, -9.13680809e-02, 9.81559270e+00], [ 3.56932177e+01, -1.54676003e+00, -9.04859136e-02, 9.79484562e+00], [ 3.76421873e+01, -1.72154515e+00, -8.83971179e-02, 9.77307098e+00], [ 3.95871864e+01, -1.89087947e+00, -8.52877092e-02, 9.75050143e+00], [ 4.15282170e+01, -2.05296693e+00, -8.13374631e-02, 9.72737561e+00], [ 4.34652803e+01, -2.20636175e+00, -7.67114427e-02, 9.70391600e+00], [ 4.53983772e+01, -2.34993117e+00, -7.15546057e-02, 9.68031568e+00], [ 4.73275086e+01, -2.48281085e+00, -6.59892879e-02, 9.65673297e+00], [ 4.92526750e+01, -2.60435938e+00, -6.01165980e-02, 9.63329181e+00], [ 5.11738771e+01, -2.71411662e+00, -5.40182610e-02, 9.61008527e+00], [ 5.30911154e+01, -2.81176608e+00, -4.77585100e-02, 9.58718020e+00], [ 5.50043903e+01, -2.89710162e+00, -4.13860399e-02, 9.56462221e+00], [ 5.69137022e+01, -2.96999832e+00, -3.49360318e-02, 9.54244062e+00], [ 5.88190514e+01, -3.03038789e+00, -2.84322483e-02, 9.52065307e+00], [ 6.07204383e+01, -3.07823825e+00, -2.18892006e-02, 9.49926943e+00], [ 6.26178630e+01, -3.11353783e+00, -1.53143860e-02, 9.47829505e+00], [ 6.45133116e+01, -3.14256773e+00, -1.53143860e-02, 9.47841405e+00]]) obstacle_outline0 = np.array([[14., 1.7], [22., 1.7], [22., 4.7], [14., 4.7], [14., 1.7]]) # optimizer opt = Optimizer(params) opt.SetOptimizationVector(opt_vec) # costs ref_cost = ReferenceCost(params, 100.) ref_cost.SetReference(ref_line) jerk_cost = JerkCost(params, 10000.) outline = ObjectOutline() obstacle_outline1 = obstacle_outline0 + np.array([[30.0, -3.]]) outline.Add(obstacle_outline0, 0.) outline.Add(obstacle_outline1, 6.) object_cost = StaticObjectCost(params, 2.5, 10000.) object_cost.AddObjectOutline(outline) input_cost = InputCost(params, 10.) input_cost.SetLowerBound(np.array([[-0.2, -1.0]])) input_cost.SetUpperBound(np.array([[0.2, 1.0]])) # optimization problem functor = opt.AddFastSingleTrackFunctor(initial_state, params, [jerk_cost, object_cost, input_cost, ref_cost]) opt.FixOptimizationVector(0, 1) opt.Solve() opt.Report() inputs = opt.Result() trajectory = GenerateTrajectorySingleTrack(initial_state, inputs, params) cmap, norm = GetColorMap(0., 6.) fig, ax = plt.subplots(nrows=1, ncols=2) for t in np.arange(0, 6, 0.5): poly = outline.Query(t) ax[0].plot(poly[:, 0], poly[:, 1], color=cmap(norm(t))) colorbar_axis = ax[0].plot(trajectory[:, 0], trajectory[:, 1]) for i, pt in enumerate(trajectory[:]): ax[0].plot(pt[0], pt[1], color=cmap(norm(params.set("dt", 0.2)*i)), marker='o') ax[0].axis("equal") ax[1].plot(inputs[:-1, 0], label="Steering angle", marker='o') ax[1].plot(inputs[:-1, 1], label="Acceleration", marker='o', color="green") ax[1].legend() plt.show() print(repr(inputs)) print(repr(trajectory))
def test_single_track_optimizer(self): params = Parameter() params.set("wheel_base", 2.7) params.set("dt", 0.2) params.set("function_tolerance", 1e-6) params.set("max_num_iterations", 1000) params.set("num_threads", 1) initial_state = np.array([[0., 0., 0., 10.], [2., 0., 0., 10.], [4., 0., 0., 10.], [6., 0., 0., 10.]]) opt_vec = np.zeros(shape=(30, 2)) ref_line = np.array([[0., 4.], [1000., 4.]]) obstacle_outline0 = np.array([[14., 1.7], [22., 1.7], [22., 4.7], [14., 4.7], [14., 1.7]]) # optimizer opt = Optimizer(params) opt.SetOptimizationVector(opt_vec) # costs ref_cost = ReferenceLineCost(params, 100.) ref_cost.SetReferenceLine(ref_line) jerk_cost = JerkCost(params, 10000.) outline = ObjectOutline() obstacle_outline1 = obstacle_outline0 + np.array([[30.0, -2.]]) outline.Add(obstacle_outline0, 0.) outline.Add(obstacle_outline1, 6.) object_cost = StaticObjectCost(params, 2.5, 10000.) object_cost.AddObjectOutline(outline) input_cost = InputCost(params, 10.) input_cost.SetLowerBound(np.array([[-0.2, -1.0]])) input_cost.SetUpperBound(np.array([[0.2, 1.0]])) speed_cost = SpeedCost(params, 10.) speed_cost.SetDesiredSpeed(10.) # optimization problem functor = opt.AddFastSingleTrackFunctor( initial_state, params, [jerk_cost, ref_cost, input_cost, object_cost, speed_cost]) opt.FixOptimizationVector(0, 1) opt.Solve() opt.Report() inputs = opt.Result() trajectory = GenerateTrajectorySingleTrack(initial_state, inputs, params) cmap, norm = GetColorMap(0., 6.) fig, ax = plt.subplots(nrows=1, ncols=2) for t in np.arange(0, 6, 0.5): poly = outline.Query(t) ax[0].plot(poly[:, 0], poly[:, 1], color=cmap(norm(t))) colorbar_axis = ax[0].plot(trajectory[:, 0], trajectory[:, 1]) for i, pt in enumerate(trajectory[:]): ax[0].plot(pt[0], pt[1], color=cmap(norm(params.set("dt", 0.2) * i)), marker='o') ax[0].axis("equal") ax[1].plot(inputs[:-1, 0], label="Steering angle", marker='o') ax[1].plot(inputs[:-1, 1], label="Acceleration", marker='o', color="green") ax[1].legend() plt.show() print(repr(trajectory)) print(repr(inputs))