def cmc_config(): # run parameters nb_bootstrap = 10 nb_explorations = 50 nb_tests = 100 nb_timesteps = 1000 offline_eval = (1e6, 10) # (x,y): y evaluation episodes every x (done offline) # controller parameters hidden_sizes = [] controller_tmp = 1. activation = 'relu' subset_obs = range(2) norm_values = None scale = np.array([[-1.2,0.6],[-0.07,0.07]]) controller = NNController(hidden_sizes, controller_tmp, subset_obs, 1, norm_values, scale, activation) nb_weights = controller.nb_weights # representer representer = CMCRepresenter() initial_space = representer.initial_space goal_space = representer.initial_space # space in which goal are sampled nb_rep = representer.dim engineer_goal = np.array([0.5, 1.5, 5.]) # engineer goal # scale engineer goal to [-1,1]^N engineer_goal = scale_vec(engineer_goal, initial_space) # inverse model knn = KNNRegressor(n_neighbors=1) # exploration_noise noise = 0.1 return nb_bootstrap, nb_explorations, nb_tests, nb_timesteps, offline_eval, \ controller, representer, nb_rep, engineer_goal, goal_space, initial_space, knn, noise, nb_weights
def cheetah_config(): # run parameters nb_bootstrap = 200 nb_explorations = 1000 nb_tests = 100 nb_timesteps = 1000 offline_eval = (1e6, 10 ) # (x,y): y evaluation episodes every x (done offline) # controller parameters hidden_sizes = [] controller_tmp = 0.15 activation = 'relu' subset_obs = [2, 3, 4, 5, 6, 7, 11, 12, 13, 14, 15, 16] norm_values = np.array([[ -0.18, 0.064, 0.14, 0.17, 0.079, -0.082, -0.08, -0.084, 0.30, -0.011, 0.0078, 0.0065, -0.055, 0.014, -0.011, 0.073, 0.054 ], [ 0.073, 0.25, 0.22, 0.22, 0.25, 0.35, 0.27, 0.25, 0.64, 0.38, 1.1, 2.1, 2.9, 3.5, 3.9, 3.5, 3.4 ]]) # to zscore observations scale = None controller = NNController(hidden_sizes, controller_tmp, subset_obs, 6, norm_values, scale, activation) nb_weights = controller.nb_weights # representer representer = CheetahRepresenter() initial_space = representer.initial_space goal_space = np.array([[2., 6.], [-0.5, 0.]]) # space in which goal are sampled engineer_goal = np.array([6., -0.2]) # engineer goal # scale engineer goal to [-1,1]^N from gep_utils import scale_vec engineer_goal = scale_vec(engineer_goal, initial_space) nb_rep = representer.dim # inverse model knn = KNNRegressor(n_neighbors=1) # exploration_noise noise = 0.1 return nb_bootstrap, nb_explorations, nb_tests, nb_timesteps, offline_eval, \ controller, representer, nb_rep, engineer_goal, goal_space, initial_space, knn, noise, nb_weights
def kobuki_config(): # run parameters nb_bootstrap = 200 nb_explorations = 1000 nb_tests = 10 #nb_timesteps = random.randint(1,50) #print('Timesteps: ' + str(nb_timesteps)) nb_timesteps = 30 offline_eval = (1e6, 10) # controller parameters hidden_sizes = [] controller_tmp = 1. activation = 'relu' subset_obs = range(6) norm_values = None #scale = np.vstack([np.array([[-1.0,1.0],]*2)]) scale = np.array([[-1.0, 1.0], [-1.0, 1.0], [-1.0, 1.0], [-1.0, 1.0], [0.0, 1.0], [0.0, 1.0]]) controller = NNController(hidden_sizes, controller_tmp, subset_obs, 2, norm_values, scale, activation) nb_weights = controller.nb_weights # representer representer = KobukiRepresenter() initial_space = representer.initial_space goal_space = representer.initial_space nb_rep = representer.dim engineer_goal = np.random.uniform(-0.2, 0.2, (2, )) # scale engineer goal to[-1, 1]^N engineer_goal = scale_vec(engineer_goal, initial_space) # inverse model knn = KNNRegressor(n_neighbors=1) # exploration_noise noise = 0.1 return nb_bootstrap, nb_explorations, nb_tests, nb_timesteps, offline_eval, \ controller, representer, nb_rep, engineer_goal, goal_space, initial_space, knn, noise, nb_weights