def create_params(): p = create_socnav_params() p.obstacle_map_params = DotMap(obstacle_map=SBPDMap, map_origin_2=[0., 0.], sampling_thres=2, plotting_grid_steps=100) return create_test_map_params(p)
def create_params(): p = create_socnav_params() # The camera is assumed to be mounted on a robot at fixed height # and fixed pitch. See params/central_params.py for more information p.camera_params.width = 1024 p.camera_params.height = 1024 p.camera_params.fov_vertical = 75.0 p.camera_params.fov_horizontal = 75.0 # Introduce the robot params from params.central_params import create_robot_params p.robot_params = create_robot_params() # Introduce the episode params from params.central_params import create_episodes_params p.episode_params = create_episodes_params() # Tilt the camera 10 degree down from the horizontal axis p.robot_params.physical_params.camera_elevation_degree = -10 if p.render_3D: # Can only render rgb and depth if the host has an available display p.camera_params.modalities = ['rgb', 'disparity'] else: p.camera_params.modalities = ['occupancy_grid'] return p
def create_params(): p = create_socnav_params() # Angle Distance parameters p.goal_angle_objective = DotMap(power=1, angle_cost=25.0) p.obstacle_map_params = DotMap(obstacle_map=SBPDMap, map_origin_2=[0., 0.], sampling_thres=2, plotting_grid_steps=100) return create_test_map_params(p)
def create_params(): p = create_socnav_params() # Obstacle avoidance parameters p.avoid_obstacle_objective = DotMap(obstacle_margin0=0.3, obstacle_margin1=0.5, power=2, obstacle_cost=25.0) p.obstacle_map_params = DotMap(obstacle_map=SBPDMap, map_origin_2=[0., 0.], sampling_thres=2, plotting_grid_steps=100) return create_test_map_params(p)
def create_params(): p = create_socnav_params() # The camera is assumed to be mounted on a robot at fixed height # and fixed pitch. See params/central_params.py for more information p.camera_params.width = 1024 p.camera_params.height = 1024 p.camera_params.fov_vertical = 75.0 p.camera_params.fov_horizontal = 75.0 # Introduce the robot params from params.central_params import create_robot_params p.robot_params = create_robot_params() # Introduce the episode params from params.central_params import create_episodes_params, create_datasets_params p.episode_params = create_episodes_params() # not testing robot, only simulator + agents p.episode_params.without_robot = False # overwrite tests with custom basic test p.episode_params.tests = {} default_name = "test_socnav_univ" p.episode_params.tests[default_name] = \ DotMap(name=default_name, map_name='Univ', pedestrian_datasets=create_datasets_params(["univ"]), datasets_start_t=[0.], ped_ranges=[(0, 100)], # agents_start=[[8, 8, 0]], agents_end=[[17.5, 13, 0.]], agents_start=[], agents_end=[], robot_start_goal=[[10, 3, 0], [15.5, 8, 0.7]], max_time=30, write_episode_log=True ) # Tilt the camera 10 degree down from the horizontal axis p.robot_params.physical_params.camera_elevation_degree = -10 if p.render_3D: # Can only render rgb and depth if the host has an available display p.camera_params.modalities = ['rgb', 'disparity'] else: p.camera_params.modalities = ['occupancy_grid'] return p
def create_params(): p = create_socnav_params() # Obstacle avoidance parameters p.avoid_obstacle_objective = DotMap(obstacle_margin0=0.3, obstacle_margin1=.5, power=2, obstacle_cost=25.0) # Angle Distance parameters p.goal_angle_objective = DotMap(power=1, angle_cost=25.0) # Goal Distance parameters p.goal_distance_objective = DotMap(power=2, goal_cost=25.0, goal_margin=0.0) p.objective_fn_params = DotMap(obj_type='mean') p.obstacle_map_params = DotMap(obstacle_map=SBPDMap, map_origin_2=[0, 0], sampling_thres=2, plotting_grid_steps=100) return create_test_map_params(p)
def create_params(): p = create_socnav_params() # Angle Distance parameters p.goal_angle_objective = DotMap(power=1, angle_cost=25.0) p.obstacle_map_params = DotMap(obstacle_map=SBPDMap, map_origin_2=[0., 0.], sampling_thres=2, plotting_grid_steps=100) # Obstacle avoidance parameters p.avoid_obstacle_objective = DotMap(obstacle_margin0=0.3, obstacle_margin1=.5, power=2, obstacle_cost=25.0) # Angle Distance parameters p.goal_angle_objective = DotMap(power=1, angle_cost=25.0) # Goal Distance parameters p.goal_distance_objective = DotMap(power=2, goal_cost=25.0, goal_margin=0.0) p.objective_fn_params = DotMap(obj_type='mean') p.obstacle_map_params = DotMap(obstacle_map=SBPDMap, map_origin_2=[0, 0], sampling_thres=2, plotting_grid_steps=100) p.personal_space_params = DotMap(power=1, psc_scale=10) # Introduce the robot params from params.central_params import create_robot_params p.robot_params = create_robot_params() # Introduce the episode params from params.central_params import create_episodes_params, create_datasets_params p.episode_params = create_episodes_params() # not testing robot, only simulator + agents p.episode_params.without_robot = True # overwrite tests with custom basic test p.episode_params.tests = {} default_name = "test_psc" p.episode_params.tests[default_name] = \ DotMap(name=default_name, map_name='Univ', pedestrian_datasets=create_datasets_params([]), datasets_start_t=[], ped_ranges=[], agents_start=[], agents_end=[], robot_start_goal=[[10, 3, 0], [15.5, 8, 0.7]], max_time=30, write_episode_log=False ) # definitely wont be rendering this p.render_3D = False # Tilt the camera 10 degree down from the horizontal axis p.robot_params.physical_params.camera_elevation_degree = -10 if p.render_3D: # Can only render rgb and depth if the host has an available display p.camera_params.modalities = ['rgb', 'disparity'] else: p.camera_params.modalities = ['occupancy_grid'] return create_test_map_params(p)