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rans-env / server /tasks /go_to_pose.py

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	# Copyright (c) Space Robotics Lab, SnT, University of Luxembourg, SpaceR
	# RANS: arXiv:2310.07393

	"""
	GoToPose Task
	=============
	The spacecraft must reach a target position AND heading (x_t, y_t, θ_t).

	Observation (7 values):
	[Δx_body, Δy_body, cos(Δθ), sin(Δθ), vx, vy, ω]

	Reward:
	r = w_p · exp(-‖p_error‖² / (2·σ_p²))
	+ w_h · exp(-\|heading_error\|² / (2·σ_h²))

	Episode terminates when ‖p_error‖ < tol_p AND \|heading_error\| < tol_h.
	"""

	from __future__ import annotations

	import math
	from typing import Any, Dict, Tuple

	import numpy as np

	from .base import BaseTask


	class GoToPoseTask(BaseTask):
	"""Navigate spacecraft to a target 2-D pose (position + heading)."""

	_DEFAULTS: Dict[str, Any] = {
	"tolerance_pos": 0.10, # position success threshold (m)
	"tolerance_heading": 0.10, # heading success threshold (rad)
	"reward_sigma_pos": 1.00, # position reward width
	"reward_sigma_heading": 0.50, # heading reward width
	"position_weight": 0.70, # w_p
	"heading_weight": 0.30, # w_h
	"spawn_min_radius": 0.50,
	"spawn_max_radius": 3.00,
	}

	def __init__(self, config: Dict[str, Any] \| None = None) -> None:
	super().__init__(config)
	cfg = {self._DEFAULTS, (config or {})}
	self.tolerance_pos: float = cfg["tolerance_pos"]
	self.tolerance_heading: float = cfg["tolerance_heading"]
	self.reward_sigma_pos: float = cfg["reward_sigma_pos"]
	self.reward_sigma_heading: float = cfg["reward_sigma_heading"]
	self.position_weight: float = cfg["position_weight"]
	self.heading_weight: float = cfg["heading_weight"]
	self.spawn_min_radius: float = cfg["spawn_min_radius"]
	self.spawn_max_radius: float = cfg["spawn_max_radius"]

	self._target_pos = np.zeros(2, dtype=np.float64)
	self._target_heading: float = 0.0

	# ------------------------------------------------------------------
	# BaseTask interface
	# ------------------------------------------------------------------

	def reset(self, spacecraft_state: np.ndarray) -> Dict[str, Any]:
	r = np.random.uniform(self.spawn_min_radius, self.spawn_max_radius)
	angle = np.random.uniform(0.0, 2.0 * math.pi)
	self._target_pos = np.array([r * math.cos(angle), r * math.sin(angle)])
	self._target_heading = np.random.uniform(-math.pi, math.pi)
	return {
	"target_position": self._target_pos.tolist(),
	"target_heading_rad": self._target_heading,
	}

	def get_observation(self, spacecraft_state: np.ndarray) -> np.ndarray:
	x, y, theta, vx, vy, omega = spacecraft_state
	dx, dy = self._target_pos[0] - x, self._target_pos[1] - y
	dx_b, dy_b = self._world_to_body(dx, dy, theta)
	d_theta = self._wrap_angle(self._target_heading - theta)
	return np.array(
	[dx_b, dy_b, math.cos(d_theta), math.sin(d_theta), vx, vy, omega],
	dtype=np.float32,
	)

	def compute_reward(
	self, spacecraft_state: np.ndarray
	) -> Tuple[float, bool, Dict[str, Any]]:
	x, y, theta = spacecraft_state[0], spacecraft_state[1], spacecraft_state[2]
	pos_error = float(np.linalg.norm(self._target_pos - np.array([x, y])))
	heading_error = abs(self._wrap_angle(self._target_heading - theta))

	r_pos = self._reward_exponential(pos_error, self.reward_sigma_pos)
	r_head = self._reward_exponential(heading_error, self.reward_sigma_heading)
	reward = self.position_weight * r_pos + self.heading_weight * r_head

	goal_reached = (
	pos_error < self.tolerance_pos and heading_error < self.tolerance_heading
	)
	info = {
	"position_error_m": pos_error,
	"heading_error_rad": heading_error,
	"goal_reached": goal_reached,
	}
	return reward, goal_reached, info

	@property
	def num_observations(self) -> int:
	return 7