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__credits__ = ["Carlos Luis"] | |
from os import path | |
from typing import Optional | |
import numpy as np | |
import gym | |
from gym import spaces | |
from gym.envs.classic_control import utils | |
from gym.error import DependencyNotInstalled | |
DEFAULT_X = np.pi | |
DEFAULT_Y = 1.0 | |
class PendulumEnv(gym.Env): | |
""" | |
### Description | |
The inverted pendulum swingup problem is based on the classic problem in control theory. | |
The system consists of a pendulum attached at one end to a fixed point, and the other end being free. | |
The pendulum starts in a random position and the goal is to apply torque on the free end to swing it | |
into an upright position, with its center of gravity right above the fixed point. | |
The diagram below specifies the coordinate system used for the implementation of the pendulum's | |
dynamic equations. | |
![Pendulum Coordinate System](./diagrams/pendulum.png) | |
- `x-y`: cartesian coordinates of the pendulum's end in meters. | |
- `theta` : angle in radians. | |
- `tau`: torque in `N m`. Defined as positive _counter-clockwise_. | |
### Action Space | |
The action is a `ndarray` with shape `(1,)` representing the torque applied to free end of the pendulum. | |
| Num | Action | Min | Max | | |
|-----|--------|------|-----| | |
| 0 | Torque | -2.0 | 2.0 | | |
### Observation Space | |
The observation is a `ndarray` with shape `(3,)` representing the x-y coordinates of the pendulum's free | |
end and its angular velocity. | |
| Num | Observation | Min | Max | | |
|-----|------------------|------|-----| | |
| 0 | x = cos(theta) | -1.0 | 1.0 | | |
| 1 | y = sin(theta) | -1.0 | 1.0 | | |
| 2 | Angular Velocity | -8.0 | 8.0 | | |
### Rewards | |
The reward function is defined as: | |
*r = -(theta<sup>2</sup> + 0.1 * theta_dt<sup>2</sup> + 0.001 * torque<sup>2</sup>)* | |
where `$\theta$` is the pendulum's angle normalized between *[-pi, pi]* (with 0 being in the upright position). | |
Based on the above equation, the minimum reward that can be obtained is | |
*-(pi<sup>2</sup> + 0.1 * 8<sup>2</sup> + 0.001 * 2<sup>2</sup>) = -16.2736044*, | |
while the maximum reward is zero (pendulum is upright with zero velocity and no torque applied). | |
### Starting State | |
The starting state is a random angle in *[-pi, pi]* and a random angular velocity in *[-1,1]*. | |
### Episode Truncation | |
The episode truncates at 200 time steps. | |
### Arguments | |
- `g`: acceleration of gravity measured in *(m s<sup>-2</sup>)* used to calculate the pendulum dynamics. | |
The default value is g = 10.0 . | |
``` | |
gym.make('Pendulum-v1', g=9.81) | |
``` | |
### Version History | |
* v1: Simplify the math equations, no difference in behavior. | |
* v0: Initial versions release (1.0.0) | |
""" | |
metadata = { | |
"render_modes": ["human", "rgb_array"], | |
"render_fps": 30, | |
} | |
def __init__(self, render_mode: Optional[str] = None, g=10.0): | |
self.max_speed = 8 | |
self.max_torque = 2.0 | |
self.dt = 0.05 | |
self.g = g | |
self.m = 1.0 | |
self.l = 1.0 | |
self.render_mode = render_mode | |
self.screen_dim = 500 | |
self.screen = None | |
self.clock = None | |
self.isopen = True | |
high = np.array([1.0, 1.0, self.max_speed], dtype=np.float32) | |
# This will throw a warning in tests/envs/test_envs in utils/env_checker.py as the space is not symmetric | |
# or normalised as max_torque == 2 by default. Ignoring the issue here as the default settings are too old | |
# to update to follow the openai gym api | |
self.action_space = spaces.Box( | |
low=-self.max_torque, high=self.max_torque, shape=(1,), dtype=np.float32 | |
) | |
self.observation_space = spaces.Box(low=-high, high=high, dtype=np.float32) | |
def step(self, u): | |
th, thdot = self.state # th := theta | |
g = self.g | |
m = self.m | |
l = self.l | |
dt = self.dt | |
u = np.clip(u, -self.max_torque, self.max_torque)[0] | |
self.last_u = u # for rendering | |
costs = angle_normalize(th) ** 2 + 0.1 * thdot**2 + 0.001 * (u**2) | |
newthdot = thdot + (3 * g / (2 * l) * np.sin(th) + 3.0 / (m * l**2) * u) * dt | |
newthdot = np.clip(newthdot, -self.max_speed, self.max_speed) | |
newth = th + newthdot * dt | |
self.state = np.array([newth, newthdot]) | |
if self.render_mode == "human": | |
self.render() | |
return self._get_obs(), -costs, False, False, {} | |
def reset(self, *, seed: Optional[int] = None, options: Optional[dict] = None): | |
super().reset(seed=seed) | |
if options is None: | |
high = np.array([DEFAULT_X, DEFAULT_Y]) | |
else: | |
# Note that if you use custom reset bounds, it may lead to out-of-bound | |
# state/observations. | |
x = options.get("x_init") if "x_init" in options else DEFAULT_X | |
y = options.get("y_init") if "y_init" in options else DEFAULT_Y | |
x = utils.verify_number_and_cast(x) | |
y = utils.verify_number_and_cast(y) | |
high = np.array([x, y]) | |
low = -high # We enforce symmetric limits. | |
self.state = self.np_random.uniform(low=low, high=high) | |
self.last_u = None | |
if self.render_mode == "human": | |
self.render() | |
return self._get_obs(), {} | |
def _get_obs(self): | |
theta, thetadot = self.state | |
return np.array([np.cos(theta), np.sin(theta), thetadot], dtype=np.float32) | |
def render(self): | |
if self.render_mode is None: | |
gym.logger.warn( | |
"You are calling render method without specifying any render mode. " | |
"You can specify the render_mode at initialization, " | |
f'e.g. gym("{self.spec.id}", render_mode="rgb_array")' | |
) | |
return | |
try: | |
import pygame | |
from pygame import gfxdraw | |
except ImportError: | |
raise DependencyNotInstalled( | |
"pygame is not installed, run `pip install gym[classic_control]`" | |
) | |
if self.screen is None: | |
pygame.init() | |
if self.render_mode == "human": | |
pygame.display.init() | |
self.screen = pygame.display.set_mode( | |
(self.screen_dim, self.screen_dim) | |
) | |
else: # mode in "rgb_array" | |
self.screen = pygame.Surface((self.screen_dim, self.screen_dim)) | |
if self.clock is None: | |
self.clock = pygame.time.Clock() | |
self.surf = pygame.Surface((self.screen_dim, self.screen_dim)) | |
self.surf.fill((255, 255, 255)) | |
bound = 2.2 | |
scale = self.screen_dim / (bound * 2) | |
offset = self.screen_dim // 2 | |
rod_length = 1 * scale | |
rod_width = 0.2 * scale | |
l, r, t, b = 0, rod_length, rod_width / 2, -rod_width / 2 | |
coords = [(l, b), (l, t), (r, t), (r, b)] | |
transformed_coords = [] | |
for c in coords: | |
c = pygame.math.Vector2(c).rotate_rad(self.state[0] + np.pi / 2) | |
c = (c[0] + offset, c[1] + offset) | |
transformed_coords.append(c) | |
gfxdraw.aapolygon(self.surf, transformed_coords, (204, 77, 77)) | |
gfxdraw.filled_polygon(self.surf, transformed_coords, (204, 77, 77)) | |
gfxdraw.aacircle(self.surf, offset, offset, int(rod_width / 2), (204, 77, 77)) | |
gfxdraw.filled_circle( | |
self.surf, offset, offset, int(rod_width / 2), (204, 77, 77) | |
) | |
rod_end = (rod_length, 0) | |
rod_end = pygame.math.Vector2(rod_end).rotate_rad(self.state[0] + np.pi / 2) | |
rod_end = (int(rod_end[0] + offset), int(rod_end[1] + offset)) | |
gfxdraw.aacircle( | |
self.surf, rod_end[0], rod_end[1], int(rod_width / 2), (204, 77, 77) | |
) | |
gfxdraw.filled_circle( | |
self.surf, rod_end[0], rod_end[1], int(rod_width / 2), (204, 77, 77) | |
) | |
fname = path.join(path.dirname(__file__), "assets/clockwise.png") | |
img = pygame.image.load(fname) | |
if self.last_u is not None: | |
scale_img = pygame.transform.smoothscale( | |
img, | |
(scale * np.abs(self.last_u) / 2, scale * np.abs(self.last_u) / 2), | |
) | |
is_flip = bool(self.last_u > 0) | |
scale_img = pygame.transform.flip(scale_img, is_flip, True) | |
self.surf.blit( | |
scale_img, | |
( | |
offset - scale_img.get_rect().centerx, | |
offset - scale_img.get_rect().centery, | |
), | |
) | |
# drawing axle | |
gfxdraw.aacircle(self.surf, offset, offset, int(0.05 * scale), (0, 0, 0)) | |
gfxdraw.filled_circle(self.surf, offset, offset, int(0.05 * scale), (0, 0, 0)) | |
self.surf = pygame.transform.flip(self.surf, False, True) | |
self.screen.blit(self.surf, (0, 0)) | |
if self.render_mode == "human": | |
pygame.event.pump() | |
self.clock.tick(self.metadata["render_fps"]) | |
pygame.display.flip() | |
else: # mode == "rgb_array": | |
return np.transpose( | |
np.array(pygame.surfarray.pixels3d(self.screen)), axes=(1, 0, 2) | |
) | |
def close(self): | |
if self.screen is not None: | |
import pygame | |
pygame.display.quit() | |
pygame.quit() | |
self.isopen = False | |
def angle_normalize(x): | |
return ((x + np.pi) % (2 * np.pi)) - np.pi | |