lawarob-wheeled/Ex9_tank_l1.py

#!/usr/bin/env python

import numpy as np
from WheeledRobot import TankRobotEnv

# TankRobot kinematics
b = 1
r = 0.1

# Wheel equations
J = np.array([
    [+1/r, 0, -b/(2*r)],
    [-1/r, 0, -b/(2*r)]
])
F = np.linalg.pinv(J)

def controller_tank_l1(t, X_I, dX_I, target_position):
    """L1 adaptive control with path planning and dynamic target"""

    # Controller parameters
    dx_R_max = 3
    L0 = 4
    L1 = 4

    ...

    # Calculate control input
    U = J @ dX_R_des
    return U

def run_simulation():
    """Run simulation using Gymnasium environment with L1 adaptive control to dynamic target"""
    
    # Initialize environment with fixed target for reproducible results
    # You can set random_target=True for random target generation
    env = TankRobotEnv(render_mode="human", random_target=False)
    observation, _ = env.reset()
    
    # Expand render bounds to show target position (default target is at [10,5])
    env.set_render_bounds((-2, 12), (-2, 8))
    
    print("Starting Tank Robot L1 Adaptive Control Simulation")
    print("Controller: L1 adaptive control with path planning to dynamic target")
    print(f"Target position: [{observation[7]:.2f}, {observation[8]:.2f}, {observation[9]:.2f}]")
    
    for step in range(1000):
        # Extract controller inputs from observation
        # New observation format: [x, y, theta, dx, dy, dtheta, time, target_x, target_y, target_theta]
        time = observation[6]                    # Current time
        X_I = observation[:3].reshape(-1, 1)     # State [x, y, theta]
        dX_I = observation[3:6].reshape(-1, 1)   # Derivatives [dx, dy, dtheta]
        target_position = observation[7:10]      # Target [target_x, target_y, target_theta]
        
        # Call L1 adaptive controller with dynamic target
        U = controller_tank_l1(time, X_I, dX_I, target_position)
        
        # Step environment
        observation, reward, terminated, truncated, _ = env.step(U.flatten())
        
        # Render the environment
        env.render()
        
        # Check if target reached
        if terminated:
            print(f"Target reached at step {step}! Reward: {reward:.2f}")
            break
        elif truncated:
            print(f"Maximum steps reached at step {step}")
            break
    
    input("Press Enter to close the simulation window...")
    env.close()
    print("Simulation completed")

if __name__ == "__main__":
    run_simulation()