integrate official rm ik, and qp based ik, with mujoco

This commit is contained in:
LiuzhengSJ
2026-06-02 22:24:43 +01:00
parent 99ba1786b0
commit 3febe65b6a

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@ -1,72 +1,194 @@
# conda activate coppeliasim
# env fix, in terminal: ~/fix_robotics_env.sh
from rm75_kine_qp import KinematicsSolver as controller from rm75_kine_qp import KinematicsSolver as kine_ctrl
from rm75_mjc import MuJoCoPositionController from rm75_mjc import MuJoCoPositionController
from Robotic_Arm.rm_robot_interface import *
import time import time
from pathlib import Path from math import radians, degrees, pi, cos, sin
import numpy as np
def demo_position_control(): def demo_position_control():
"""Demonstrate pure position control""" """Demonstrate pure position control"""
urdf_path = "/home/zl/Downloads/urdf_rm75/RM75-B.urdf" urdf_path = "/home/zl/Downloads/urdf_rm75/RM75-B.urdf"
if not Path(urdf_path).exists():
print(f"Error: URDF not found at {urdf_path}")
return
print("=" * 60)
print("Pure Position Control Demo")
print("=" * 60)
# Create controller # Create controller
robot = MuJoCoPositionController(urdf_path, smoothness=0.05, enable_viewer=True) robot_mjk = MuJoCoPositionController(urdf_path, smoothness=0.05, enable_viewer=True)
robot.start() robot_mjk.start()
time.sleep(1) time.sleep(1)
print("\n[Test 1] Move joint 1 to 45 degrees") print("\n[Test 1] Move joint 1 to 45 degrees")
robot.send_command([0.785, 0, 0, 0, 0, 0, 0]) robot_mjk.send_command([0.785, 0, 0, 0, 0, 0, 0])
robot.wait_until_reached() robot_mjk.wait_until_reached()
robot.print_state() robot_mjk.print_state()
time.sleep(0.5) time.sleep(0.5)
print("\n[Test 2] Move joint 2 to -30 degrees") print("\n[Test 2] Move joint 2 to -30 degrees")
robot.send_command([0, -0.524, 0, 0, 0, 0, 0]) robot_mjk.send_command([0, -0.524, 0, 0, 0, 0, 0])
robot.wait_until_reached() robot_mjk.wait_until_reached()
robot.print_state() robot_mjk.print_state()
time.sleep(0.5) time.sleep(0.5)
print("\n[Test 3] Move multiple joints simultaneously") print("\n[Test 3] Move multiple joints simultaneously")
robot.send_command([0.5, -0.4, 0.3, 0.2, 0.1, 0, 0]) robot_mjk.send_command([0.5, -0.4, 0.3, 0.2, 0.1, 0, 0])
robot.wait_until_reached() robot_mjk.wait_until_reached()
robot.print_state() robot_mjk.print_state()
time.sleep(0.5) time.sleep(0.5)
print("\n[Test 4] Return home") print("\n[Test 4] Return home")
robot.send_command([0, 0, 0, 0, 0, 0, 0]) robot_mjk.send_command([0, 0, 0, 0, 0, 0, 0])
robot.wait_until_reached() robot_mjk.wait_until_reached()
robot.print_state() robot_mjk.print_state()
robot_kine = kine_ctrl()
# Test 1: Forward Kinematics
print("\n1. Forward Kinematics Test")
print("-" * 40)
tool_name = "scissor"
joint_angles_zero = [0.1] * 7
fk_result = robot_kine.forward_kinematics(joint_angles_zero, tool=tool_name)
# Test 2: Inverse Kinematics with more reachable target
print("\n2. Inverse Kinematics Test")
print("-" * 40)
# Try a simpler target first
target_pos = [0.3, 0.2, 0.4] # More reachable position
target_rpy = [0.0, 0.0, radians(45)] # Simpler orientation
print(f"Target: ({target_pos[0]:.3f}, {target_pos[1]:.3f}, {target_pos[2]:.3f}) m")
init_joints = [0.2] * 7
time0 = time.time()
for ii in range(100):
joint_solution, success, error = robot_kine.inverse_kinematics(
target_pos, target_rpy=target_rpy, initial_guess=init_joints,
max_iter=500, debug=False, tool=tool_name
)
time1 = time.time()
print(f"Time: {time1 - time0}")
if success:
print(f"✓ Solution found! Error: {error:.6f} m")
for i, angle in enumerate(joint_solution):
print(f" Joint {i + 1}: {degrees(angle):7.2f}°")
# Verify
fk_verify = robot_kine.forward_kinematics(joint_solution,tool=tool_name)
print(
f" Position: ({fk_verify['position'][0]:.3f}, {fk_verify['position'][1]:.3f}, {fk_verify['position'][2]:.3f}) m")
else:
print("✗ IK failed to find a solution!")
# Test 3: Jacobian
print("\n3. Jacobian Matrix")
print("-" * 40)
J = robot_kine.compute_jacobian(joint_angles_zero, tool=tool_name)
print(f"Jacobian shape: {J.shape}")
for i in range(min(3, J.shape[0])):
row_str = " ".join([f"{J[i, j]:7.3f}" for j in range(7)])
print(f" Row {i + 1}: {row_str}")
# Test 4: Trajectory Planning with reachable positions
print("\n4. Cartesian Trajectory Planning")
print("-" * 40)
start_pos = [0.3, 0.0, 0.4] # Start position
end_pos = [0.3, 0.0, 0.55] # End position (smaller movement)
fk0 = robot_kine.forward_kinematics([0.1] * 7, tool=tool_name)
trajectory = robot_kine.plan_cartesian_trajectory(
start_pos,
end_pos,
start_rpy=fk0['rpy'],
end_rpy=[
fk0['rpy'][0] + radians(10),
fk0['rpy'][1],
fk0['rpy'][2]
],
num_steps=10,
tool=tool_name
)
if trajectory:
print(f"\n✓ Generated {len(trajectory)} waypoints")
if success:
print("✓ Inverse kinematics working (with simplified target)")
else:
print("⚠ Inverse kinematics may need tuning - try different targets")
print("\n" + "=" * 60) print("\n" + "=" * 60)
print("✓ All tests passed! Robot is stable and controllable.") print(f'test subchain Jacobian, for future obstacle avoidance')
print("=" * 60) frame_names = [
print("\nInteractive mode - close viewer to exit") "link_2",
"link_4",
"link_7"
]
Js_sub = robot_kine.get_subchain_jacobian(
joint_angles=joint_angles_zero,
frame_names=frame_names
)
print(f'Js_sub: {Js_sub}')
# ---------- rm75 official algorithm -----------
arm_model = rm_robot_arm_model_e.RM_MODEL_RM_75_E # RM_65 Robotic arm
force_type = rm_force_type_e.RM_MODEL_RM_B_E # Standard version
# Initialize the robotic arm model and sensor type in the algorithm
robot_kine_rm = Algo(arm_model, force_type)
frame = rm_frame_t("work", [0.0, 0.0, 0.0, 0.0, 0, 0.0])
robot_kine_rm.rm_algo_set_workframe(frame)
print(robot_kine_rm.rm_algo_get_curr_workframe())
frame = rm_frame_t("work", [0.0, 0.0, 0.0, 0.0, 0, 0.0])
robot_kine_rm.rm_algo_set_toolframe(frame)
print(robot_kine_rm.rm_algo_get_curr_toolframe())
joint_max_limit = np.array([
3.14159, 2.2689, 3.14159, 2.3562, 3.14159, 2.234, 3.14159
])*57
robot_kine_rm.rm_algo_set_joint_max_limit(joint_max_limit.tolist())
joint_min_limit = np.array([
-3.14159, -2.2689, -3.14159, -2.3562, -3.14159, -2.234, -3.14159
]) * 57
robot_kine_rm.rm_algo_set_joint_min_limit(joint_max_limit.tolist())
q_ref = [0.0, 110.0, 20.0, 40.0, 30.0, 180.0, 20.0]
ret, phi = robot_kine_rm.rm_algo_calculate_arm_angle_from_config_rm75(q_ref)
params = rm_inverse_kinematics_params_t([0.0, 110.0, 20.0, 40.0, 30.0, 180.0, 20.0],
[0.3, 0.0, 0.3, 3.14, 0.0, 3.14], 1)
ret, q_out = robot_kine_rm.rm_algo_inverse_kinematics_rm75_for_arm_angle(params, phi)
print(f"rm_algo_inverse_kinematics_rm75_for_arm_angle ret: {ret} q_out: {q_out}")
try: try:
while robot.viewer and robot.viewer.is_running(): while robot_mjk.viewer and robot_mjk.viewer.is_running():
time.sleep(0.1) time.sleep(0.1)
except KeyboardInterrupt: except KeyboardInterrupt:
pass pass
robot_mjk.stop()
robot.stop()
def main(): def main():
demo_position_control() demo_position_control()
# kine_node = controller()
# kine_node.loop_run()
# print("main get returned kine_node")
if __name__ == "__main__": if __name__ == "__main__":