got mpc controller running again

This commit is contained in:
Simon Pirkelmann 2021-08-25 22:53:09 +02:00
parent b65b6568d0
commit d0c17c0b91
3 changed files with 62 additions and 17 deletions

View File

@ -21,7 +21,8 @@ class ControllerBase:
if self.controlling:
self.apply_control(control)
self.apply_control((0.0, 0.0)) # stop robot
if self.robot is not None:
self.robot.send_cmd(u1=0, u2=0) # stop robot
def set_target_position(self, target_pos):
self.target_pos = target_pos

View File

@ -3,17 +3,32 @@ import socket
import threading
import time
from robot import Robot
from robot import Robot, ControlledRobot
from mpc_controller import MPCController
from aruco_estimator import ArucoEstimator
# HOST, PORT = "localhost", 42424
#
# robot_id = 12
#
# sock = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
# sock.connect((HOST, PORT))
# sock.sendall(f"{robot_id}\n".encode()) # request data for robot with given id
# #sock.sendall(f"events\n".encode()) # request events
# receiving = True
# while receiving:
# received = str(sock.recv(1024), "utf-8")
# print("Received: {}".format(received))
# receiving = len(received) > 0
class RemoteController:
def __init__(self):
self.robots = []
#self.robots = [Robot(11, '192.168.1.11'), Robot(13, '192.168.1.13'), Robot(14, '192.168.1.14')]
#self.robots = [Robot(11, '192.168.1.11')] #, Robot(13, '192.168.1.13'), Robot(14, '192.168.1.14')]
#self.robots = [Robot(12, '10.10.11.91'), Robot(13, '10.10.11.90'), Robot(14, '10.10.11.89')]
#self.robots = [Robot(14, '10.10.11.89')]
self.robots = [ControlledRobot(13, '192.168.1.13')]
self.robot_ids = {}
for r in self.robots:
@ -32,18 +47,17 @@ class RemoteController:
self.t = time.time()
# start thread for marker position detection
self.estimator = ArucoEstimator(self.robot_ids.keys())
self.estimator_thread = threading.Thread(target=self.estimator.run_tracking)
self.estimator_thread.start()
self.controller = MPCController(self.estimator)
self.controller = MPCController()
self.robots[0].attach_controller(self.controller)
def run(self):
print("waiting until all markers are detected...")
while not (self.estimator.all_corners_detected() and self.estimator.all_robots_detected()):
pass
#print("waiting until all markers are detected...")
#while not (self.estimator.all_corners_detected() and self.estimator.all_robots_detected()):
# pass
print("starting control")
self.controller.interactive_control(robots=self.robots)
#self.controller.interactive_control(robots=self.robots)
self.controller.start()
pass
def main(args):
@ -53,3 +67,13 @@ def main(args):
if __name__ == '__main__':
main(sys.argv)
# to use the program, first start measurement_server.py, which launches the Aruco marker detection GUI and streams
# marker positions and GUI events via socket
# next, launch this program (mpc_test.py) in debug mode and set a breakpoint after self.controller.start()
# you can now set the target position for the controlled robot via move_to_pos(), e.g.
# self.robots[0].move_to_pos([0.0,0,0], True)
# TODO
# figure out how to get clicked positions from measurement server and drive robot there
# also document and improve program structure

View File

@ -1,7 +1,9 @@
import socket
import threading
import json
import numpy as np
import time
import math
class Robot:
def __init__(self, marker_id, ip, measurement_server=('127.0.0.1', 42424)):
@ -123,8 +125,26 @@ class ControlledRobot(Robot):
self.controller = controller
self.controller.attach_robot(self)
def move_to_pos(self, target_pos):
def move_to_pos(self, target_pos, blocking=False):
if self.controller is not None:
self.controller.set_target_position(target_pos)
if not blocking:
self.controller.set_target_position(target_pos)
else: # only return after the robot has reached the target
self.stop_control()
self.controller.set_target_position(target_pos)
self.start_control()
close_to_target = False
while not close_to_target:
current_pos = np.array([self.x, self.y, self.angle])
v = target_pos - current_pos
angles_unwrapped = np.unwrap([current_pos[2], target_pos[2]]) # unwrap angle to avoid jump in data
e_angle = angles_unwrapped[0] - angles_unwrapped[1] # angle difference
e_pos = np.linalg.norm(v[0:2])
print(f"e_pos = {e_pos}, e_ang = {e_angle}")
close_to_target = e_pos < 0.05 and abs(e_angle) < 0.1
time.sleep(0.1)
print("target reached!")
self.stop_control()
else:
raise Exception("Error: Cannot move to position: there is not controller attached to the robot!")