feat: finised project

2025-04-07 14:53:38 +02:00 · 2025-04-07 14:53:38 +02:00 · 6b0f2c2170
commit 6b0f2c2170
parent 90d08671d9
2 changed files with 145 additions and 87 deletions
--- a/control.py
+++ b/control.py
@ -1,14 +1,15 @@
 import logging
-import math
+
 import numpy as np
 from math import *
 from logs import *
 from dynamixel_sdk import *
 from xbox import *
 import time
 # DEBUG
-LEGS_LOG_LEVEL = logging.INFO
+LEGS_LOG_LEVEL = logging.DEBUG
-CONTROLLER_LOG_LEVEL = logging.INFO
+CONTROLLER_LOG_LEVEL = logging.CRITICAL
 # Variables configurations
 l1h = 0.049
@ -40,17 +41,39 @@ controllerLogger = setup_logger("Controller", CONTROLLER_LOG_LEVEL)
 # Initialize controller
 xbox = Xbox(controllerLogger)
 CONTROLLER_MODE = xbox.initialized
-xbox.mode_count = 4
+xbox.mode_count = 5
 neutral_position = np.array([
-    [0.1, 0.15, -0.15],
+    [0.1, 0.16, -0.15],
-    [-0.1, 0.15, -0.15],
+    [-0.1, 0.16, -0.15],
    [-0.2, -0.00, -0.15],
-    [-0.1, -0.15, -0.15],
+    [-0.1, -0.16, -0.15],
-    [0.1, -0.15, -0.15],
+    [0.1, -0.16, -0.15],
    [0.2, 0, -0.15]
 ])
 REAL = 0
 # Robot setup
 if REAL == 1:
    portHandler = PortHandler("/dev/ttyUSB0")
    packetHandler = PacketHandler(1.0)
    portHandler.openPort()
    portHandler.setBaudRate(1000000)
    ADDR_GOAL_POSITION = 30
    ids = []
    for id in range(0, 100):
        model_number, result, error = packetHandler.ping(portHandler, id)
        if model_number == 12:
            print(f"Found AX-12 with id: {id}")
            ids.append(id)
        time.sleep(0.01)
 # Done
 def interpol2(point2, point1, t):
    x1, y1, z1 = point1
@ -88,14 +111,14 @@ def inverse(x, y, z):
    param2 = -1 * (-(l ** 2) + l2 ** 2 + l3 ** 2) / (2 * l2 * l3)
    if param2 > 1 or param2 < -1:
-        print("\033[94m" + f"Tentative d'acces a une position impossible (param2) ({x}, {y}, {z})" + "\033[0m")
+        legsLogger.warning("fTentative d'acces a une position impossible (param2) ({x}, {y}, {z})")
        param2 = 1 if param2 > 1 else -1
    theta2 = acos(param2)
    param1 = (-l3 ** 2 + l2 ** 2 + l ** 2) / (2 * l2 * l)
    if param1 > 1 or param1 < -1:
-        print("\033[94m" + f"Tentative d'acces a une position impossible (param1) ({x}, {y}, {z})" + "\033[0m")
+        legsLogger.warning(f"Tentative d'acces a une position impossible (param1) ({x}, {y}, {z})")
        param1 = 1 if param1 > 1 else -1
    theta1 = acos(param1) + asin(z / l)
@ -203,46 +226,10 @@ def naive_walk(t, speed_x, speed_y):
    return legs(real_position)
 def translate(tx, ty, tz):
    return np.array([
        [1.0, 0.0, 0.0, tx],
        [0.0, 1.0, 0.0, ty],
        [0.0, 0.0, 1.0, tz],
        [0.0, 0.0, 0.0, 1.0],
    ])
 def normalize(matrix, slider_max, speed):
    return (matrix / slider_max) * speed
 def Rx(alpha):
    return np.array([
        [1.0, 0.0, 0.0, 0.0],
        [0.0, np.cos(alpha), -np.sin(alpha), 0.0],
        [0.0, np.sin(alpha), np.cos(alpha), 0.0],
        [0.0, 0.0, 0.0, 1.0],
    ])
 def Ry(alpha):
    return np.array([
        [np.cos(alpha), 0.0, -np.sin(alpha), 0.0],
        [0.0, 1.0, 0.0, 0.0],
        [np.sin(alpha), 0.0, np.cos(alpha), 0.0],
        [0.0, 0.0, 0.0, 1.0],
    ])
 def Rz(alpha):
    return np.array([
        [np.cos(alpha), -np.sin(alpha), 0.0, 0.0],
        [np.sin(alpha), np.cos(alpha), 0.0, 0.0],
        [0.0, 0.0, 1.0, 0.0],
        [0.0, 0.0, 0.0, 1.0],
    ])
 def walk(t, sx, sy, sr):
    xboxdata = xbox.get_data()
    max_slider = 0.200
@ -255,10 +242,10 @@ def walk(t, sx, sy, sr):
        return dino_naive(t, max_slider * xboxdata["y1"], max_slider * xboxdata["x1"], max_slider * xboxdata["y2"],
                          max_slider * xboxdata["x2"], max_slider * (xboxdata["r2"] + 1))
    elif xbox.mode == 3:
        return dev(t, max_slider * xboxdata["y1"], max_slider * xboxdata["x1"], max_slider * xboxdata["y2"],
                   max_slider * xboxdata["x2"])
    else:
        return naive_walk(t, max_slider * xboxdata["x1"], max_slider * xboxdata["y1"])
    elif xbox.mode == 4:
        return dev(t, max_slider * xboxdata["y1"], max_slider * xboxdata["x1"], xboxdata["x2"] * max_slider,
                   max_slider * xboxdata["y2"])
 def static():
@ -266,16 +253,21 @@ def static():
 # Walk V2
-def dev(t, x1, y1, x2, y2):
+def dev(t, speed_x, speed_y, speed_r, y2):
    """
    x1: speed along the x-axis
    y1: speed along the y-axis
    x2: rotational speed along the z-axis
    """
    max_dist = 0.3
    def get_rotation_center(speed_x, speed_y, theta_point):
        direction = np.array([-speed_y, speed_x])
-        return direction / max(0.001, theta_point)
+        return direction / max(0.00001, theta_point)
-    x0, y0 = get_rotation_center(x1, y1, x2)
+    center_x, center_y = get_rotation_center(speed_x, speed_y, speed_r)
-    print(x0, y0)
+    legsLogger.debug(f"rotation center: center_x: {center_x}, center_y: {center_y}")
    num_patte = 6
    real_position = np.copy(neutral_position)
@ -285,7 +277,7 @@ def dev(t, x1, y1, x2, y2):
        [0, 0, -0.01]
    ])
-    step_duration = np.array([0.05, 0.3, 0.05])
+    step_duration = np.array([0.15, 0.3, 0.15])
    step_count = len(movement_z)
    movement_duration = np.sum(step_duration)
@ -296,15 +288,21 @@ def dev(t, x1, y1, x2, y2):
    def get_next_step(t):
        return floor((get_current_step(t, step_duration, movement_duration) + 1) % step_count)
-    offsets = np.array([0, 1 / 2, 2 / 3, 0, 1 / 2, 2 / 3]) * movement_duration  # offset between each leg
+    offsets = np.array([0, 1 / 3, 2 / 3, 0, 1 / 3, 2 / 3]) * movement_duration  # offset between each leg
    assert len(offsets) == num_patte, f"all offsets must be set, currently, {len(offsets)}/{num_patte} have them"
    max_radius = 0
    for patte in range(num_patte):
        x1, y1 = real_position[patte][0], real_position[patte][1]
        circle_radius = sqrt((center_x - x1) ** 2 + (center_y - y1) ** 2)
        max_radius = max(max_radius, circle_radius)
    for patte in range(num_patte):
        time = t + offsets[patte]
        mov_index_start = get_current_step(time, step_duration, movement_duration)
        mov_index_end = get_next_step(time)
-        step_adv = get_current_step_advancement(t, movement_duration, step_duration, mov_index_start)
+        step_adv = get_current_step_advancement(time, movement_duration, step_duration, mov_index_start)
        mov_start_z = movement_z[mov_index_start]
        mov_end_z = movement_z[mov_index_end]
@ -316,25 +314,37 @@ def dev(t, x1, y1, x2, y2):
         real_position[patte][1],
         real_position[patte][2]) = interpol2(mov_start, mov_end, step_adv)
        dthteta = x2 * 2
        theta = dthteta * (step_adv - 0.5)
        # theta = 0
        print(theta)
        # rotating the vector
        x1, y1 = real_position[patte][0], real_position[patte][1]
        print(f"x1: {x1}, y1: {y1}")
        x1t, y1t = x1 - x0, y1 - y0
        x2t, y2t = x1t * cos(theta) + y1t * sin(theta), x1t * sin(theta) + y1t * cos(theta)
        x2, y2 = x2t + x0, y2t + y0
        print(f"x2: {x2}, y2: {y2}")
        if mov_index_start == 1:
            # theta += time
            # xp = d * cos(theta) + real_position[patte][0]
            real_position[patte][0] = x2
            real_position[patte][1] = y2
-    return legs(real_position)
+        circle_radius = sqrt((center_x - x1) ** 2 + (center_y - y1) ** 2)
        cur_theta = acos((x1 - center_x) / circle_radius)
        if y1 < center_y:
            cur_theta *= -1
        speed = abs(speed_x) + abs(speed_y)
        if speed == 0:
            speed = speed_r
        dthteta = speed * (1 / max_radius * max_dist)
        legsLogger.info(f"speed: {speed}, dthteta: {dthteta}")
        if mov_index_start == 0:
            # midair part 1
            theta_offset = dthteta * (- step_adv)
        elif mov_index_start == 1:
            # moving part
            theta_offset = dthteta * (step_adv - 0.5) * 2
        else:
            # midair part 1
            theta_offset = dthteta * (1 - step_adv)
        wanted_theta = cur_theta + theta_offset
        wanted_x = center_x + circle_radius * cos(wanted_theta)
        wanted_y = center_y + circle_radius * sin(wanted_theta)
        real_position[patte][0] = wanted_x
        real_position[patte][1] = wanted_y
    return legs(real_position), [center_x, center_y]
 def jump(sy):
@ -424,5 +434,35 @@ def dino_naive(t, speed_x, speed_y, hz, hy, hx):
    return legs(real_position)
 def robot_input():
    print("Send motors wave (press enter)")
    input()
    for id in ids:
        packetHandler.write2ByteTxRx(portHandler, id, ADDR_GOAL_POSITION, 512)
    input()
    angle = [512, 624, 400, 512, 624, 400]
    for id in range(1, 7):
        packetHandler.write2ByteTxRx(portHandler, id * 10 + 1, ADDR_GOAL_POSITION, angle[id - 1])
    input()
    # Dino mode
    packetHandler.write2ByteTxRx(portHandler, 12, ADDR_GOAL_POSITION, 650)
    packetHandler.write2ByteTxRx(portHandler, 13, ADDR_GOAL_POSITION, 400)
    packetHandler.write2ByteTxRx(portHandler, 42, ADDR_GOAL_POSITION, 650)
    packetHandler.write2ByteTxRx(portHandler, 43, ADDR_GOAL_POSITION, 400)
    input()
    for id in ids:
        packetHandler.write2ByteTxRx(portHandler, id, ADDR_GOAL_POSITION, 512)
    # t = 0.0
    # while True:
    #     print("Send motors wave (press enter)")
    #     angle = 512 + int(50 * np.sin(t))
    #     print(angle)
    #     packetHandler.write2ByteTxRx(portHandler, 53, ADDR_GOAL_POSITION, angle)
    #     time.sleep(0.001)
    #     t += 0.01
 if __name__ == "__main__":
    print("N'exécutez pas ce fichier, mais simulator.py")
--- a/simulator.py
+++ b/simulator.py
@ -3,6 +3,7 @@ import argparse
 import math
 import time
 import pybullet as p
 if __package__ is None or __package__ == '':
    import control
 else:
@ -14,6 +15,7 @@ dirname = os.path.dirname(__file__) + '/models/'
 n_motors = 0
 jointsMap = []
 def init():
    """Initialise le simulateur"""
    # Instanciation de Bullet
@ -21,7 +23,7 @@ def init():
    p.setGravity(0, 0, -10)
    # Chargement du sol
-    planeId = p.loadURDF(dirname+'/plane.urdf')
+    planeId = p.loadURDF(dirname + '/plane.urdf')
    p.setPhysicsEngineParameter(fixedTimeStep=dt)
@ -29,7 +31,7 @@ def init():
 def loadModel(name, fixed=False, startPos=[0., 0., 0.1], startOrientation=[0., 0., 0.]):
    """Charge un modèle"""
    startOrientation = p.getQuaternionFromEuler(startOrientation)
-    model = p.loadURDF(dirname+"/"+name+"/robot.urdf",
+    model = p.loadURDF(dirname + "/" + name + "/robot.urdf",
                       startPos, startOrientation, useFixedBase=fixed)
    return model
@ -60,6 +62,7 @@ def inverseControls(name='', x_default=0.15, y_default=0.):
    return target_x, target_y, target_z, target
 def directControls():
    alpha = p.addUserDebugParameter('alpha', -math.pi, math.pi, 0)
    beta = p.addUserDebugParameter('beta', -math.pi, math.pi, 0)
@ -78,6 +81,7 @@ def inverseUpdate(controls):
    return x, y, z
 def tick():
    global t
@ -85,6 +89,7 @@ def tick():
    p.stepSimulation()
    time.sleep(dt)
 if __name__ == "__main__":
    # Arguments
    parser = argparse.ArgumentParser(prog="Quadruped")
@ -104,11 +109,11 @@ if __name__ == "__main__":
    if robot == 'quadruped':
        oneLegStartPos = [-0.04, 0., floatHeight]
-        oneLegstartOrientation = [0., 0., math.pi + math.pi/4]
+        oneLegstartOrientation = [0., 0., math.pi + math.pi / 4]
        n_motors = 12
        jointsMap = [0, 1, 2, 4, 5, 6, 8, 9, 10, 12, 13, 14]
    else:
-        oneLegstartOrientation = [0., 0., -math.pi/2]
+        oneLegstartOrientation = [0., 0., -math.pi / 2]
        oneLegStartPos = [-0.079, 0.032, floatHeight]
        n_motors = 18
        jointsMap = list(range(18))
@ -161,6 +166,8 @@ if __name__ == "__main__":
    robot = loadModel(robot, fixed, startPos, startOrientation)
    target = loadModel('target2', True)
    # Boucle principale
    while True:
        if mode == 'motors':
@ -168,23 +175,25 @@ if __name__ == "__main__":
            for entry in motors_sliders:
                joints.append(p.readUserDebugParameter(entry))
        elif mode == 'inverse':
-            joints = control.inverse(*inverseUpdate(leg)) + [0]*(n_motors-3)
+            joints = control.inverse(*inverseUpdate(leg)) + [0] * (n_motors - 3)
        elif mode == 'direct':
            alpha_slider, beta_slider, gamma_slider, target = leg
            alpha = p.readUserDebugParameter(alpha_slider)
            beta = p.readUserDebugParameter(beta_slider)
            gamma = p.readUserDebugParameter(gamma_slider)
-            joints = [alpha, beta, gamma] + [0]*(n_motors-3)
+            joints = [alpha, beta, gamma] + [0] * (n_motors - 3)
            x, y, z = control.direct(alpha, beta, gamma)
            p.resetBasePositionAndOrientation(target, [x, y, z + floatHeight],
-                p.getQuaternionFromEuler([0, 0, 0]))
+                                              p.getQuaternionFromEuler([0, 0, 0]))
        elif mode == 'draw':
-            joints = control.draw(t) + [0]*(n_motors-3)
+            joints = control.draw(t) + [0] * (n_motors - 3)
            def getLegTip():
                res = p.getLinkState(robot, 3)
                return res[0]
            if lastLine is None:
                lastLine = time.time(), getLegTip()
            elif time.time() - lastLine[0] > 0.1:
@ -201,7 +210,16 @@ if __name__ == "__main__":
            x = p.readUserDebugParameter(speed_x)
            y = p.readUserDebugParameter(speed_y)
            rotation = p.readUserDebugParameter(speed_rotation)
-            joints = control.walk(t, x, y, rotation)
+            data = control.walk(t, x, y, rotation)
            if len(data) == 2:  # When we receive the position of a target
                joints = data[0]
                x, y = data[1]
                z = 0
            else:
                joints = data
                x, y, z = 0, 0, -5  # We hide the target under the map
            p.resetBasePositionAndOrientation(target, [x, y, z],
                                              p.getQuaternionFromEuler([0, 0, 0]))
        elif mode == 'sandbox':
            joints = control.sandbox(t)