master
Zhengyu Peng 3 years ago
parent 43dad0fcfa
commit e5cecbe838

@ -62,7 +62,7 @@ class Hexapod:
self.leg_0 = Leg(0, self.leg_0 = Leg(0,
[self.pca_left.servo[15], self.pca_left.servo[2], [self.pca_left.servo[15], self.pca_left.servo[2],
self.pca_left.servo[1]], self.pca_left.servo[1]],
correction=[-6, 4, -6]) correction=[-6, 4, -4])
# center right # center right
self.leg_1 = Leg(1, self.leg_1 = Leg(1,
[self.pca_left.servo[7], self.pca_left.servo[8], [self.pca_left.servo[7], self.pca_left.servo[8],
@ -117,30 +117,30 @@ class Hexapod:
for mm in range(0, 20): for mm in range(0, 20):
self.move(self.backward_path, 0.005) self.move(self.backward_path, 0.005)
# for mm in range(0, 20): for mm in range(0, 20):
# self.move(self.fastforward_path, 0.005) self.move(self.fastforward_path, 0.005)
# for mm in range(0, 20): for mm in range(0, 20):
# self.move(self.fastbackward_path, 0.005) self.move(self.fastbackward_path, 0.005)
# for mm in range(0, 20): for mm in range(0, 20):
# self.move(self.leftturn_path, 0.005) self.move(self.leftturn_path, 0.005)
# for mm in range(0, 20): for mm in range(0, 20):
# self.move(self.rightturn_path, 0.005) self.move(self.rightturn_path, 0.005)
# for mm in range(0, 20): for mm in range(0, 20):
# self.move(self.shiftleft_path, 0.005) self.move(self.shiftleft_path, 0.005)
# for mm in range(0, 20): for mm in range(0, 20):
# self.move(self.shiftright_path, 0.005) self.move(self.shiftright_path, 0.005)
# for mm in range(0, 20): for mm in range(0, 20):
# self.move(self.climb_path, 0.005) self.move(self.climb_path, 0.005)
# self.move(self.rotatex_path, 0.005) # self.move(self.rotatex_path, 0.005)
for mm in range(0, 20): # for mm in range(0, 20):
self.move(self.twist_path, 0.005) # self.move(self.rotatez_path, 0.005)
time.sleep(1) time.sleep(1)
self.standby() self.standby()
@ -161,7 +161,6 @@ class Hexapod:
def move(self, path, interval): def move(self, path, interval):
for p_idx in range(0, np.shape(path)[0]): for p_idx in range(0, np.shape(path)[0]):
# dest = path[p_idx, :, :]+self.standby_coordinate
dest = path[p_idx, :, :] dest = path[p_idx, :, :]
angles = self.inverse_kinematics(dest) angles = self.inverse_kinematics(dest)

@ -106,4 +106,4 @@ def path_rotate_z(path, angle):
if __name__ == '__main__': if __name__ == '__main__':
pt = [0, 1, 0] pt = [0, 1, 0]
print(point_rotate_z(pt, 270))

@ -110,102 +110,89 @@ def gen_leftturn_path(standby_coordinate,
return path+np.tile(standby_coordinate, (g_steps, 1, 1)) return path+np.tile(standby_coordinate, (g_steps, 1, 1))
def gen_rightturn_path(standby_coordinate): def gen_rightturn_path(standby_coordinate,
g_steps = 20 g_steps = 20,
g_radius = 25 g_radius = 25):
assert (g_steps % 4) == 0 assert (g_steps % 4) == 0
halfsteps = int(g_steps/2) halfsteps = int(g_steps/2)
path = semicircle_generator(g_radius, g_steps) semi_circle = semicircle_generator(g_radius, g_steps)
mir_path = np.roll(path, halfsteps, axis=0) mir_path = np.roll(semi_circle, halfsteps, axis=0)
rightturn = np.zeros((g_steps, 6, 3)) path = np.zeros((g_steps, 6, 3))
rightturn[:, 0, :] = path_rotate_z(path, 45+180) path[:, 0, :] = path_rotate_z(semi_circle, 45+180)
rightturn[:, 1, :] = path_rotate_z(mir_path, 0+180) path[:, 1, :] = path_rotate_z(mir_path, 0+180)
rightturn[:, 2, :] = path_rotate_z(path, 315+180) path[:, 2, :] = path_rotate_z(semi_circle, 315+180)
rightturn[:, 3, :] = path_rotate_z(mir_path, 225+180) path[:, 3, :] = path_rotate_z(mir_path, 225+180)
rightturn[:, 4, :] = path_rotate_z(path, 180+180) path[:, 4, :] = path_rotate_z(semi_circle, 180+180)
rightturn[:, 5, :] = path_rotate_z(mir_path, 135+180) path[:, 5, :] = path_rotate_z(mir_path, 135+180)
return rightturn+np.tile(standby_coordinate, (g_steps, 1, 1)) return path+np.tile(standby_coordinate, (g_steps, 1, 1))
def gen_shiftleft_path(standby_coordinate): def gen_shiftleft_path(standby_coordinate,
g_steps = 20 g_steps = 20,
g_radius = 25 g_radius = 25):
assert (g_steps % 4) == 0 assert (g_steps % 4) == 0
halfsteps = int(g_steps/2) halfsteps = int(g_steps/2)
path = semicircle_generator(g_radius, g_steps) semi_circle = semicircle_generator(g_radius, g_steps)
# shift 90 degree to make the path "left" shift # shift 90 degree to make the path "left" shift
path = path_rotate_z(path, 90) semi_circle = np.array(path_rotate_z(semi_circle, 90))
mir_path = np.roll(path, halfsteps, axis=0) mir_path = np.roll(semi_circle, halfsteps, axis=0)
shiftleft = np.zeros((g_steps, 6, 3)) path = np.zeros((g_steps, 6, 3))
shiftleft[:, 0, :] = path path[:,[0,2,4],:] = np.tile(semi_circle[:, np.newaxis, :], (1, 3, 1))
shiftleft[:, 1, :] = mir_path path[:,[1,3,5],:] = np.tile(mir_path[:, np.newaxis, :], (1, 3, 1))
shiftleft[:, 2, :] = path
shiftleft[:, 3, :] = mir_path
shiftleft[:, 4, :] = path
shiftleft[:, 5, :] = mir_path
return shiftleft+np.tile(standby_coordinate, (g_steps, 1, 1)) return path+np.tile(standby_coordinate, (g_steps, 1, 1))
def gen_shiftright_path(standby_coordinate): def gen_shiftright_path(standby_coordinate,
g_steps = 20 g_steps = 20,
g_radius = 25 g_radius = 25):
assert (g_steps % 4) == 0 assert (g_steps % 4) == 0
halfsteps = int(g_steps/2) halfsteps = int(g_steps/2)
path = semicircle_generator(g_radius, g_steps) semi_circle = semicircle_generator(g_radius, g_steps)
# shift 90 degree to make the path "left" shift # shift 90 degree to make the path "left" shift
path = path_rotate_z(path, 270) semi_circle = np.array(path_rotate_z(semi_circle, 270))
mir_path = np.roll(path, halfsteps, axis=0) mir_path = np.roll(semi_circle, halfsteps, axis=0)
shiftright = np.zeros((g_steps, 6, 3))
shiftright[:, 0, :] = path
shiftright[:, 1, :] = mir_path
shiftright[:, 2, :] = path
shiftright[:, 3, :] = mir_path
shiftright[:, 4, :] = path
shiftright[:, 5, :] = mir_path
return shiftright+np.tile(standby_coordinate, (g_steps, 1, 1))
path = np.zeros((g_steps, 6, 3))
path[:,[0,2,4],:] = np.tile(semi_circle[:, np.newaxis, :], (1, 3, 1))
path[:,[1,3,5],:] = np.tile(mir_path[:, np.newaxis, :], (1, 3, 1))
def gen_climb_path(standby_coordinate): return path+np.tile(standby_coordinate, (g_steps, 1, 1))
g_steps = 20
y_radius = 20
z_radius = 80
x_radius = 30
z_shift = -30
def gen_climb_path(standby_coordinate,
g_steps = 20,
y_radius = 20,
z_radius = 80,
x_radius = 30,
z_shift = -30):
assert (g_steps % 4) == 0 assert (g_steps % 4) == 0
halfsteps = int(g_steps/2) halfsteps = int(g_steps/2)
rpath = semicircle2_generator(g_steps, y_radius, z_radius, x_radius) rpath = semicircle2_generator(g_steps, y_radius, z_radius, x_radius)
rpath[:, 2] = rpath[:, 2]+z_shift rpath[:, 2] = rpath[:, 2]+z_shift
# rpath = [(x, y, z + z_shift) for x, y,
# z in semicircle2_generator(g_steps, y_radius, z_radius, x_radius)]
lpath = semicircle2_generator(g_steps, y_radius, z_radius, -x_radius) lpath = semicircle2_generator(g_steps, y_radius, z_radius, -x_radius)
lpath[:, 2] = lpath[:, 2]+z_shift lpath[:, 2] = lpath[:, 2]+z_shift
# lpath = [(x, y, z + z_shift) for x, y,
# z in semicircle2_generator(g_steps, y_radius, z_radius, -x_radius)]
mir_rpath = np.roll(rpath, halfsteps, axis=0) mir_rpath = np.roll(rpath, halfsteps, axis=0)
mir_lpath = np.roll(lpath, halfsteps, axis=0) mir_lpath = np.roll(lpath, halfsteps, axis=0)
climbpath = np.zeros((g_steps, 6, 3)) path = np.zeros((g_steps, 6, 3))
climbpath[:, 0, :] = rpath path[:, 0, :] = rpath
climbpath[:, 1, :] = mir_rpath path[:, 1, :] = mir_rpath
climbpath[:, 2, :] = rpath path[:, 2, :] = rpath
climbpath[:, 3, :] = mir_lpath path[:, 3, :] = mir_lpath
climbpath[:, 4, :] = lpath path[:, 4, :] = lpath
climbpath[:, 5, :] = mir_lpath path[:, 5, :] = mir_lpath
return climbpath+np.tile(standby_coordinate, (g_steps, 1, 1)) return path+np.tile(standby_coordinate, (g_steps, 1, 1))
def gen_rotatex_path(standby_coordinate): def gen_rotatex_path(standby_coordinate):

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