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294 lines
8.7 KiB
Python
294 lines
8.7 KiB
Python
#!python
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#
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# 2021 Zhengyu Peng
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# Website: https://zpeng.me
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#
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# ` `
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# -:. -#:
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# -//:. -###:
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# -////:. -#####:
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# -/:.://:. -###++##:
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# .. `://:- -###+. :##:
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# `:/+####+. :##:
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# .::::::::/+###. :##:
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# .////-----+##: `:###:
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# `-//:. :##: `:###/.
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# `-//:. :##:`:###/.
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# `-//:+######/.
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# `-/+####/.
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# `+##+.
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# :##:
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# :##:
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# :##:
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# :##:
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# :##:
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# .+:
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from lib import semicircle_generator, semicircle2_generator
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from lib import path_rotate_z
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from lib import get_rotate_x_matrix, get_rotate_y_matrix, get_rotate_z_matrix
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import numpy as np
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def gen_walk_path(standby_coordinate,
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g_steps=20,
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g_radius=35,
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direction=0):
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assert (g_steps % 4) == 0
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halfsteps = int(g_steps/2)
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semi_circle = semicircle_generator(g_radius, g_steps)
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semi_circle = np.array(path_rotate_z(semi_circle, direction))
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mir_path = np.roll(semi_circle, halfsteps, axis=0)
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path = np.zeros((g_steps, 6, 3))
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path[:, [0, 2, 4], :] = np.tile(semi_circle[:, np.newaxis, :], (1, 3, 1))
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path[:, [1, 3, 5], :] = np.tile(mir_path[:, np.newaxis, :], (1, 3, 1))
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return {'coord': path+np.tile(standby_coordinate, (g_steps, 1, 1)),
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'type': 'motion'}
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def gen_fastwalk_path(standby_coordinate,
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g_steps=20,
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y_radius=50,
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z_radius=30,
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x_radius=10,
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reverse=False):
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assert (g_steps % 2) == 0
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halfsteps = int(g_steps/2)
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path = np.zeros((g_steps, 6, 3))
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semi_circle_r = semicircle2_generator(
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g_steps, y_radius, z_radius, x_radius, reverse=reverse)
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semi_circle_l = semicircle2_generator(
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g_steps, y_radius, z_radius, -x_radius, reverse=reverse)
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path[:, [0, 2], :] = np.tile(semi_circle_r[:, np.newaxis, :], (1, 2, 1))
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path[:, 1, :] = np.roll(semi_circle_r, halfsteps, axis=0)
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path[:, 4, :] = semi_circle_l
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path[:, [3, 5], :] = np.tile(
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np.roll(semi_circle_l[:, np.newaxis, :], halfsteps, axis=0), (1, 2, 1))
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return {'coord': path+np.tile(standby_coordinate, (g_steps, 1, 1)),
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'type': 'motion'}
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def gen_turn_path(standby_coordinate,
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g_steps=20,
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g_radius=35,
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direction='left'):
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assert (g_steps % 4) == 0
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halfsteps = int(g_steps/2)
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path = np.zeros((g_steps, 6, 3))
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semi_circle = semicircle_generator(g_radius, g_steps)
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mir_path = np.roll(semi_circle, halfsteps, axis=0)
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if direction == 'left':
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path[:, 0, :] = path_rotate_z(semi_circle, 45)
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path[:, 1, :] = path_rotate_z(mir_path, 0)
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path[:, 2, :] = path_rotate_z(semi_circle, 315)
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path[:, 3, :] = path_rotate_z(mir_path, 225)
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path[:, 4, :] = path_rotate_z(semi_circle, 180)
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path[:, 5, :] = path_rotate_z(mir_path, 135)
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elif direction == 'right':
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path[:, 0, :] = path_rotate_z(semi_circle, 45+180)
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path[:, 1, :] = path_rotate_z(mir_path, 0+180)
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path[:, 2, :] = path_rotate_z(semi_circle, 315+180)
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path[:, 3, :] = path_rotate_z(mir_path, 225+180)
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path[:, 4, :] = path_rotate_z(semi_circle, 180+180)
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path[:, 5, :] = path_rotate_z(mir_path, 135+180)
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return {'coord': path+np.tile(standby_coordinate, (g_steps, 1, 1)),
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'type': 'motion'}
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def gen_climb_path(standby_coordinate,
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g_steps=20,
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y_radius=20,
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z_radius=80,
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x_radius=30,
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z_shift=-30,
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reverse=False):
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assert (g_steps % 4) == 0
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halfsteps = int(g_steps/2)
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rpath = semicircle2_generator(
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g_steps, y_radius, z_radius, x_radius, reverse=reverse)
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rpath[:, 2] = rpath[:, 2]+z_shift
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lpath = semicircle2_generator(
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g_steps, y_radius, z_radius, -x_radius, reverse=reverse)
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lpath[:, 2] = lpath[:, 2]+z_shift
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mir_rpath = np.roll(rpath, halfsteps, axis=0)
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mir_lpath = np.roll(lpath, halfsteps, axis=0)
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path = np.zeros((g_steps, 6, 3))
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path[:, 0, :] = rpath
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path[:, 1, :] = mir_rpath
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path[:, 2, :] = rpath
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path[:, 3, :] = mir_lpath
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path[:, 4, :] = lpath
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path[:, 5, :] = mir_lpath
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return {'coord': path+np.tile(standby_coordinate, (g_steps, 1, 1)),
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'type': 'motion'}
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def gen_rotatex_path(standby_coordinate,
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g_steps=20,
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swing_angle=15,
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y_radius=15):
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assert (g_steps % 4) == 0
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quarter = int(g_steps/4)
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path = np.zeros((g_steps, 6, 3))
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step_angle = swing_angle / quarter
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step_offset = y_radius / quarter
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scx = np.append(standby_coordinate, np.ones((6, 1)), axis=1)
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for i in range(quarter):
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m = get_rotate_x_matrix(swing_angle - i*step_angle)
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m[1, 3] = -i * step_offset
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path[i, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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for i in range(quarter):
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m = get_rotate_x_matrix(-i*step_angle)
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m[1, 3] = -y_radius + i * step_offset
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path[i+quarter, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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for i in range(quarter):
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m = get_rotate_x_matrix(i*step_angle-swing_angle)
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m[1, 3] = i * step_offset
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path[i+quarter*2, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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for i in range(quarter):
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m = get_rotate_x_matrix(i*step_angle)
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m[1, 3] = y_radius-i * step_offset
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path[i+quarter*3, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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return {'coord': path,
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'type': 'motion'}
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def gen_rotatey_path(standby_coordinate,
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g_steps=20,
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swing_angle=15,
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x_radius=15):
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assert (g_steps % 4) == 0
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quarter = int(g_steps/4)
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path = np.zeros((g_steps, 6, 3))
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step_angle = swing_angle / quarter
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step_offset = x_radius / quarter
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scx = np.append(standby_coordinate, np.ones((6, 1)), axis=1)
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for i in range(quarter):
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m = get_rotate_y_matrix(swing_angle - i*step_angle)
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m[1, 3] = -i * step_offset
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path[i, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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for i in range(quarter):
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m = get_rotate_y_matrix(-i*step_angle)
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m[1, 3] = -x_radius + i * step_offset
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path[i+quarter, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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for i in range(quarter):
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m = get_rotate_y_matrix(i*step_angle-swing_angle)
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m[1, 3] = i * step_offset
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path[i+quarter*2, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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for i in range(quarter):
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m = get_rotate_y_matrix(i*step_angle)
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m[1, 3] = x_radius-i * step_offset
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path[i+quarter*3, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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return {'coord': path,
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'type': 'motion'}
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def gen_rotatez_path(standby_coordinate,
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g_steps=20,
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z_lift=4.5,
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xy_radius=1):
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assert (g_steps % 4) == 0
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path = np.zeros((g_steps, 6, 3))
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step_angle = 2*np.pi / g_steps
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scx = np.append(standby_coordinate, np.ones((6, 1)), axis=1)
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for i in range(g_steps):
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x = xy_radius * np.cos(i*step_angle)
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y = xy_radius * np.sin(i*step_angle)
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m = get_rotate_y_matrix(np.arctan2(x, z_lift)*180/np.pi) * \
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get_rotate_x_matrix(np.arctan2(y, z_lift)*180/np.pi)
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path[i, :, :] = ((np.matmul(m, scx.T)).T)[:, :-1]
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return {'coord': path,
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'type': 'motion'}
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def gen_twist_path(standby_coordinate,
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g_steps=20,
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raise_angle=3,
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twist_x_angle=20,
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twise_y_angle=12):
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assert (g_steps % 4) == 0
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quarter = int(g_steps / 4)
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step_x_angle = twist_x_angle / quarter
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step_y_angle = twise_y_angle / quarter
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scx = np.append(standby_coordinate, np.ones((6, 1)), axis=1)
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m = get_rotate_x_matrix(raise_angle)
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path = np.zeros((g_steps, 6, 3))
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for i in range(quarter):
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temp = m * get_rotate_z_matrix(i*step_x_angle) * \
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get_rotate_x_matrix(i*step_y_angle)
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path[i, :, :] = ((np.matmul(temp, scx.T)).T)[:, :-1]
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for i in range(quarter):
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temp = m * get_rotate_z_matrix((quarter-i)*step_x_angle) * \
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get_rotate_x_matrix((quarter-i)*step_y_angle)
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path[i+quarter*1, :, :] = ((np.matmul(temp, scx.T)).T)[:, :-1]
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for i in range(quarter):
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temp = m * get_rotate_z_matrix(-i*step_x_angle) * \
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get_rotate_x_matrix(i*step_y_angle)
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path[i+quarter*2, :, :] = ((np.matmul(temp, scx.T)).T)[:, :-1]
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for i in range(quarter):
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temp = m * get_rotate_z_matrix((-quarter+i)*step_x_angle) * \
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get_rotate_x_matrix((quarter-i)*step_y_angle)
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path[i+quarter*3, :, :] = ((np.matmul(temp, scx.T)).T)[:, :-1]
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return {'coord': path,
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'type': 'motion'}
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