98 lines
3.2 KiB
Plaintext
98 lines
3.2 KiB
Plaintext
import numpy as np
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from scipy.spatial.transform import Rotation as R
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def flip_coefficient_if_positive(coefficient):
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# 检查 coefficient[2] 是否大于0
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if coefficient[2] > 0:
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# 取反所有分量
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coefficient = [-x for x in coefficient]
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print("翻转:\n")
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return coefficient
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def vec2ola(coefficient):
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coefficient_raw = flip_coefficient_if_positive(coefficient)
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coefficient = coefficient_raw.reshape(-1)
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curZ = np.array(coefficient)# 定义 Z 方向的向量
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# print(curZ)
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curX = np.array([1, 1, 0],dtype=np.float64)# 定义初始 X 方向的向量
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curX /= np.linalg.norm(curX) # 归一化 X 向量
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curY = np.cross(curZ, curX)# 计算 Y 方向的向量
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curY /= np.linalg.norm(curY) # 归一化 Y 向量
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curX = np.cross(curY, curZ)# 重新计算 X 方向的向量
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curX /= np.linalg.norm(curX) # 归一化 X 向量
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# 创建旋转矩阵
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rotM = np.array([
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[curX[0], curY[0], curZ[0]],
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[curX[1], curY[1], curZ[1]],
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[curX[2], curY[2], curZ[2]]
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])
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# 打印旋转矩阵
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print("Rotation Matrix:")
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print(rotM)
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# 计算欧拉角(XYZ顺序)并转换为度
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r = R.from_matrix(rotM)
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euler_angles = r.as_euler('xyz', degrees=True)
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print("Euler Angles (degrees):")
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print(euler_angles)
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def vec2attitude(a,b,c):
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pi = np.arccos(-1.0) # pi 的值
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# 输入a, b, c
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# 定义矩阵
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r1 = np.array([[1, 0, 0],
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[0, np.cos(a * pi), np.sin(a * pi)],
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[0, -np.sin(a * pi), np.cos(a * pi)]]) # r1 矩阵 3x3
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r2 = np.array([[np.cos(b * pi), 0, -np.sin(b * pi)],
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[0, 1, 0],
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[np.sin(b * pi), 0, np.cos(b * pi)]]) # r2 矩阵 3x3
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r3 = np.array([[np.cos(c * pi), np.sin(c * pi), 0],
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[-np.sin(c * pi), np.cos(c * pi), 0],
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[0, 0, 1]]) # r3 矩阵 3x3
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vector1 = np.array([[1], [1], [1]]) # 初始向量 3x1
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# 旋转矩阵相乘并应用于向量
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matrix_result = np.dot(np.dot(np.dot(r1, r2), r3), vector1)
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# 输出结果
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ola=[]
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for m in range(matrix_result.shape[0]):
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ola.append(matrix_result[m][0])
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print(f"{matrix_result[m][0]:<20}")
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return ola
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#这个版本是先拿法向量转换成基坐标,在转欧拉
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#黄老师会给我传目标物的中心点坐标x,y,z和目标位姿的平面法向量a,b,c
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def getPosition(x,y,z,a,b,c):
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target = np.asarray([x, y, z])
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camera2robot = np.loadtxt('D:\BaiduNetdiskDownload\机械臂\GRCNN\\real\cam_pose.txt', delimiter=' ')
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position = np.dot(camera2robot[0:3, 0:3], target) + camera2robot[0:3, 3:]
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target_position = position[0:3, 0]#转换后的位置信息
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vector = np.asarray([a, b, c])
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normal_vector = vector / np.linalg.norm(vector)#归一化
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normal_vector.shape = (3, 1)
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dot_angle = np.dot(camera2robot[0:3, 0:3], normal_vector)#转换后的法向量,方向依然是同一个方向,只是表示方法变了
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target_angle = vec2ola(dot_angle)#把转换之后的法向量转换为欧拉角,欧拉角不是rpy角
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# r,p,y = angle_tool.as_euler('xyz',degrees=True)#r表示u,p表示v,y表示w
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# target_angle = np.asarray([r,p,y])
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# print(target_angle)
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return target_position,target_angle |