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(1)官方介绍地址
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2、介绍 2.1 原理(1)关于ICP registration
2.2 辅助可视化函数本教程演示ICP(迭代最近点)配准算法。多年来,它一直是研究和工业中几何配准的支柱。输入是两个点云和一个初始转换,该转换大致将源点云与目标点云对齐。输出是一个精细化的转换,它将两个点云紧密对齐。一个助手函数draw_registration_result可视化注册过程中的对齐情况。在本教程中,我们展示了两种ICP变体,点到点ICP和点到面ICP [Rusinkiewicz2001]。
(2)采用的辅助可视化函数
下面的函数可视化了一个目标点云和一个经过对齐转换的源点云。目标点云和源点云分别绘以青色和黄色。两点云重叠越紧密,对准效果越好。
def draw_registration_result(source, target, transformation):
source_temp = copy.deepcopy(source)
target_temp = copy.deepcopy(target)
source_temp.paint_uniform_color([1, 0.706, 0])
target_temp.paint_uniform_color([0, 0.651, 0.929])
source_temp.transform(transformation)
o3d.visualization.draw_geometries([source_temp, target_temp],
zoom=0.4459,
front=[0.9288, -0.2951, -0.2242],
lookat=[1.6784, 2.0612, 1.4451],
up=[-0.3402, -0.9189, -0.1996])
2.3 输入注意:由于函数transform和paint_uniform_color改变了点云,我们调用copy.deepcopy(深度复制,即重新拷贝一份全新的对象)来复制和保护原始的点云。
2.3 .1 两个原始输入下面的代码从两个文件读取一个源点云和一个目标点云。给出了一个粗略的变换。
注意:初始对准通常采用全局配准算法。有关示例,请参见全局注册 Global registration例子。
(1)先看看两个原始点云的分别
import open3d as o3d
import numpy as np
from copy import deepcopy
#(一)先简单看看
demo_icp_pcds = o3d.data.DemoICPPointClouds()
source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
o3d.visualization.draw_geometries([source,target])
(2)可以看到两个模型一开始没有对准,可以理解成在两个角度采集的
2.3.2两个输入粗略配准(1)下面是
import open3d as o3d
import numpy as np
from copy import deepcopy
def draw_registration_result(source, target, transformation):
# source_temp = copy.deepcopy(source)
# target_temp = copy.deepcopy(target)
source_temp = deepcopy(source)
target_temp = deepcopy(target)
source_temp.paint_uniform_color([1, 0.706, 0])
target_temp.paint_uniform_color([0, 0.651, 0.929])
source_temp.transform(transformation)
o3d.visualization.draw_geometries([source_temp, target_temp],
zoom=0.4459,
front=[0.9288, -0.2951, -0.2242],
lookat=[1.6784, 2.0612, 1.4451],
up=[-0.3402, -0.9189, -0.1996])
demo_icp_pcds = o3d.data.DemoICPPointClouds()
source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
threshold = 0.02
trans_init = np.asarray([[0.862, 0.011, -0.507, 0.5],
[-0.139, 0.967, -0.215, 0.7],
[0.487, 0.255, 0.835, -1.4], [0.0, 0.0, 0.0, 1.0]])
draw_registration_result(source, target, trans_init)
(2)配准后的两种颜色,对应两个输入,看看是真的粗略配准了
2.4 初始化注册函数evaluate_registration(1)说明
evaluate_registration函数计算两个主要指标:
fitness, 适应度,衡量重叠区域(内部对应的# /目标点的#)。越高越好。
inlier_rmse,它计算所有内部(inlier)匹配的RMSE。越低越好。
(2)代码测试一下
import open3d as o3d
import numpy as np
from copy import deepcopy
# #(一)先简单看看
# demo_icp_pcds = o3d.data.DemoICPPointClouds()
# source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
# target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
# o3d.visualization.draw_geometries([source,target])
#(二)粗略配准
def draw_registration_result(source, target, transformation):
# source_temp = copy.deepcopy(source)
# target_temp = copy.deepcopy(target)
source_temp = deepcopy(source)
target_temp = deepcopy(target)
source_temp.paint_uniform_color([1, 0.706, 0])
target_temp.paint_uniform_color([0, 0.651, 0.929])
source_temp.transform(transformation)
o3d.visualization.draw_geometries([source_temp, target_temp],
zoom=0.4459,
front=[0.9288, -0.2951, -0.2242],
lookat=[1.6784, 2.0612, 1.4451],
up=[-0.3402, -0.9189, -0.1996])
demo_icp_pcds = o3d.data.DemoICPPointClouds()
source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
threshold = 0.02
trans_init = np.asarray([[0.862, 0.011, -0.507, 0.5],
[-0.139, 0.967, -0.215, 0.7],
[0.487, 0.255, 0.835, -1.4], [0.0, 0.0, 0.0, 1.0]])
draw_registration_result(source, target, trans_init)
print("Initial alignment")
evaluation = o3d.pipelines.registration.evaluate_registration(
source, target, threshold, trans_init)
print(evaluation)
3点对点ICP(Point-to-point ICP ) 3.1原理Initial alignment
RegistrationResult with fitness=1.747228e-01, inlier_rmse=1.177106e-02, and correspondence_set size of 34741
Access transformation to get result.
通常情况下,ICP算法迭代两个步骤:
(1)从目标点云P中找对应集K={(p,q)},用当前变换矩阵T变换源点云Q。
(2)通过对应集合K上定义的,最小化目标函数E(T),来更新变换矩阵T。
Different variants of ICP use different objective functions E(T)E(T) [BeslAndMcKay1992] [ChenAndMedioni1992] [Park2017].
我们首先展示了使用目标的点对点ICP算法[BeslAndMcKay1992]
TransformationEstimationPointToPoint类提供函数来计算点对点ICP目标的残差和雅可比矩阵。函数registration_icp将其作为参数并运行点对点ICP以获得结果。
3.2 代码测试(1)测试代码
import open3d as o3d
import numpy as np
from copy import deepcopy
# #(一)先简单看看
# demo_icp_pcds = o3d.data.DemoICPPointClouds()
# source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
# target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
# o3d.visualization.draw_geometries([source,target])
#(二)粗略配准
def draw_registration_result(source, target, transformation):
# source_temp = copy.deepcopy(source)
# target_temp = copy.deepcopy(target)
source_temp = deepcopy(source)
target_temp = deepcopy(target)
source_temp.paint_uniform_color([1, 0.706, 0])
target_temp.paint_uniform_color([0, 0.651, 0.929])
source_temp.transform(transformation)
o3d.visualization.draw_geometries([source_temp, target_temp],
zoom=0.4459,
front=[0.9288, -0.2951, -0.2242],
lookat=[1.6784, 2.0612, 1.4451],
up=[-0.3402, -0.9189, -0.1996])
demo_icp_pcds = o3d.data.DemoICPPointClouds()
source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
threshold = 0.02
trans_init = np.asarray([[0.862, 0.011, -0.507, 0.5],
[-0.139, 0.967, -0.215, 0.7],
[0.487, 0.255, 0.835, -1.4], [0.0, 0.0, 0.0, 1.0]])
draw_registration_result(source, target, trans_init)
print("Initial alignment")
evaluation = o3d.pipelines.registration.evaluate_registration(
source, target, threshold, trans_init)
print(evaluation)
print("Apply point-to-point ICP")
reg_p2p = o3d.pipelines.registration.registration_icp(
source, target, threshold, trans_init,
o3d.pipelines.registration.TransformationEstimationPointToPoint())
print(reg_p2p)
print("Transformation is:")
print(reg_p2p.transformation)
draw_registration_result(source, target, reg_p2p.transformation)
(2)展示的结果
(3)改进
适应度(
fitness
)分数从0.174723增加到0.372450。inlier_rmse从0.011771减少到0.007760。默认情况下,registration_icp运行直到收敛或达到大迭代次数(默认为30)。可以更改它以允许更多的计算时间并进一步改进结果。
(4)改进的参数设置
o3d.pipelines.registration.ICPConvergenceCriteria(max_iteration=2000)
(5)测试代码
import open3d as o3d
import numpy as np
from copy import deepcopy
# #(一)先简单看看
# demo_icp_pcds = o3d.data.DemoICPPointClouds()
# source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
# target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
# o3d.visualization.draw_geometries([source,target])
#(二)粗略配准
def draw_registration_result(source, target, transformation):
# source_temp = copy.deepcopy(source)
# target_temp = copy.deepcopy(target)
source_temp = deepcopy(source)
target_temp = deepcopy(target)
source_temp.paint_uniform_color([1, 0.706, 0])
target_temp.paint_uniform_color([0, 0.651, 0.929])
source_temp.transform(transformation)
o3d.visualization.draw_geometries([source_temp, target_temp],
zoom=0.4459,
front=[0.9288, -0.2951, -0.2242],
lookat=[1.6784, 2.0612, 1.4451],
up=[-0.3402, -0.9189, -0.1996])
demo_icp_pcds = o3d.data.DemoICPPointClouds()
source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
threshold = 0.02
trans_init = np.asarray([[0.862, 0.011, -0.507, 0.5],
[-0.139, 0.967, -0.215, 0.7],
[0.487, 0.255, 0.835, -1.4], [0.0, 0.0, 0.0, 1.0]])
draw_registration_result(source, target, trans_init)
print("Initial alignment")
evaluation = o3d.pipelines.registration.evaluate_registration(
source, target, threshold, trans_init)
print(evaluation)
print("Apply point-to-point ICP")
reg_p2p = o3d.pipelines.registration.registration_icp(
source, target, threshold, trans_init,
o3d.pipelines.registration.TransformationEstimationPointToPoint())
print(reg_p2p)
print("Transformation is:")
print(reg_p2p.transformation)
draw_registration_result(source, target, reg_p2p.transformation)
reg_p2p = o3d.pipelines.registration.registration_icp(
source, target, threshold, trans_init,
o3d.pipelines.registration.TransformationEstimationPointToPoint(),
o3d.pipelines.registration.ICPConvergenceCriteria(max_iteration=2000))
print(reg_p2p)
print("Transformation is:")
print(reg_p2p.transformation)
draw_registration_result(source, target, reg_p2p.transformation)
果然,2000步迭代后,果然匹配的漂亮了很多
计算得到的变换矩阵也更精确了
4、点对面ICP(Point-to-plane ICP ) 4.1原理点到平面的ICP算法[ChenAndMedioni1992]使用了不同的目标函数
其中np为点p的法线。[Rusinkiewicz2001]证明了点到面ICP算法比点到点ICP算法具有更快的收敛速度。
registration_icp调用了使用不同的参数TransformationEstimationPointToPlane。在内部,这个类实现函数来计算残差和点到平面的ICP目标的雅可比矩阵。
4.2 测试代码(1)代码
import open3d as o3d
import numpy as np
from copy import deepcopy
# #(一)先简单看看
# demo_icp_pcds = o3d.data.DemoICPPointClouds()
# source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
# target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
# o3d.visualization.draw_geometries([source,target])
#(二)粗略配准
def draw_registration_result(source, target, transformation):
# source_temp = copy.deepcopy(source)
# target_temp = copy.deepcopy(target)
source_temp = deepcopy(source)
target_temp = deepcopy(target)
source_temp.paint_uniform_color([1, 0.706, 0])
target_temp.paint_uniform_color([0, 0.651, 0.929])
source_temp.transform(transformation)
o3d.visualization.draw_geometries([source_temp, target_temp],
zoom=0.4459,
front=[0.9288, -0.2951, -0.2242],
lookat=[1.6784, 2.0612, 1.4451],
up=[-0.3402, -0.9189, -0.1996])
demo_icp_pcds = o3d.data.DemoICPPointClouds()
source = o3d.io.read_point_cloud(demo_icp_pcds.paths[0])
target = o3d.io.read_point_cloud(demo_icp_pcds.paths[1])
threshold = 0.02
trans_init = np.asarray([[0.862, 0.011, -0.507, 0.5],
[-0.139, 0.967, -0.215, 0.7],
[0.487, 0.255, 0.835, -1.4], [0.0, 0.0, 0.0, 1.0]])
# draw_registration_result(source, target, trans_init)
# print("Initial alignment")
# evaluation = o3d.pipelines.registration.evaluate_registration(
# source, target, threshold, trans_init)
# print(evaluation)
#(三)点对点配准
# print("Apply point-to-point ICP")
# reg_p2p = o3d.pipelines.registration.registration_icp(
# source, target, threshold, trans_init,
# o3d.pipelines.registration.TransformationEstimationPointToPoint())
# print(reg_p2p)
# print("Transformation is:")
# print(reg_p2p.transformation)
# draw_registration_result(source, target, reg_p2p.transformation)
# reg_p2p = o3d.pipelines.registration.registration_icp(
# source, target, threshold, trans_init,
# o3d.pipelines.registration.TransformationEstimationPointToPoint(),
# o3d.pipelines.registration.ICPConvergenceCriteria(max_iteration=2000))
# print(reg_p2p)
# print("Transformation is:")
# print(reg_p2p.transformation)
# draw_registration_result(source, target, reg_p2p.transformation)
#(四)平面配准
print("Apply point-to-plane ICP")
reg_p2l = o3d.pipelines.registration.registration_icp(
source, target, threshold, trans_init,
o3d.pipelines.registration.TransformationEstimationPointToPlane())
print(reg_p2l)
print("Transformation is:")
print(reg_p2l.transformation)
draw_registration_result(source, target, reg_p2l.transformation)
(2)测试结果图
点到平面的ICP在30次迭代中达到紧密对齐(适合度评分为0.620972,inlier_rmse评分为0.006581)。效果还很不错
Apply point-to-plane ICP
RegistrationResult with fitness=6.209722e-01, inlier_rmse=6.581453e-03, and correspondence_set size of 123471
注意:点到平面的ICP算法使用点法线。在本教程中,我们从文件加载法线。如果没有给出法线,可以用顶点法线估计来计算。
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