平面拟合在3d点云

Question

我试图使用回归公式Z = a X + b Y + C在三维点云中找到平面

我实现最小二乘和RANSAC的解决方案,但3个参数方程限制平面拟合到2.5D-式不能在平面上施加平行于Z轴.

我的问题是如何将平面拟合推广到完整的3d？我想添加第四个参数以获得完整的方程式X + b Y + c*Z + d如何避免平凡的(0,0,0,0)解？

谢谢!

我正在使用的代码:

from sklearn import linear_model

def local_regression_plane_ransac(neighborhood):
    """
    Computes parameters for a local regression plane using RANSAC
    """

    XY = neighborhood[:,:2]
    Z  = neighborhood[:,2]
    ransac = linear_model.RANSACRegressor(
                                          linear_model.LinearRegression(),
                                          residual_threshold=0.1
                                         )
    ransac.fit(XY, Z)

    inlier_mask = ransac.inlier_mask_
    coeff = model_ransac.estimator_.coef_
    intercept = model_ransac.estimator_.intercept_

Answer 1

更新

此功能现已集成在https://github.com/daavoo/pyntcloud中,使平面拟合过程更加简单:

鉴于点云:

你只需要添加一个像这样的标量字段:

is_floor = cloud.add_scalar_field("plane_fit")

将为安装的平面点添加一个值为1的新列.

您可以可视化标量字段:

老答案

我认为您可以轻松使用PCA将平面拟合到3D点而不是回归.

这是一个简单的PCA实现:

def PCA(data, correlation = False, sort = True):
""" Applies Principal Component Analysis to the data

Parameters
----------        
data: array
    The array containing the data. The array must have NxM dimensions, where each
    of the N rows represents a different individual record and each of the M columns
    represents a different variable recorded for that individual record.
        array([
        [V11, ... , V1m],
        ...,
        [Vn1, ... , Vnm]])

correlation(Optional) : bool
        Set the type of matrix to be computed (see Notes):
            If True compute the correlation matrix.
            If False(Default) compute the covariance matrix. 

sort(Optional) : bool
        Set the order that the eigenvalues/vectors will have
            If True(Default) they will be sorted (from higher value to less).
            If False they won't.   
Returns
-------
eigenvalues: (1,M) array
    The eigenvalues of the corresponding matrix.

eigenvector: (M,M) array
    The eigenvectors of the corresponding matrix.

Notes
-----
The correlation matrix is a better choice when there are different magnitudes
representing the M variables. Use covariance matrix in other cases.

"""

mean = np.mean(data, axis=0)

data_adjust = data - mean

#: the data is transposed due to np.cov/corrcoef syntax
if correlation:

    matrix = np.corrcoef(data_adjust.T)

else:
    matrix = np.cov(data_adjust.T) 

eigenvalues, eigenvectors = np.linalg.eig(matrix)

if sort:
    #: sort eigenvalues and eigenvectors
    sort = eigenvalues.argsort()[::-1]
    eigenvalues = eigenvalues[sort]
    eigenvectors = eigenvectors[:,sort]

return eigenvalues, eigenvectors

以下是如何将点拟合到飞机上:

def best_fitting_plane(points, equation=False):
""" Computes the best fitting plane of the given points

Parameters
----------        
points: array
    The x,y,z coordinates corresponding to the points from which we want
    to define the best fitting plane. Expected format:
        array([
        [x1,y1,z1],
        ...,
        [xn,yn,zn]])

equation(Optional) : bool
        Set the oputput plane format:
            If True return the a,b,c,d coefficients of the plane.
            If False(Default) return 1 Point and 1 Normal vector.    
Returns
-------
a, b, c, d : float
    The coefficients solving the plane equation.

or

point, normal: array
    The plane defined by 1 Point and 1 Normal vector. With format:
    array([Px,Py,Pz]), array([Nx,Ny,Nz])

"""

w, v = PCA(points)

#: the normal of the plane is the last eigenvector
normal = v[:,2]

#: get a point from the plane
point = np.mean(points, axis=0)


if equation:
    a, b, c = normal
    d = -(np.dot(normal, point))
    return a, b, c, d

else:
    return point, normal    

但是,由于此方法对异常值很敏感,因此可以使用RANSAC使异常值非常稳定.

有一个Python实现RANSAC的位置.

而且您应该只需要定义一个Plane Model类,以便将它用于将平面拟合到3D点.

在任何情况下,如果你可以从异常值清理3D点(也许你可以使用KD-Tree SOR滤波器),你应该用PCA获得相当不错的结果.

以下是SOR的实现:

def statistical_outilier_removal(kdtree, k=8, z_max=2 ):
""" Compute a Statistical Outlier Removal filter on the given KDTree.

Parameters
----------                        
kdtree: scipy's KDTree instance
    The KDTree's structure which will be used to
    compute the filter.

k(Optional): int
    The number of nearest neighbors wich will be used to estimate the 
    mean distance from each point to his nearest neighbors.
    Default : 8

z_max(Optional): int
    The maximum Z score wich determines if the point is an outlier or 
    not.

Returns
-------
sor_filter : boolean array
    The boolean mask indicating wherever a point should be keeped or not.
    The size of the boolean mask will be the same as the number of points
    in the KDTree.

Notes
-----    
The 2 optional parameters (k and z_max) should be used in order to adjust
the filter to the desired result.

A HIGHER 'k' value will result(normally) in a HIGHER number of points trimmed.

A LOWER 'z_max' value will result(normally) in a HIGHER number of points trimmed.

"""

distances, i = kdtree.query(kdtree.data, k=k, n_jobs=-1) 

z_distances = stats.zscore(np.mean(distances, axis=1))

sor_filter = abs(z_distances) < z_max

return sor_filter

您可以使用此实现为计算出的3D点数的KDtree提供函数