python：绘制线框 3D 长方体

我也遇到了同样的问题，尝试给出以下答案。

def cuboid_data(center, size):
"""
   Create a data array for cuboid plotting.


   ============= ================================================
   Argument      Description
   ============= ================================================
   center        center of the cuboid, triple
   size          size of the cuboid, triple, (x_length,y_width,z_height)
   :type size: tuple, numpy.array, list
   :param size: size of the cuboid, triple, (x_length,y_width,z_height)
   :type center: tuple, numpy.array, list
   :param center: center of the cuboid, triple, (x,y,z)


  """


    # suppose axis direction: x: to left; y: to inside; z: to upper
    # get the (left, outside, bottom) point
    o = [a - b / 2 for a, b in zip(center, size)]
    # get the length, width, and height
    l, w, h = size
    x = [[o[0], o[0] + l, o[0] + l, o[0], o[0]],  # x coordinate of points in bottom surface
         [o[0], o[0] + l, o[0] + l, o[0], o[0]],  # x coordinate of points in upper surface
         [o[0], o[0] + l, o[0] + l, o[0], o[0]],  # x coordinate of points in outside surface
         [o[0], o[0] + l, o[0] + l, o[0], o[0]]]  # x coordinate of points in inside surface
    y = [[o[1], o[1], o[1] + w, o[1] + w, o[1]],  # y coordinate of points in bottom surface
         [o[1], o[1], o[1] + w, o[1] + w, o[1]],  # y coordinate of points in upper surface
         [o[1], o[1], o[1], o[1], o[1]],          # y coordinate of points in outside surface
         [o[1] + w, o[1] + w, o[1] + w, o[1] + w, o[1] + w]]    # y coordinate of points in inside surface
    z = [[o[2], o[2], o[2], o[2], o[2]],                        # z coordinate of points in bottom surface
         [o[2] + h, o[2] + h, o[2] + h, o[2] + h, o[2] + h],    # z coordinate of points in upper surface
         [o[2], o[2], o[2] + h, o[2] + h, o[2]],                # z coordinate of points in outside surface
         [o[2], o[2], o[2] + h, o[2] + h, o[2]]]                # z coordinate of points in inside surface
    return x, y, z



def test():
    import matplotlib as mpl
    from mpl_toolkits.mplot3d import Axes3D
    import numpy as np
    center = [0, 0, 0]
    length = 32 * 2
    width = 50 * 2
    height = 100 * 2
    import matplotlib.pyplot as plt
    fig = plt.figure()
    ax = fig.add_subplot(projection='3d') 
    X, Y, Z = cuboid_data(center, (length, width, height))
    ax.plot_surface(np.asarray(X), np.asarray(Y), np.asarray(Z), color='b', rstride=1, cstride=1, alpha=0.1)
    ax.set_xlabel('X')
    ax.set_xlim(-100, 100)
    ax.set_ylabel('Y')
    ax.set_ylim(-100, 100)
    ax.set_zlabel('Z')
    ax.set_zlim(-100, 100)
    plt.show()


if __name__ == '__main__':
    test()

这是结果：

这是长方体的线框图。

def plot_cuboid(center, size):
    """
       Create a data array for cuboid plotting.


       ============= ================================================
       Argument      Description
       ============= ================================================
       center        center of the cuboid, triple
       size          size of the cuboid, triple, (x_length,y_width,z_height)
       :type size: tuple, numpy.array, list
       :param size: size of the cuboid, triple, (x_length,y_width,z_height)
       :type center: tuple, numpy.array, list
       :param center: center of the cuboid, triple, (x,y,z)
   """
    # suppose axis direction: x: to left; y: to inside; z: to upper
    # get the (left, outside, bottom) point
    import numpy as np
    ox, oy, oz = center
    l, w, h = size

    x = np.linspace(ox-l/2,ox+l/2,num=10)
    y = np.linspace(oy-w/2,oy+w/2,num=10)
    z = np.linspace(oz-h/2,oz+h/2,num=10)
    x1, z1 = np.meshgrid(x, z)
    y11 = np.ones_like(x1)*(oy-w/2)
    y12 = np.ones_like(x1)*(oy+w/2)
    x2, y2 = np.meshgrid(x, y)
    z21 = np.ones_like(x2)*(oz-h/2)
    z22 = np.ones_like(x2)*(oz+h/2)
    y3, z3 = np.meshgrid(y, z)
    x31 = np.ones_like(y3)*(ox-l/2)
    x32 = np.ones_like(y3)*(ox+l/2)

    from mpl_toolkits.mplot3d import Axes3D
    import matplotlib.pyplot as plt
    fig = plt.figure()
    ax = fig.add_subplot(projection='3d')
    # outside surface
    ax.plot_wireframe(x1, y11, z1, color='b', rstride=1, cstride=1, alpha=0.6)
    # inside surface
    ax.plot_wireframe(x1, y12, z1, color='b', rstride=1, cstride=1, alpha=0.6)
    # bottom surface
    ax.plot_wireframe(x2, y2, z21, color='b', rstride=1, cstride=1, alpha=0.6)
    # upper surface
    ax.plot_wireframe(x2, y2, z22, color='b', rstride=1, cstride=1, alpha=0.6)
    # left surface
    ax.plot_wireframe(x31, y3, z3, color='b', rstride=1, cstride=1, alpha=0.6)
    # right surface
    ax.plot_wireframe(x32, y3, z3, color='b', rstride=1, cstride=1, alpha=0.6)
    ax.set_xlabel('X')
    ax.set_xlim(-100, 100)
    ax.set_ylabel('Y')
    ax.set_ylim(-100, 100)
    ax.set_zlabel('Z')
    ax.set_zlim(-100, 100)
    plt.show()



def test():
    center = [0, 0, 0]
    length = 32 * 2
    width = 50 * 2
    height = 100 * 2
    plot_cuboid(center, (length, width, height))


if __name__ == '__main__':
    test()

这是结果。

每个人都忘记了可以很好地处理 3D 的 POVray。不过，它不会渲染线框，但您可以使用半透明纹理来查看盒子内部的内容。

#!/usr/bin/python
# -*- coding: utf-8 -*-

import os

center='-1, -1, -1'
radius='1, 1, 1'


pov='camera { location <0, 2, -3> look_at  <0, 1,  2> }\n\
light_source { <2, 4, -3> color rgb 1*1.5}\n\
background {color rgb <0.00, 0.00, 0.00>}\n\
box {<'+center+'>, < '+radius+'>\n\
pigment { color rgbt <0.67, 1.00, 0.39, 0.80> }\n\
rotate <52, 6, 0>\n\
scale 0.9\n\
translate <0, 1.2, 1>}\n\
'

f=open('scene.pov', 'w')
f.write(pov)
f.close()

os.system('povray +W400 +H300 +A +FN  scene.pov')

输出“场景.png”

您需要阅读 povray 的文档。