Exemplo n.º 1
0
    def get_plane(
        self,
        pos=None,
        norm=None,
        plane=None,
        sx=None,
        sy=None,
        color="lightgray",
        alpha=0.25,
        **kwargs,
    ):
        """
        Returns a plane going through a point at pos, oriented
        orthogonally to the vector norm and of width and height
        sx, sy.

        :param pos: 3-tuple or list with x,y,z, coords of point the plane goes through
        :param norm: 3-tuple with plane's normal vector (optional)
        :param sx, sy: int, width and height of the plane
        :param plane: "sagittal", "horizontal", or "frontal"
        :param color, alpha: plane color and transparency
        """
        axes_pairs = dict(sagittal=(0, 1), horizontal=(2, 0), frontal=(2, 1))

        if pos is None:
            pos = self.root.centerOfMass()

        try:
            norm = norm or self.space.plane_normals[plane]
        except KeyError:  # pragma: no cover
            raise ValueError(  # pragma: no cover
                f"Could not find normals for plane {plane}. Atlas space provides these normals: {self.space.plane_normals}"  # pragma: no cover
            )

        # Get plane width and height
        idx_pair = (
            axes_pairs[plane]
            if plane is not None
            else axes_pairs["horizontal"]
        )

        bounds = self.root.bounds()
        root_bounds = [
            [bounds[0], bounds[1]],
            [bounds[2], bounds[3]],
            [bounds[4], bounds[5]],
        ]

        wh = [float(np.diff(root_bounds[i])) for i in idx_pair]
        if sx is None:
            sx = wh[0]
        if sy is None:
            sy = wh[1]

        # return plane
        return Actor(
            Plane(pos=pos, normal=norm, sx=sx, sy=sy, c=color, alpha=alpha),
            name=f"Plane at {pos} norm: {norm}",
            br_class="plane",
        )
Exemplo n.º 2
0
    def get_plane_at_point(
        self,
        pos=None,
        norm=None,
        plane=None,
        sx=None,
        sy=None,
        color="lightgray",
        alpha=0.25,
        **kwargs,
    ):
        """ 
            Returns a plane going through a point at pos, oriented 
            orthogonally to the vector norm and of width and height
            sx, sy. 

            :param pos: 3-tuple or list with x,y,z, coords of point the plane goes through
            :param norm: 3-tuple with plane's normal vector (optional)
            :param sx, sy: int, width and height of the plane
            :param plane: "sagittal", "horizontal", or "frontal"
            :param color, alpha: plane color and transparency
        """
        axes_pairs = dict(sagittal=(0, 1), horizontal=(2, 0), frontal=(2, 1))

        # Get position
        if pos is None:
            pos = self._root_midpoint
        elif not isinstance(pos, (list, tuple)) or not len(pos) == 3:
            raise ValueError(f"Invalid pos argument: {pos}")

        # Get normal if one is not given
        if norm is None:
            try:
                norm = self.space.plane_normals[plane]
            except KeyError:
                raise ValueError(
                    f"Could not find normals for plane {plane}. Atlas space {self.space} provides these normals: {self.spacel.plane_normals}"
                )

        # Get plane width and height
        idx_pair = (
            axes_pairs[plane]
            if plane is not None
            else axes_pairs["horizontal"]
        )
        wh = [float(np.diff(self._root_bounds[i])) * 1.2 for i in idx_pair]
        if sx is None:
            sx = wh[0]
        if sy is None:
            sy = wh[1]

        # return plane
        return Plane(pos=pos, normal=norm, sx=sx, sy=sy, c=color, alpha=alpha)
Exemplo n.º 3
0
from vedo import Plotter, Plane, datadir

vp = Plotter()

cow = vp.load(datadir + "cow.vtk", c="grey").scale(4).rotateX(-90)
vp += Plane(pos=[0, -3.6, 0], normal=[0, 1, 0], sx=20).texture("grass")
vp.show(viewup='y', interactive=0)

# vp.light() returns a vtkLight object with focal Point, fp, to mesh cow
# fp can also be explicitly set as fp=[x,y,z]
l = vp.addLight(pos=[-6, 6, 6], focalPoint=cow, deg=12, showsource=1)

# can be switched on/off this way
#l.SwitchOff()

vp.show(interactive=1)
Exemplo n.º 4
0
import trimesh
import numpy as np
from vedo import show, Plane, printc, download

# load the mesh from filename, file objects are also supported
f = download(
    'https://github.com/mikedh/trimesh/raw/master/models/featuretype.STL')
mesh = trimesh.load_mesh(f)

# get a single cross section of the mesh
txt = 'cross section of the mesh'
mslice = mesh.section(plane_origin=mesh.centroid, plane_normal=[0, 0, 1])

pl = Plane(mesh.centroid, normal=[0, 0, 1], sx=6, sy=4, alpha=0.3)

slice_2D, to_3D = mslice.to_planar()

# show objects on N=2 non-synced renderers:
show([(mesh, pl), (slice_2D, txt)], N=2, sharecam=False, axes=True)

# if we wanted to take a bunch of parallel slices, like for a 3D printer
# we can do that easily with the section_multiplane method
# we're going to slice the mesh into evenly spaced chunks along z
# this takes the (2,3) bounding box and slices it into [minz, maxz]
z_extents = mesh.bounds[:, 2]
# slice every .125 model units (eg, inches)
z_levels = np.arange(*z_extents, step=0.125)

# find a bunch of parallel cross sections
sections = mesh.section_multiplane(plane_origin=mesh.bounds[0],
                                   plane_normal=[0, 0, 1],
Exemplo n.º 5
0
"""Forward kinematics: hover the mouse to drag the chain"""
from vedo import Plotter, versor, Plane, Line

n = 15  # number of points
l = 3  # length of one segment


def move(evt):
    if not evt.actor:
        return
    coords = line.points()
    coords[0] = evt.picked3d
    for i in range(1, n):
        v = versor(coords[i] - coords[i - 1])
        coords[i] = coords[i - 1] + v * l
    line.points(coords)  # update positions
    nodes.points(coords)
    plt.render()


plt = Plotter()
plt.addCallback("mouse move", move)

surf = Plane(sx=60, sy=60)
line = Line([l * n / 2, 0], [-l * n / 2, 0], res=n, lw=12)
nodes = line.clone().c('red3').pointSize(15)

plt.show(surf, line, nodes, __doc__, zoom=1.3).close()