OCCRevolutionSurface

class compas_occ.geometry.OCCRevolutionSurface(*args, **kwargs)

Bases: OCCSurface

Class representing a surface of revolution based on the corresponding surface of the OCC kernel.

Parameters:

curvecompas_occ.geometry.OCCCurve: The base curve for the revolution. The curve should be planar.
pointcompas.geometry.Point: The location of the axis of revolution.
vectorcompas.geometry.Vector: The direction of the axis of revolution.

Examples

>>>

Attributes:

curvecompas_occ.geometry.OCCCurve: The base curve for the revolution.
pointcompas.geometry.Point: The location of the axis of revolution.
vectorcompas.geometry.Vector: The direction of the axis of revolution.

Methods

compute

Compute the surface of revolution using the current curve and axis.

Inherited Methods

`ToString`	Converts the instance to a string.
`aabb`	Compute the axis aligned bounding box of the surface.
`boundary`	Compute the boundary curves of the surface.
`closest_point`	Compute the closest point on the curve to a given point.
`compute_aabb`	Compute the axis-aligned bounding box of the geometry.
`compute_obb`	Compute the oriented bounding box of the geometry.
`copy`	Make an independent copy of the current surface.
`curvature_at`	Compute the curvature at a point on the surface.
`frame_at`	Compute the local frame at a point on the curve.
`from_face`	Construct surface from an existing OCC TopoDS_Face.
`from_json`	Construct an object of this type from a JSON file.
`from_jsonstring`	Construct an object of this type from a JSON string.
`from_obj`	Load a surface from an OBJ file.
`from_occ`	Construct a NUBRS surface from an existing OCC BSplineSurface.
`from_plane`	Construct a surface from a plane.
`from_step`	Load a surface from a STP file.
`gaussian_curvature_at`	Compute the Gaussian curvature at a point on the surface.
`intersections_with_curve`	Compute the intersections with a curve.
`intersections_with_line`	Compute the intersections with a line.
`intersections_with_plane`	Compute the intersections with a plane.
`isocurve_u`	Compute the isoparametric curve at parameter u.
`isocurve_v`	Compute the isoparametric curve at parameter v.
`mean_curvature_at`	Compute the mean curvature at a point on the surface.
`normal_at`	Compute a normal at a point on the surface.
`obb`	Compute the oriented bounding box of the surface.
`point_at`	Compute a point on the surface.
`pointgrid`	Compute point locations corresponding to evenly spaced parameters over the surface domain.
`rotate`	Rotate the geometry.
`rotated`	Returns a rotated copy of this geometry.
`scale`	Scale the geometry.
`scaled`	Returns a scaled copy of this geometry.
`sha256`	Compute a hash of the data for comparison during version control using the sha256 algorithm.
`space_u`	Compute evenly spaced parameters over the surface domain in the U direction.
`space_v`	Compute evenly spaced parameters over the surface domain in the V direction.
`to_brep`	Convert the surface to a BREP representation.
`to_json`	Convert an object to its native data representation and save it to a JSON file.
`to_jsonstring`	Convert an object to its native data representation and save it to a JSON string.
`to_mesh`	Convert the surface to a mesh.
`to_polyhedron`	Convert the surface to a polyhedron.
`to_quads`	Convert the surface to a list of quads.
`to_step`	Write the surface geometry to a STP file.
`to_tesselation`	Convert the surface to a triangle mesh.
`to_triangles`	Convert the surface to a list of triangles.
`to_vertices_and_faces`	Convert the surface to a list of vertices and faces.
`transform`	Transform this surface.
`transformed`	Returns a transformed copy of this geometry.
`translate`	Translate the geometry.
`translated`	Returns a translated copy of this geometry.
`validate_data`	Validate the data against the object's data schema.