Module fnpcell.geometry.cosine_bend

Functions

new_cosine_bend

def new_cosine_bend(*, radius_min: float, radians: Optional[float] = None,
                    degrees: Optional[float] = None, p: Optional[float] = None,
                    l_max: Optional[float] = None, angle_step: Optional[float] = None,
                    origin: Optional[Tuple[float, float]] = None,
                    transform: Affine2D = Affine2D.identity()) -> CosineBend

Create a CosineBend curve.

:param degrees central angle in degrees :param radius_min radius minimum :param radius_eff radius effective choose either radius_min(imum) or radius_eff(ective) :param p radio of cosine spiral in whole bend, 0 < p <= 1, when p = 1, there’s no cirular part in the bend :param l_max max length of cosine spiral in half bend, l_max is paired with radius_min choose either p or l_max, if both absent, p = 1 is assumed.

Classes

CosineBend

class CosineBend(radius_min: float, central_angle: float, l_max: float, angle_step: float,
                    transform: Affine2D = Affine2D.identity())

CosineBend(args: Any, *kwargs: Any)

Ancestors

HybridBend, TransformMixin, IUpdatable, CurveMixin, ICurve, ICurveLike, IAffineTransformable

Class variables

var angle_step: float
var central_angle: float
var l_max: float
var radius_min: float
var transform: Affine2D

Static methods

def transform_from_at(at: Union[None, Tuple[float, float], IPositioned, IRay] = None,
                        transform: Affine2D = Affine2D.identity()) -> Affine2D

Inherited from: HybridBend.transform_from_at

Returns an Affine2D that is the result of the matrix product of the given transformation and the translation transformation at the given origin, the …

def transform_from_origin(origin: Optional[Tuple[float, float]] = None,
                            transform: Affine2D = Affine2D.identity()) -> Affine2D

Inherited from: HybridBend.transform_from_origin

Returns an Affine2D that is the result of the matrix product of the given transformation and the translation transformation at the given origin, It …

Methods

def c_mirrored(self: ~_Self, *, center: Tuple[float, float] = (0, 0)) -> ~_Self

Inherited from: HybridBend.c_mirrored

Center mirrored.

def curve_curvatures(self, target: float, n: int)

def h_mirrored(self: ~_Self, *, x: float = 0) -> ~_Self

Inherited from: HybridBend.h_mirrored

Horizontal mirrored.

def rotated(self: ~_Self, *, degrees: Optional[float] = None,
            radians: Optional[float] = None, origin: Optional[Tuple[float, float]] = None,
            inplace: Optional[bool] = None) -> ~_Self

Inherited from: HybridBend.rotated

Return a new cell reference rotated, either degrees or radians must be provided. If both provided, radians is used …

def sample_at(self, length: float) -> SampleInfo

Inherited from: HybridBend.sample_at

return sample info at length.

def scaled(self: ~_Self, sx: float, sy: Optional[float] = None, *,
            center: Tuple[float, float] = (0, 0)) -> ~_Self

Inherited from: HybridBend.scaled

scaled at center.

def split_at(self, length: float) -> Tuple[ICurve, ICurve]

Inherited from: HybridBend.split_at

return two subcurve at length, if length < 0, abs(length) from end

def subcurve(self, start: float, end: float) -> ICurve

Inherited from: HybridBend.subcurve

return a subcurve between start and end …

def transform_combined(self, transform: Affine2D)

Inherited from: HybridBend.transform_combined

Returns an Affine2D that is the result of the matrix product with the given transformation. It means that the original image can be transformed by a …

def translated(self: ~_Self, tx: float, ty: float) -> ~_Self

Inherited from: HybridBend.translated

Translated.

def v_mirrored(self: ~_Self, *, y: float = 0) -> ~_Self

Inherited from: HybridBend.v_mirrored

Vertical mirrored.