gp_Ax1 Class Reference

Describes an axis in 3D space. An axis is defined by: More...

#include <gp_Ax1.hxx>

Public Member Functions
	gp_Ax1 ()
	Creates an axis object representing Z axis of the reference co-ordinate system. More...
	gp_Ax1 (const gp_Pnt &P, const gp_Dir &V)
	P is the location point and V is the direction of <me>. More...
void	SetDirection (const gp_Dir &V)
	Assigns V as the "Direction" of this axis. More...
void	SetLocation (const gp_Pnt &P)
	Assigns P as the origin of this axis. More...
const gp_Dir &	Direction () const
	Returns the direction of <me>. More...
const gp_Pnt &	Location () const
	Returns the location point of <me>. More...
Standard_Boolean	IsCoaxial (const gp_Ax1 &Other, const Standard_Real AngularTolerance, const Standard_Real LinearTolerance) const
	Returns True if : . the angle between <me> and <Other> is lower or equal to <AngularTolerance> and . the distance between <me>.Location() and <Other> is lower or equal to <LinearTolerance> and . the distance between <Other>.Location() and <me> is lower or equal to LinearTolerance. More...
Standard_Boolean	IsNormal (const gp_Ax1 &Other, const Standard_Real AngularTolerance) const
	Returns True if the direction of the <me> and <Other> are normal to each other. That is, if the angle between the two axes is equal to Pi/2. Note: the tolerance criterion is given by AngularTolerance.. More...
Standard_Boolean	IsOpposite (const gp_Ax1 &Other, const Standard_Real AngularTolerance) const
	Returns True if the direction of <me> and <Other> are parallel with opposite orientation. That is, if the angle between the two axes is equal to Pi. Note: the tolerance criterion is given by AngularTolerance. More...
Standard_Boolean	IsParallel (const gp_Ax1 &Other, const Standard_Real AngularTolerance) const
	Returns True if the direction of <me> and <Other> are parallel with same orientation or opposite orientation. That is, if the angle between the two axes is equal to 0 or Pi. Note: the tolerance criterion is given by AngularTolerance. More...
Standard_Real	Angle (const gp_Ax1 &Other) const
	Computes the angular value, in radians, between <me>.Direction() and <Other>.Direction(). Returns the angle between 0 and 2*PI radians. More...
void	Reverse ()
	Reverses the unit vector of this axis. and assigns the result to this axis. More...
gp_Ax1	Reversed () const
	Reverses the unit vector of this axis and creates a new one. More...
void	Mirror (const gp_Pnt &P)
	Performs the symmetrical transformation of an axis placement with respect to the point P which is the center of the symmetry and assigns the result to this axis. More...
gp_Ax1	Mirrored (const gp_Pnt &P) const
	Performs the symmetrical transformation of an axis placement with respect to the point P which is the center of the symmetry and creates a new axis. More...
void	Mirror (const gp_Ax1 &A1)
	Performs the symmetrical transformation of an axis placement with respect to an axis placement which is the axis of the symmetry and assigns the result to this axis. More...
gp_Ax1	Mirrored (const gp_Ax1 &A1) const
	Performs the symmetrical transformation of an axis placement with respect to an axis placement which is the axis of the symmetry and creates a new axis. More...
void	Mirror (const gp_Ax2 &A2)
	Performs the symmetrical transformation of an axis placement with respect to a plane. The axis placement <A2> locates the plane of the symmetry : (Location, XDirection, YDirection) and assigns the result to this axis. More...
gp_Ax1	Mirrored (const gp_Ax2 &A2) const
	Performs the symmetrical transformation of an axis placement with respect to a plane. The axis placement <A2> locates the plane of the symmetry : (Location, XDirection, YDirection) and creates a new axis. More...
void	Rotate (const gp_Ax1 &A1, const Standard_Real Ang)
	Rotates this axis at an angle Ang (in radians) about the axis A1 and assigns the result to this axis. More...
gp_Ax1	Rotated (const gp_Ax1 &A1, const Standard_Real Ang) const
	Rotates this axis at an angle Ang (in radians) about the axis A1 and creates a new one. More...
void	Scale (const gp_Pnt &P, const Standard_Real S)
	Applies a scaling transformation to this axis with: More...
gp_Ax1	Scaled (const gp_Pnt &P, const Standard_Real S) const
	Applies a scaling transformation to this axis with: More...
void	Transform (const gp_Trsf &T)
	Applies the transformation T to this axis. and assigns the result to this axis. More...
gp_Ax1	Transformed (const gp_Trsf &T) const
	Applies the transformation T to this axis and creates a new one. More...
void	Translate (const gp_Vec &V)
	Translates this axis by the vector V, and assigns the result to this axis. More...
gp_Ax1	Translated (const gp_Vec &V) const
	Translates this axis by the vector V, and creates a new one. More...
void	Translate (const gp_Pnt &P1, const gp_Pnt &P2)
	Translates this axis by: the vector (P1, P2) defined from point P1 to point P2. and assigns the result to this axis. More...
gp_Ax1	Translated (const gp_Pnt &P1, const gp_Pnt &P2) const
	Translates this axis by: the vector (P1, P2) defined from point P1 to point P2. and creates a new one. More...

Detailed Description

Describes an axis in 3D space. An axis is defined by:

• its origin (also referred to as its "Location point"), and
• its unit vector (referred to as its "Direction" or "main Direction"). An axis is used:
• to describe 3D geometric entities (for example, the axis of a revolution entity). It serves the same purpose as the STEP function "axis placement one axis", or
• to define geometric transformations (axis of symmetry, axis of rotation, and so on). For example, this entity can be used to locate a geometric entity or to define a symmetry axis.

Constructor & Destructor Documentation

gp_Ax1() [1/2]

gp_Ax1::gp_Ax1

(

)

Creates an axis object representing Z axis of the reference co-ordinate system.

gp_Ax1() [2/2]

gp_Ax1::gp_Ax1	(	const gp_Pnt &	P,
		const gp_Dir &	V
	)

P is the location point and V is the direction of <me>.

Member Function Documentation

Angle()

Standard_Real gp_Ax1::Angle

(

const gp_Ax1 &

Other

)

const

Computes the angular value, in radians, between <me>.Direction() and <Other>.Direction(). Returns the angle between 0 and 2*PI radians.

Direction()

const gp_Dir& gp_Ax1::Direction

(

)

const

Returns the direction of <me>.

IsCoaxial()

Standard_Boolean gp_Ax1::IsCoaxial	(	const gp_Ax1 &	Other,
		const Standard_Real	AngularTolerance,
		const Standard_Real	LinearTolerance
	)		const

Returns True if : . the angle between <me> and <Other> is lower or equal to <AngularTolerance> and . the distance between <me>.Location() and <Other> is lower or equal to <LinearTolerance> and . the distance between <Other>.Location() and <me> is lower or equal to LinearTolerance.

IsNormal()

Standard_Boolean gp_Ax1::IsNormal	(	const gp_Ax1 &	Other,
		const Standard_Real	AngularTolerance
	)		const

Returns True if the direction of the <me> and <Other> are normal to each other. That is, if the angle between the two axes is equal to Pi/2. Note: the tolerance criterion is given by AngularTolerance..

IsOpposite()

Standard_Boolean gp_Ax1::IsOpposite	(	const gp_Ax1 &	Other,
		const Standard_Real	AngularTolerance
	)		const

Returns True if the direction of <me> and <Other> are parallel with opposite orientation. That is, if the angle between the two axes is equal to Pi. Note: the tolerance criterion is given by AngularTolerance.

IsParallel()

Standard_Boolean gp_Ax1::IsParallel	(	const gp_Ax1 &	Other,
		const Standard_Real	AngularTolerance
	)		const

Returns True if the direction of <me> and <Other> are parallel with same orientation or opposite orientation. That is, if the angle between the two axes is equal to 0 or Pi. Note: the tolerance criterion is given by AngularTolerance.

Location()

const gp_Pnt& gp_Ax1::Location

(

)

const

Returns the location point of <me>.

Mirror() [1/3]

void gp_Ax1::Mirror

(

const gp_Pnt &

P

)

Performs the symmetrical transformation of an axis placement with respect to the point P which is the center of the symmetry and assigns the result to this axis.

Mirror() [2/3]

void gp_Ax1::Mirror

(

const gp_Ax1 &

A1

)

Performs the symmetrical transformation of an axis placement with respect to an axis placement which is the axis of the symmetry and assigns the result to this axis.

Mirror() [3/3]

void gp_Ax1::Mirror

(

const gp_Ax2 &

A2

)

Performs the symmetrical transformation of an axis placement with respect to a plane. The axis placement <A2> locates the plane of the symmetry : (Location, XDirection, YDirection) and assigns the result to this axis.

Mirrored() [1/3]

gp_Ax1 gp_Ax1::Mirrored

(

const gp_Pnt &

P

)

const

Performs the symmetrical transformation of an axis placement with respect to the point P which is the center of the symmetry and creates a new axis.

Mirrored() [2/3]

gp_Ax1 gp_Ax1::Mirrored

(

const gp_Ax1 &

A1

)

const

Performs the symmetrical transformation of an axis placement with respect to an axis placement which is the axis of the symmetry and creates a new axis.

Mirrored() [3/3]

gp_Ax1 gp_Ax1::Mirrored

(

const gp_Ax2 &

A2

)

const

Performs the symmetrical transformation of an axis placement with respect to a plane. The axis placement <A2> locates the plane of the symmetry : (Location, XDirection, YDirection) and creates a new axis.

Reverse()

void gp_Ax1::Reverse

(

)

Reverses the unit vector of this axis. and assigns the result to this axis.

Reversed()

gp_Ax1 gp_Ax1::Reversed

(

)

const

Reverses the unit vector of this axis and creates a new one.

Rotate()

void gp_Ax1::Rotate	(	const gp_Ax1 &	A1,
		const Standard_Real	Ang
	)

Rotates this axis at an angle Ang (in radians) about the axis A1 and assigns the result to this axis.

Rotated()

gp_Ax1 gp_Ax1::Rotated	(	const gp_Ax1 &	A1,
		const Standard_Real	Ang
	)		const

Rotates this axis at an angle Ang (in radians) about the axis A1 and creates a new one.

Scale()

void gp_Ax1::Scale	(	const gp_Pnt &	P,
		const Standard_Real	S
	)

Applies a scaling transformation to this axis with:

• scale factor S, and
• center P and assigns the result to this axis.

Scaled()

gp_Ax1 gp_Ax1::Scaled	(	const gp_Pnt &	P,
		const Standard_Real	S
	)		const

Applies a scaling transformation to this axis with:

• scale factor S, and
• center P and creates a new axis.

SetDirection()

void gp_Ax1::SetDirection

(

const gp_Dir &

V

)

Assigns V as the "Direction" of this axis.

SetLocation()

void gp_Ax1::SetLocation

(

const gp_Pnt &

P

)

Assigns P as the origin of this axis.

Transform()

void gp_Ax1::Transform

(

const gp_Trsf &

T

)

Applies the transformation T to this axis. and assigns the result to this axis.

Transformed()

gp_Ax1 gp_Ax1::Transformed

(

const gp_Trsf &

T

)

const

Applies the transformation T to this axis and creates a new one.

Translates an axis plaxement in the direction of the vector <V>. The magnitude of the translation is the vector's magnitude.

Translate() [1/2]

void gp_Ax1::Translate

(

const gp_Vec &

V

)

Translates this axis by the vector V, and assigns the result to this axis.

Translate() [2/2]

void gp_Ax1::Translate	(	const gp_Pnt &	P1,
		const gp_Pnt &	P2
	)

Translates this axis by: the vector (P1, P2) defined from point P1 to point P2. and assigns the result to this axis.

Translated() [1/2]

gp_Ax1 gp_Ax1::Translated

(

const gp_Vec &

V

)

const

Translates this axis by the vector V, and creates a new one.

Translated() [2/2]

gp_Ax1 gp_Ax1::Translated	(	const gp_Pnt &	P1,
		const gp_Pnt &	P2
	)		const

Translates this axis by: the vector (P1, P2) defined from point P1 to point P2. and creates a new one.

---

The documentation for this class was generated from the following file:

• gp_Ax1.hxx