Uses of Class org.hipparchus.geometry.euclidean.threed.FieldVector3D (Hipparchus 2.3 API)

Packages that use FieldVector3D
Package Description

org.hipparchus.geometry.euclidean.threed
This package provides basic 3D geometry components.

Packages that use FieldVector3D
Package	Description
org.hipparchus.geometry.euclidean.threed	This package provides basic 3D geometry components.

Uses of FieldVector3D in org.hipparchus.geometry.euclidean.threed

Methods in org.hipparchus.geometry.euclidean.threed that return FieldVector3D
Modifier and Type	Method and Description
`FieldVector3D<T>`	FieldVector3D.`add(double factor, FieldVector3D<T> v)` Add a scaled vector to the instance.
`FieldVector3D<T>`	FieldVector3D.`add(double factor, Vector3D v)` Add a scaled vector to the instance.
`FieldVector3D<T>`	FieldVector3D.`add(FieldVector3D<T> v)` Add a vector to the instance.
`FieldVector3D<T>`	FieldVector3D.`add(T factor, FieldVector3D<T> v)` Add a scaled vector to the instance.
`FieldVector3D<T>`	FieldVector3D.`add(T factor, Vector3D v)` Add a scaled vector to the instance.
`FieldVector3D<T>`	FieldVector3D.`add(Vector3D v)` Add a vector to the instance.
`FieldVector3D<T>`	FieldRotation.`applyInverseTo(FieldVector3D<T> u)` Apply the inverse of the rotation to a vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldRotation.`applyInverseTo(Rotation r, FieldVector3D<T> u)` Apply the inverse of a rotation to a vector.
`FieldVector3D<T>`	FieldRotation.`applyInverseTo(Vector3D u)` Apply the inverse of the rotation to a vector.
`FieldVector3D<T>`	FieldRotation.`applyTo(FieldVector3D<T> u)` Apply the rotation to a vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldRotation.`applyTo(Rotation r, FieldVector3D<T> u)` Apply a rotation to a vector.
`FieldVector3D<T>`	FieldRotation.`applyTo(Vector3D u)` Apply the rotation to a vector.
`FieldVector3D<T>`	FieldLine.`closestPoint(FieldLine<T> line)` Compute the point of the instance closest to another line.
`FieldVector3D<T>`	FieldVector3D.`crossProduct(FieldVector3D<T> v)` Compute the cross-product of the instance with another vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`crossProduct(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the cross-product of two vectors.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`crossProduct(FieldVector3D<T> v1, Vector3D v2)` Compute the cross-product of two vectors.
`FieldVector3D<T>`	FieldVector3D.`crossProduct(Vector3D v)` Compute the cross-product of the instance with another vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`crossProduct(Vector3D v1, FieldVector3D<T> v2)` Compute the cross-product of two vectors.
`FieldVector3D<T>`	FieldRotation.`getAxis(RotationConvention convention)` Get the normalized axis of the rotation.
`FieldVector3D<T>`	FieldLine.`getDirection()` Get the normalized direction vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getMinusI(Field<T> field)` Get opposite of the first canonical vector (coordinates: -1, 0, 0).
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getMinusJ(Field<T> field)` Get opposite of the second canonical vector (coordinates: 0, -1, 0).
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getMinusK(Field<T> field)` Get opposite of the third canonical vector (coordinates: 0, 0, -1).
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getNaN(Field<T> field)` Get a vector with all coordinates set to NaN.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getNegativeInfinity(Field<T> field)` Get a vector with all coordinates set to negative infinity.
`FieldVector3D<T>`	FieldLine.`getOrigin()` Get the line point closest to the origin.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getPlusI(Field<T> field)` Get first canonical vector (coordinates: 1, 0, 0).
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getPlusJ(Field<T> field)` Get second canonical vector (coordinates: 0, 1, 0).
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getPlusK(Field<T> field)` Get third canonical vector (coordinates: 0, 0, 1).
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getPositiveInfinity(Field<T> field)` Get a vector with all coordinates set to positive infinity.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`getZero(Field<T> field)` Get null vector (coordinates: 0, 0, 0).
`FieldVector3D<T>`	FieldLine.`intersection(FieldLine<T> line)` Get the intersection point of the instance and another line.
`FieldVector3D<T>`	FieldVector3D.`negate()` Get the opposite of the instance.
`FieldVector3D<T>`	FieldVector3D.`normalize()` Get a normalized vector aligned with the instance.
`FieldVector3D<T>`	FieldVector3D.`orthogonal()` Get a vector orthogonal to the instance.
`FieldVector3D<T>`	FieldLine.`pointAt(double abscissa)` Get one point from the line.
`FieldVector3D<T>`	FieldLine.`pointAt(T abscissa)` Get one point from the line.
`FieldVector3D<T>`	FieldVector3D.`scalarMultiply(double a)` Multiply the instance by a scalar.
`FieldVector3D<T>`	FieldVector3D.`scalarMultiply(T a)` Multiply the instance by a scalar.
`FieldVector3D<T>`	FieldVector3D.`subtract(double factor, FieldVector3D<T> v)` Subtract a scaled vector from the instance.
`FieldVector3D<T>`	FieldVector3D.`subtract(double factor, Vector3D v)` Subtract a scaled vector from the instance.
`FieldVector3D<T>`	FieldVector3D.`subtract(FieldVector3D<T> v)` Subtract a vector from the instance.
`FieldVector3D<T>`	FieldVector3D.`subtract(T factor, FieldVector3D<T> v)` Subtract a scaled vector from the instance.
`FieldVector3D<T>`	FieldVector3D.`subtract(T factor, Vector3D v)` Subtract a scaled vector from the instance.
`FieldVector3D<T>`	FieldVector3D.`subtract(Vector3D v)` Subtract a vector from the instance.

Methods in org.hipparchus.geometry.euclidean.threed with parameters of type FieldVector3D
Modifier and Type	Method and Description
`FieldVector3D<T>`	FieldVector3D.`add(double factor, FieldVector3D<T> v)` Add a scaled vector to the instance.
`FieldVector3D<T>`	FieldVector3D.`add(FieldVector3D<T> v)` Add a vector to the instance.
`FieldVector3D<T>`	FieldVector3D.`add(T factor, FieldVector3D<T> v)` Add a scaled vector to the instance.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`angle(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the angular separation between two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`angle(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the angular separation between two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`angle(FieldVector3D<T> v1, Vector3D v2)` Compute the angular separation between two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`angle(Vector3D v1, FieldVector3D<T> v2)` Compute the angular separation between two vectors.
`FieldVector3D<T>`	FieldRotation.`applyInverseTo(FieldVector3D<T> u)` Apply the inverse of the rotation to a vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldRotation.`applyInverseTo(Rotation r, FieldVector3D<T> u)` Apply the inverse of a rotation to a vector.
`FieldVector3D<T>`	FieldRotation.`applyTo(FieldVector3D<T> u)` Apply the rotation to a vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldRotation.`applyTo(Rotation r, FieldVector3D<T> u)` Apply a rotation to a vector.
`boolean`	FieldLine.`contains(FieldVector3D<T> p)` Check if the instance contains a point.
`FieldVector3D<T>`	FieldVector3D.`crossProduct(FieldVector3D<T> v)` Compute the cross-product of the instance with another vector.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`crossProduct(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the cross-product of two vectors.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`crossProduct(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the cross-product of two vectors.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`crossProduct(FieldVector3D<T> v1, Vector3D v2)` Compute the cross-product of two vectors.
`static <T extends CalculusFieldElement<T>> FieldVector3D<T>`	FieldVector3D.`crossProduct(Vector3D v1, FieldVector3D<T> v2)` Compute the cross-product of two vectors.
`T`	FieldLine.`distance(FieldVector3D<T> p)` Compute the distance between the instance and a point.
`T`	FieldVector3D.`distance(FieldVector3D<T> v)` Compute the distance between the instance and another vector according to the L₂ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L₂ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L₂ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance(FieldVector3D<T> v1, Vector3D v2)` Compute the distance between two vectors according to the L₂ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance(Vector3D v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L₂ norm.
`T`	FieldVector3D.`distance1(FieldVector3D<T> v)` Compute the distance between the instance and another vector according to the L₁ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance1(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L₁ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance1(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L₁ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance1(FieldVector3D<T> v1, Vector3D v2)` Compute the distance between two vectors according to the L₁ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distance1(Vector3D v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L₁ norm.
`T`	FieldVector3D.`distanceInf(FieldVector3D<T> v)` Compute the distance between the instance and another vector according to the L_∞ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceInf(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L_∞ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceInf(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L_∞ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceInf(FieldVector3D<T> v1, Vector3D v2)` Compute the distance between two vectors according to the L_∞ norm.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceInf(Vector3D v1, FieldVector3D<T> v2)` Compute the distance between two vectors according to the L_∞ norm.
`T`	FieldVector3D.`distanceSq(FieldVector3D<T> v)` Compute the square of the distance between the instance and another vector.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceSq(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the square of the distance between two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceSq(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the square of the distance between two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceSq(FieldVector3D<T> v1, Vector3D v2)` Compute the square of the distance between two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`distanceSq(Vector3D v1, FieldVector3D<T> v2)` Compute the square of the distance between two vectors.
`T`	FieldVector3D.`dotProduct(FieldVector3D<T> v)` Compute the dot-product of the instance and another vector.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`dotProduct(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the dot-product of two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`dotProduct(FieldVector3D<T> v1, FieldVector3D<T> v2)` Compute the dot-product of two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`dotProduct(FieldVector3D<T> v1, Vector3D v2)` Compute the dot-product of two vectors.
`static <T extends CalculusFieldElement<T>> T`	FieldVector3D.`dotProduct(Vector3D v1, FieldVector3D<T> v2)` Compute the dot-product of two vectors.
`T`	FieldLine.`getAbscissa(FieldVector3D<T> point)` Get the abscissa of a point with respect to the line.
`void`	FieldLine.`reset(FieldVector3D<T> p1, FieldVector3D<T> p2)` Reset the instance as if built from two points.
`void`	FieldLine.`reset(FieldVector3D<T> p1, FieldVector3D<T> p2)` Reset the instance as if built from two points.
`FieldVector3D<T>`	FieldVector3D.`subtract(double factor, FieldVector3D<T> v)` Subtract a scaled vector from the instance.
`FieldVector3D<T>`	FieldVector3D.`subtract(FieldVector3D<T> v)` Subtract a vector from the instance.
`FieldVector3D<T>`	FieldVector3D.`subtract(T factor, FieldVector3D<T> v)` Subtract a scaled vector from the instance.

Constructors in org.hipparchus.geometry.euclidean.threed with parameters of type FieldVector3D
Constructor and Description
`FieldLine(FieldVector3D<T> p1, FieldVector3D<T> p2, double tolerance)` Build a line from two points.
`FieldLine(FieldVector3D<T> p1, FieldVector3D<T> p2, double tolerance)` Build a line from two points.
`FieldRotation(FieldVector3D<T> u, FieldVector3D<T> v)` Build one of the rotations that transform one vector into another one.
`FieldRotation(FieldVector3D<T> u, FieldVector3D<T> v)` Build one of the rotations that transform one vector into another one.
`FieldRotation(FieldVector3D<T> u1, FieldVector3D<T> u2, FieldVector3D<T> v1, FieldVector3D<T> v2)` Build the rotation that transforms a pair of vectors into another pair.
`FieldRotation(FieldVector3D<T> u1, FieldVector3D<T> u2, FieldVector3D<T> v1, FieldVector3D<T> v2)` Build the rotation that transforms a pair of vectors into another pair.
`FieldRotation(FieldVector3D<T> u1, FieldVector3D<T> u2, FieldVector3D<T> v1, FieldVector3D<T> v2)` Build the rotation that transforms a pair of vectors into another pair.
`FieldRotation(FieldVector3D<T> u1, FieldVector3D<T> u2, FieldVector3D<T> v1, FieldVector3D<T> v2)` Build the rotation that transforms a pair of vectors into another pair.
`FieldRotation(FieldVector3D<T> axis, T angle, RotationConvention convention)` Build a rotation from an axis and an angle.
`FieldVector3D(double a, FieldVector3D<T> u)` Multiplicative constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2, double a3, FieldVector3D<T> u3)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2, double a3, FieldVector3D<T> u3)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2, double a3, FieldVector3D<T> u3)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2, double a3, FieldVector3D<T> u3, double a4, FieldVector3D<T> u4)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2, double a3, FieldVector3D<T> u3, double a4, FieldVector3D<T> u4)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2, double a3, FieldVector3D<T> u3, double a4, FieldVector3D<T> u4)` Linear constructor.
`FieldVector3D(double a1, FieldVector3D<T> u1, double a2, FieldVector3D<T> u2, double a3, FieldVector3D<T> u3, double a4, FieldVector3D<T> u4)` Linear constructor.
`FieldVector3D(T a, FieldVector3D<T> u)` Multiplicative constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2, T a3, FieldVector3D<T> u3)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2, T a3, FieldVector3D<T> u3)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2, T a3, FieldVector3D<T> u3)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2, T a3, FieldVector3D<T> u3, T a4, FieldVector3D<T> u4)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2, T a3, FieldVector3D<T> u3, T a4, FieldVector3D<T> u4)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2, T a3, FieldVector3D<T> u3, T a4, FieldVector3D<T> u4)` Linear constructor.
`FieldVector3D(T a1, FieldVector3D<T> u1, T a2, FieldVector3D<T> u2, T a3, FieldVector3D<T> u3, T a4, FieldVector3D<T> u4)` Linear constructor.

Uses of Classorg.hipparchus.geometry.euclidean.threed.FieldVector3D

Uses of FieldVector3D in org.hipparchus.geometry.euclidean.threed

Uses of Class
org.hipparchus.geometry.euclidean.threed.FieldVector3D