# Oolite JavaScript Reference: Vector3D

**Prototype:** `Object`

**Subtypes:** none

The ** Vector3D** class represents a geometrical vector in three-dimensional space, in cartesian representation. It is used to represent positions, headings and velocities. Explaining vector geometry is beyond the scope of this document, but there are numerous tutorials on the web.

### Vector Expressions

All Oolite-provided functions which take a vector as an argument may instead be passed an array of three numbers, or an Entity (in which case the entity’s `position`

is used). In specifications, this is represented by arguments typed `vectorExpression`

. For example, if `a`

and `b`

are vectors whose values are (0, 1, 0) and (1, 0, 0) respectively, the following are equivalent:

var c = a.add(b); var d = a.add(Vector3D(1, 0, 0)); var e = a.add([1, 0, 0]); // c, d and e are now all (1, 1, 0).

## Properties

`x`

x: Number (read/write)

The *x* co-ordinate of the vector.

`y`

y: Number (read/write)

The *y* co-ordinate of the vector.

`z`

z: Number (read/write)

The *z* co-ordinate of the vector.

## Methods

### Constructor

new Vector3D([value : vectorExpression]) : Vector3D

Create a new vector with the specified value. If no value is provided, the vector is initialized to (0, 0, 0).

`add`

functionadd(v : vectorExpression) : Vector3D

Returns the vector sum of the target and `v`

.

**See Also:** `subtract()`

`angleTo`

functionangleTo(v : vectorExpression) : Number

Returns the angle (in radians) between the target and `vectorExpression`

. This is always a positive value between 0 and π.

`v.angleTo(u)`

is equivalent to `Math.acos(v.direction().dot(u.direction()))`

.

`cross`

functioncross(v : vectorExpression) : Vector3D

Returns the cross product of the target and `vectorExpression`

.

**See Also:** `dot()`

`direction`

functiondirection() : Vector3D

Returns the unit vector with the same direction as the target.

`v.direction()`

is equivalent to `v.multiply(1 / v.magnitude())`

.

**See Also:** `magnitude()`

`distanceTo`

functiondistanceTo(v : vectorExpression) : Number

Returns the distance between the source vector and `v`

. If `v`

is not a vector, then if it is an Entity its position will be used; and if it is an array of three values (for example, `[x, y, z]`

or `[1, 2, 3]`

), it will be treated as a vector with those coordinates.

`u.distanceTo(v)`

is equivalent to `u.subtract(v).magnitude()`

.

**CAUTION:** If passed an invalid `v`

, the method will return zero, not log an error. It is also incorrect to call `distanceTo`

on something that is not a vector. For example: `this.ship.distanceTo(v)`

is missing `position`

and needs to be written as `this.ship.position.distanceTo(v)`

.

**See Also:** `squaredDistanceTo()`

`dot`

functiondot(v : vectorExpression) : Number

Returns the dot product of the target and `v`

.

The dot product of two vectors says something how well they are aligned to each other. The dot product of two identical vectors is 1 while two vectors pointing in opposite direction result in a -1 result. Also you can't reliably compare two vectors with each other to see if they are identical. To check if `vector1 == vector2`

you need the dot product :

vector1.dot(vector2) > 0.999

**See Also:** `cross()`

`fromCoordinateSystem`

functionfromCoordinateSystem(system : String) : Vector3D

Convert a vector from an abstract coordinate system to absolute coordinates. `system`

must be a three-letter string specifying an abstract coordinate system.

**Important:**
Vectors do not “know” which coordinate system they’re in. The script must keep track of that. If you add together vectors in different coordinate systems the result will be nonsense, just as if you added measurements in different units without appropriate conversions.

**Example:**

this.halfway = Vector3D(0, 0, 0.5).fromCoordinateSystem("wpu"); // Equivalent: Vector3D.interpolate([0, 0, 0], S.mainPlanet, 0.5)

**See Also:** `toCoordinateSystem()`

`magnitude`

functionmagnitude() : Number

Returns the magnitude (or length) of the vector.

**See Also:** `squaredMagnitude()`

, `direction()`

`multiply`

functionmultiply(f : Number) : Vector3D

Returns the product of the target and `f`

. This has the effect of scaling the vector by the factor `f`

.

`rotateBy`

functionrotateBy(q : quaternionExpression) : Vector3D

Apply the rotation specified by `q`

to the target vector.

`rotationTo`

functionrotationTo(v : vectorExpression [, maxArc : Number]) : Quaternion

Returns a quaternion corresponding to a rotation from the target vector to `v`

. The optional parameter `maxArc`

specifies a maximum rotation angle; if the angle between the target and `v`

is greater than `maxArc`

radians, a rotation of `maxArc`

radians towards `vectorExpression`

is generated instead.

Both the target and `v`

must be normalized. The vectors must not be antiparallel (180° apart), since the axis of rotation is undefined in this case.

**Example:**

var orientation = myVector.rotationTo([0, 0, 1])

This will generate a quaternion were the `forwardVector`

is pointing in the same direction as `myVector`

. (`[0, 0, 1]`

is equal to the `forwardVector`

of the identity quaternion.)

`squaredDistanceTo`

functionsquaredDistanceTo(v: vectorExpression) : Number

Returns the square of the distance between the source vector and vector `v`

. If `v`

is not a vector, then if it is an Entity its position will be used; and if it is an array of three values (for example, `[x, y, z]`

or `[1, 2, 3]`

), it will be treated as a vector with those coordinates.

`u.squaredDistanceTo(v)`

is equivalent to `u.distanceTo(v) * u.distanceTo(v)`

, or `u.subtract(v).squaredMagnitude()`

.

**CAUTION:** If passed an invalid `v`

, the method will return zero, not log an error. It is also incorrect to call `squaredDistanceTo`

on something that is not a vector. For example: `this.ship.squaredDistanceTo(v)`

is missing `position`

and needs to be written as `this.ship.position.squaredDistanceTo(v)`

.

**See Also:** `distanceTo()`

`squaredMagnitude`

functionsquaredMagnitude() : Number

Returns the square of the magnitude of the vector.

`v.squaredMagnitude()`

is equivalent to `v.magnitude() * v.magnitude()`

.

`subtract`

functionsubtract(v : vectorExpression) : Vector3D

Returns the vector difference between the target and `v`

.

**See Also:** `add()`

`toArray`

functiontoArray() : Array

Returns an array of the vector’s components, in the order `[x, y, z]`

. `v.toArray()`

is equivalent to `[v.x, v.y, v.z]`

.

`toCoordinateSystem`

functiontoCoordinateSystem(system : String) : Vector3D

Convert a vector from absolute coordinates to an abstract coordinate system. `system`

must be a three-letter string specifying an abstract coordinate system. The target of the method must be a vector in absolute coordinates. (To convert a vector from one abstract coordinate system to another, you must first call code>fromCoordinateSystem(), then `toCoordinateSystem()`

.)

**Important:**
Vectors do not “know” which coordinate system they’re in. The script must keep track of that. If you add together vectors in different coordinate systems the result will be nonsense, just as if you added measurements in different units without appropriate conversions.

**Example:**

Vector3D(0, 0, 226380).toCoordinateSystem("wpu") // In Lave system, this returns (0, 0, 0.5).

**See Also:** `fromCoordinateSystem()`

`tripleProduct`

functiontripleProduct(v : vectorExpression, w : vectorExpression) : Number

Returns the triple product of the target, `v`

and `w`

.

`u.tripleProduct(v, w)`

is equivalent to `u.dot(v.cross(w))`

.

## Static methods

`interpolate`

functioninterpolate(u : vectorExpression, v : vectorExpression, where : Number) : Vector3D

Returns a point on the line between `u`

and `v`

. If `where`

is 0, the result is `u`

. If `where`

is 1, the result is `v`

. If `where`

is 0.5, the result is half way between `u`

and `v`

. Values of `where`

outside the range [0, 1] are valid; for instance, `Vector3D.interpolate(u, v, -1)`

returns a point as far from `u`

as `v`

is, but in the opposite direction.

`Vector3D.interpolate(u, v, where)`

is equivalent to `u.add(v.subtract(u).multiply(where))`

, or `u.multiply(1 - where).add(v. multiply(where))`

.

`random`

functionrandom([maxLength : Number]) : Vector3D

Returns a vector of random length up to `maxLength`

, in a random direction. If `maxLength`

is not specified (or not a number), 1.0 is used. These vectors are uniformly distributed within the unit sphere, which has the effect that longer vectors are more common than shorter ones. Use `Vector3D.randomDirectionAndLength()`

if an even length distribution is desired.

In the following image, the cloud on the left was made with the 2D equivalent of `random()`

, and the image on the right was made with the 2D equivalent of `randomDirectionAndLength()`

.

**See Also:** `randomDirection()`

, `randomDirectionAndLength()`

`randomDirection`

functionrandomDirection([scale : Number]) : Vector3D

Returns a vector of length `scale`

, in a random direction. If `scale`

is not specified (or not a number), 1.0 is used.

**See Also:** `random()`

, `randomDirectionAndLength()`

`randomDirectionAndLength`

functionrandomDirectionAndLength([maxLength : Number]) : Vector3D

Returns a vector of random length up to `maxLength`

, in a random direction. If `maxLength`

is not specified (or not a number), 1.0 is used. These vectors have a uniform distribution of magnitude (all lengths are equally likely), but cluster towards the origin. Use `Vector3D.random()`

if an even spacial distribution is desired.

**See Also:** `random()`

, `randomDirection()`