Difference between revisions of "Oolite JavaScript Reference: Quaternion"

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{{Oolite-future-scripting}}
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<small>'''Prototype:''' <code>Object</code></small><br />
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<small>'''Subtypes:''' none</small>
  
 
The '''<code>Quaternion</code>''' class represents a [[quaternion]], a four-dimensional number, which is used to express rotations. Explaining quaternion mathematics is ''way'' beyond the scope of this document, but a quick overview is provided below.
 
The '''<code>Quaternion</code>''' class represents a [[quaternion]], a four-dimensional number, which is used to express rotations. Explaining quaternion mathematics is ''way'' beyond the scope of this document, but a quick overview is provided below.
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* MathWorld: [http://mathworld.wolfram.com/Quaternion.html Quaternion]
 
* MathWorld: [http://mathworld.wolfram.com/Quaternion.html Quaternion]
  
Consider a ship at point ''h'' oriented to face a station at point ''t''. This can be expressed as the vector from the ship to the station, ''v'' = ''t'' − ''h''. However, if the ship rolls, it is still heading along the same vector ''v'', so additional information is required: a twist angle, ''α'' (FIXME: relative to what?). A rotation quaternion is a tuple ''Q'' = (''w'', ''x'', ''y'', ''z''), such that
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Consider a ship at point ''h'' oriented to face a station at point ''t''. This can be expressed as the vector from the ship to the station, ''v'' = ''t'' − ''h''. However, if the ship rolls, it is still heading along the same vector ''v'', so additional information is required: a twist angle, ''α''. A rotation quaternion is a tuple ''Q'' = (''w'', ''x'', ''y'', ''z''), such that
 
:''Q<sub>w</sub>'' = cos ''α''/2
 
:''Q<sub>w</sub>'' = cos ''α''/2
 
:''Q<sub>x</sub>'' = ''v<sub>x</sub>'' sin ''α''/2
 
:''Q<sub>x</sub>'' = ''v<sub>x</sub>'' sin ''α''/2
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Additionally, a rotation quaternion must be normalized; that is, it must fulfill the '''normal invariant''' ''Q<sub>w</sub>''² + ''Q<sub>x</sub>''² + ''Q<sub>y</sub>''² + ''Q<sub>z</sub>''² = 1. Unlike with [[property list]] scripting and specifications, quaternions will not be automatically normalized for you except where specified, but a <code>[[#normalize|normalize]]()</code> method is provided.
 
Additionally, a rotation quaternion must be normalized; that is, it must fulfill the '''normal invariant''' ''Q<sub>w</sub>''² + ''Q<sub>x</sub>''² + ''Q<sub>y</sub>''² + ''Q<sub>z</sub>''² = 1. Unlike with [[property list]] scripting and specifications, quaternions will not be automatically normalized for you except where specified, but a <code>[[#normalize|normalize]]()</code> method is provided.
  
An '''identity rotation''' – that is, one which, when applied, has no effect – is represented by the '''identity quaternion''' (1, 0, 0, 0).
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An '''identity rotation''' – that is, one which, when applied, has no effect – is represented by the '''identity quaternion''' (1, 0, 0, 0). Often you will want to start with this identity quaternion before applying the methods '''rotate''', '''rotateX''', '''rotateY''' or '''rotateZ'''.
  
 
The <code>Quaternion</code> class provides several methods to make construction of rotations easier: <code>[[#rotate|rotate]]()</code>, <code>[[#rotateX|rotateX]]()</code>, <code>[[#rotateY|rotateY]]()</code>, <code>[[#rotateZ|rotateZ]]()</code>.
 
The <code>Quaternion</code> class provides several methods to make construction of rotations easier: <code>[[#rotate|rotate]]()</code>, <code>[[#rotateX|rotateX]]()</code>, <code>[[#rotateY|rotateY]]()</code>, <code>[[#rotateZ|rotateZ]]()</code>.
  
 
Rotations can be combined by quaternion multiplication (see the <code>[[#multiply|multiply]]()</code> method). Note that quaternion multiplication is not commutative; that is, ''PQ'' is not the same as ''QP''. If this seems strange, take a box or book and assign it ''x'', ''y'' and ''z'' axes. Rotate it about the ''x'' axis and then the ''y'' axis. Then, rotate it about the ''y'' axis followed by the ''x'' axis. If the results of the two rotations are the same, you’re doing it wrong.
 
Rotations can be combined by quaternion multiplication (see the <code>[[#multiply|multiply]]()</code> method). Note that quaternion multiplication is not commutative; that is, ''PQ'' is not the same as ''QP''. If this seems strange, take a box or book and assign it ''x'', ''y'' and ''z'' axes. Rotate it about the ''x'' axis and then the ''y'' axis. Then, rotate it about the ''y'' axis followed by the ''x'' axis. If the results of the two rotations are the same, you’re doing it wrong.
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The [https://app.box.com/s/6usw7ozbvobze3hkouzc Quaternion calculator] is a very useful spreadsheet to get quaternions from rotation angles.
  
 
=== Quaternion Expressions ===
 
=== Quaternion Expressions ===
All Oolite-provided functions which take a quaternion as an argument may instead be passed an [[Oolite/Development/Scripting/Class/Entity|Entity]] instead, in which case the entity’s <code>[[Oolite/Development/Scripting/Class/Entity#orientation|orientation]]</code> is used. In specifications, this is represented by arguments named <code>quaternionOrEntity</code>.
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All Oolite-provided functions which take a quaternion as an argument may instead be passed an array of four numbers, or an [[Oolite JavaScript Reference: Entity|Entity]] (in which case the entity’s <code>[[Oolite JavaScript Reference: Entity#orientation|orientation]]</code> is used). In specifications, this is represented by arguments typed <code>quaternionExpression</code>.
 
 
Additionally, most <code>Quaternion</code> methods may be passed four numbers instead of a vector. In specifications, this is represented by arguments named <code>quaternionExpression</code>.
 
  
 
== Properties ==
 
== Properties ==
 
=== <code>w</code> ===
 
=== <code>w</code> ===
  w [read-write double]
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  '''w''' : Number (read/write)
  
 
The ''w'' component of the quaternion.
 
The ''w'' component of the quaternion.
  
 
=== <code>x</code> ===
 
=== <code>x</code> ===
  x [read-write double]
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  '''x''' : Number (read/write)
 
The ''x'' component of the quaternion.
 
The ''x'' component of the quaternion.
  
 
=== <code>y</code> ===
 
=== <code>y</code> ===
  y [read-write double]
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  '''y''' : Number (read/write)
 
The ''y'' component of the quaternion.
 
The ''y'' component of the quaternion.
  
 
=== <code>z</code> ===
 
=== <code>z</code> ===
  z [read-write double]
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  '''z''' : Number (read/write)
 
The ''z'' component of the quaternion.
 
The ''z'' component of the quaternion.
  
 
== Methods ==
 
== Methods ==
 
=== Constructor ===
 
=== Constructor ===
  new Quaternion([ [[#Quaternion Expressions|quaternionExpression]]]);
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  '''new Quaternion'''([value : [[#Quaternion Expressions|quaternionExpression]]])
Create a new quaternion with the specified value. If no value is provided, the vector is initialized to the identity quaternion (1, 0, 0, 0).
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Create a new quaternion with the specified value. If no value is provided, the quaternion is initialized to the identity quaternion (1, 0, 0, 0).
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''Note'': in version 1.77 or earlier, the quaternion is incorrectly initialised to the zero quaternion ('''0''', 0, 0, 0) if no value is provided. For portability you should therefore provide a value to the constructor.
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=== <code>conjugate</code> ===
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{{oolite-method-added|1.77}}
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function '''conjugate'''() : Quaternion
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Return the conjugate of the quaternion (i.e. the quaternion which when multiplied by the original quaternion returns the identity quaternion). The input quaternion must be normalized.
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=== <code>dot</code> ===
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function '''dot'''(q : [[#Quaternion Expressions|quaternionExpression]]) : Number
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Returns the quaternion dot product (inner product) of the target and <code>q</code>. (For two normalized quaternions, this will be 1 if they’re equal, -1 if they’re opposite and 0 if they’re perpendicular.)
  
 
=== <code>multiply</code> ===
 
=== <code>multiply</code> ===
  Quaternion multiply([[#Quaternion Expressions|quaternionExpression]]);
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  function '''multiply'''(q : [[#Quaternion Expressions|quaternionExpression]]) : Quaternion
Returns the standard quaternion product (Grassman product) of the target and <code>[[#Quaternion Expressions|quaternionExpression]]</code>. This is used to concatenate rotations together.
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Returns the standard quaternion product (Grassmann product) of the target and <code>q</code>. This is used to concatenate rotations together.
  
=== <code>dot</code> ===
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=== <code>normalize</code> ===
  Quaternion dot([[#Quaternion Expressions|quaternionExpression]]);
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  function '''normalize'''() : Quaternion
Returns the quaternion dot product (inner product) of the target and <code>[[#Quaternion Expressions|quaternionExpression]]</code>. (This is not known to be useful – it’s not used anywhere in Oolite – but the functionality exists in Oolite’s maths library, so I’ve chosen to expose it. -- [[User:Ahruman|Ahruman]])
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Returns the quaternion adjusted to fulfill the [[#Quaternions for Rotations|normal invariant]]. Specifically, this divides each component by the square root of (''w''² + ''x''² + ''y''² + ''z''²).
  
 
=== <code>rotate</code> ===
 
=== <code>rotate</code> ===
  Quaternion rotate([[Oolite/Development/Scripting/Class/Vector#Vector Expressions|vectorExpression]], angle);
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  function '''rotate'''(a : [[Oolite JavaScript Reference: Vector#Vector Expressions|vectorExpression]], angle : Number) : Quaternion
Returns a quaternion rotated <code>angle</code> radians about the axis of <code>[[Oolite/Development/Scripting/Class/Vector#Vector Expressions|vectorExpression]]</code>. (FIXME: clockwise or anticlockwise?)
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Returns a quaternion rotated <code>angle</code> radians about the axis of <code>a</code>. The vector <code>a</code> must be a normalized vector. A positive angle is anti-clockwise if the vector is pointing towards you.
  
 
=== <code>rotateX</code> ===
 
=== <code>rotateX</code> ===
  Quaternion rotateX(angle);
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  function '''rotateX'''(angle : Number) : Quaternion
Returns a quaternion rotated <code>angle</code> radians about the ''x'' axis. (FIXME: clockwise or anticlockwise?)
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Returns a quaternion rotated <code>angle</code> radians about the ''x'' axis. A positive angle is anti-clockwise if the ''x'' axis is pointing towards you.
  
<code>q.rotateX(a)</code> is equivalent to <code>q.[[#rotate|rotate]](1, 0, 0, a)</code>.
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<code>q.rotateX(angle)</code> is equivalent to <code>q.[[#rotate|rotate]]([1, 0, 0], angle)</code>.
  
 
=== <code>rotateY</code> ===
 
=== <code>rotateY</code> ===
  Quaternion rotateY(angle);
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  function '''rotateY'''(angle : Number) : Quaternion
Returns a quaternion rotated <code>angle</code> radians about the ''y'' axis. (FIXME: clockwise or anticlockwise?)
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Returns a quaternion rotated <code>angle</code> radians about the ''y'' axis. A positive angle is anti-clockwise if the ''y'' axis is pointing towards you.
  
<code>q.rotateY(a)</code> is equivalent to <code>q.[[#rotate|rotate]](0, 1, 0, a)</code>.
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<code>q.rotateY(angle)</code> is equivalent to <code>q.[[#rotate|rotate]]([0, 1, 0], angle)</code>.
  
 
=== <code>rotateZ</code> ===
 
=== <code>rotateZ</code> ===
  Quaternion rotateZ(angle);
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  function '''rotateZ'''(angle : Number) : Quaternion
Returns a quaternion rotated <code>angle</code> radians about the ''z'' axis. (FIXME: clockwise or anticlockwise?)
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Returns a quaternion rotated <code>angle</code> radians about the ''z'' axis. A positive angle is anti-clockwise if the ''z'' axis is pointing towards you.
  
<code>q.rotateZ(a)</code> is equivalent to <code>q.[[#rotate|rotate]](0, 0, 1, a)</code>.
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<code>q.rotateZ(angle)</code> is equivalent to <code>q.[[#rotate|rotate]]([0, 0, 1], angle)</code>.
  
=== <code>normalize</code> ===
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=== <code>toArray</code> ===
  Quaternion normalize(angle);
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  function '''toArray'''() : Array
Returns the quaternion adjusted to fulfill the [[#Quaternions for Rotations|normal invariant]]. Specifically, this divides each component by the square root of (''w''² + ''x''² + ''y''² + ''z''²).
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Returns an array of the quaternion’s components, in the order <code>[w, x, y, z]</code>. <code>q.toArray()</code> is equivalent to <code>[q.w, q.x, q.y, q.z]</code>.
  
 
=== <code>vectorForward</code> ===
 
=== <code>vectorForward</code> ===
  [[Oolite/Development/Scripting/Class/Vector|Vector]] vectorForward();
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  function '''vectorForward'''() : [[Oolite JavaScript Reference: Vector|Vector]]
 
Returns the forward vector from the quaternion.
 
Returns the forward vector from the quaternion.
  
To understand this, consider an entity which is aligned with the world co-ordinate system – that is, its <code>[[Oolite/Development/Scripting/Class/Entity#orientation|orientation]]</code> is the identity quaternion (1, 0, 0, 0), and thus its ''x'' axis is aligned with the world ''x'' axis, its ''y'' axis is aligned with the world ''y'' axis and its ''z'' axis is aligned with the world ''z'' axis. If it is rotated by a quaternion ''Q'', <code>Q.vectorForward()</code> is the forward (''z'') axis after rotation. Similarly, <code>Q.[[#vectorUp|vectorUp]]()</code> is the up (''y'') axis after rotation, and <code>Q.[[#vectorRight|vectorRight]]()</code> is the right (''x'') axis after rotation.
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To understand this, consider an entity which is aligned with the world co-ordinate system – that is, its <code>[[Oolite JavaScript Reference: Entity#orientation|orientation]]</code> is the identity quaternion (1, 0, 0, 0), and thus its ''x'' axis is aligned with the world ''x'' axis, its ''y'' axis is aligned with the world ''y'' axis and its ''z'' axis is aligned with the world ''z'' axis. If it is rotated by a quaternion ''Q'', <code>Q.vectorForward()</code> is the forward (''z'') axis after rotation. Similarly, <code>Q.[[#vectorUp|vectorUp]]()</code> is the up (''y'') axis after rotation, and <code>Q.[[#vectorRight|vectorRight]]()</code> is the right (''x'') axis after rotation.
 +
 
 +
=== <code>vectorRight</code> ===
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function '''vectorRight'''() : [[Oolite JavaScript Reference: Vector|Vector]]
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Returns the right vector from the quaternion. See <code>[[#vectorForward|vectorForward]]()</code> for a definition.
  
 
=== <code>vectorUp</code> ===
 
=== <code>vectorUp</code> ===
  [[Oolite/Development/Scripting/Class/Vector|Vector]] vectorUp();
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  function '''vectorUp'''() : [[Oolite JavaScript Reference: Vector|Vector]]
 
Returns the up vector from the quaternion. See <code>[[#vectorForward|vectorForward]]()</code> for a definition.
 
Returns the up vector from the quaternion. See <code>[[#vectorForward|vectorForward]]()</code> for a definition.
  
=== <code>vectorRight</code> ===
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== Static Methods ==
  [[Oolite/Development/Scripting/Class/Vector|Vector]] vectorRight();
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Returns the up vector from the quaternion. See <code>[[#vectorForward|vectorForward]]()</code> for a definition.
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=== <code>random</code> ===
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  function '''random'''() : Quaternion
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Returns a random normalized quaternion.
  
  
[[Category:Oolite scripting]] [[Category:Oolite Development]]
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[[Category:Oolite JavaScript Reference]]

Latest revision as of 10:05, 20 June 2014

Prototype: Object
Subtypes: none

The Quaternion class represents a quaternion, a four-dimensional number, which is used to express rotations. Explaining quaternion mathematics is way beyond the scope of this document, but a quick overview is provided below.

Quaternions for Rotations

This is a very quick, pragmatic discussion of quaternions as they apply to rotating things in Oolite. If you’re interested in the theory, see:

Consider a ship at point h oriented to face a station at point t. This can be expressed as the vector from the ship to the station, v = th. However, if the ship rolls, it is still heading along the same vector v, so additional information is required: a twist angle, α. A rotation quaternion is a tuple Q = (w, x, y, z), such that

Qw = cos α/2
Qx = vx sin α/2
Qy = vy sin α/2
Qz = vz sin α/2

Additionally, a rotation quaternion must be normalized; that is, it must fulfill the normal invariant Qw² + Qx² + Qy² + Qz² = 1. Unlike with property list scripting and specifications, quaternions will not be automatically normalized for you except where specified, but a normalize() method is provided.

An identity rotation – that is, one which, when applied, has no effect – is represented by the identity quaternion (1, 0, 0, 0). Often you will want to start with this identity quaternion before applying the methods rotate, rotateX, rotateY or rotateZ.

The Quaternion class provides several methods to make construction of rotations easier: rotate(), rotateX(), rotateY(), rotateZ().

Rotations can be combined by quaternion multiplication (see the multiply() method). Note that quaternion multiplication is not commutative; that is, PQ is not the same as QP. If this seems strange, take a box or book and assign it x, y and z axes. Rotate it about the x axis and then the y axis. Then, rotate it about the y axis followed by the x axis. If the results of the two rotations are the same, you’re doing it wrong.

The Quaternion calculator is a very useful spreadsheet to get quaternions from rotation angles.

Quaternion Expressions

All Oolite-provided functions which take a quaternion as an argument may instead be passed an array of four numbers, or an Entity (in which case the entity’s orientation is used). In specifications, this is represented by arguments typed quaternionExpression.

Properties

w

w : Number (read/write)

The w component of the quaternion.

x

x : Number (read/write)

The x component of the quaternion.

y

y : Number (read/write)

The y component of the quaternion.

z

z : Number (read/write)

The z component of the quaternion.

Methods

Constructor

new Quaternion([value : quaternionExpression])

Create a new quaternion with the specified value. If no value is provided, the quaternion is initialized to the identity quaternion (1, 0, 0, 0).

Note: in version 1.77 or earlier, the quaternion is incorrectly initialised to the zero quaternion (0, 0, 0, 0) if no value is provided. For portability you should therefore provide a value to the constructor.

conjugate

This method was added in Oolite test release 1.77.

function conjugate() : Quaternion

Return the conjugate of the quaternion (i.e. the quaternion which when multiplied by the original quaternion returns the identity quaternion). The input quaternion must be normalized.

dot

function dot(q : quaternionExpression) : Number

Returns the quaternion dot product (inner product) of the target and q. (For two normalized quaternions, this will be 1 if they’re equal, -1 if they’re opposite and 0 if they’re perpendicular.)

multiply

function multiply(q : quaternionExpression) : Quaternion

Returns the standard quaternion product (Grassmann product) of the target and q. This is used to concatenate rotations together.

normalize

function normalize() : Quaternion

Returns the quaternion adjusted to fulfill the normal invariant. Specifically, this divides each component by the square root of (w² + x² + y² + z²).

rotate

function rotate(a : vectorExpression, angle : Number) : Quaternion

Returns a quaternion rotated angle radians about the axis of a. The vector a must be a normalized vector. A positive angle is anti-clockwise if the vector is pointing towards you.

rotateX

function rotateX(angle : Number) : Quaternion

Returns a quaternion rotated angle radians about the x axis. A positive angle is anti-clockwise if the x axis is pointing towards you.

q.rotateX(angle) is equivalent to q.rotate([1, 0, 0], angle).

rotateY

function rotateY(angle : Number) : Quaternion

Returns a quaternion rotated angle radians about the y axis. A positive angle is anti-clockwise if the y axis is pointing towards you.

q.rotateY(angle) is equivalent to q.rotate([0, 1, 0], angle).

rotateZ

function rotateZ(angle : Number) : Quaternion

Returns a quaternion rotated angle radians about the z axis. A positive angle is anti-clockwise if the z axis is pointing towards you.

q.rotateZ(angle) is equivalent to q.rotate([0, 0, 1], angle).

toArray

function toArray() : Array

Returns an array of the quaternion’s components, in the order [w, x, y, z]. q.toArray() is equivalent to [q.w, q.x, q.y, q.z].

vectorForward

function vectorForward() : Vector

Returns the forward vector from the quaternion.

To understand this, consider an entity which is aligned with the world co-ordinate system – that is, its orientation is the identity quaternion (1, 0, 0, 0), and thus its x axis is aligned with the world x axis, its y axis is aligned with the world y axis and its z axis is aligned with the world z axis. If it is rotated by a quaternion Q, Q.vectorForward() is the forward (z) axis after rotation. Similarly, Q.vectorUp() is the up (y) axis after rotation, and Q.vectorRight() is the right (x) axis after rotation.

vectorRight

function vectorRight() : Vector

Returns the right vector from the quaternion. See vectorForward() for a definition.

vectorUp

function vectorUp() : Vector

Returns the up vector from the quaternion. See vectorForward() for a definition.

Static Methods

random

function random() : Quaternion

Returns a random normalized quaternion.