Turbulence Affector
Updated: 8 Aug 2025
Applies Turbulence to physics objects.
Turbulence Affector
Method #
This node applies turbulence to the motion of physics objects. This is typically used to apply local variations to physics objects motion, and simulate small gusts of wind. The motion is generated by using a smoothed noise field for both the direction and the magnitude of the applied velocity.
All nodes connected to this node are treated as if flowing to the parent node, and inherits any transformation changes along the chain.
Parameters
These properties control the 3D transforms of the node. Transforms will generally be inherited by child nodes, although they can be ignored through the Inherit Transform Channels attributes.
Parameter Details Position X
The objects position along the local x-axis.
Position Y
The objects position along the local y-axis.
Position Z
The objects position along the local z-axis.
Rotation Heading
The objects rotation around the local y-axis.
Rotation Pitch
The objects rotation around the local x-axis.
Rotation Bank
The objects rotation around the local z-axis.
Scale X
The objects scale along the local x-axis.
Scale Y
The objects scale along the local y-axis.
Scale Z
The objects scale along the local z-axis.
Control the inheritance of the transforms from the parent.
Parameter Details Position
Toggle inheritance of the Position from the parent.
Rotation
Toggle inheritance of the Rotation from the parent.
Scale
Toggle inheritance of the Scale from the parent.
World Position Only
Inherit the world position from the parent only, rotation and scale will be ignored. Overrides above properties.
Inherit Time
Toggle inheritance of time from the parent.
Parameter Details Amount
Strength the affector has on the affected physics objects.
Noise Scale
Scale the size of the generated noise. Higher values will given denser and more erratic motion, while lower values will creater smoother and more stable motions.
Noise Threshold
Sets a minimum amount the noise must be pushing beyond to have an effect on the affected physics objects.
Animation Rate
How quickly the turbulence animated and changes over time.
Animation Time Offset
Manually control how the turbulence animation is changing oer time by offsetting it in time directly.
Update Time Mode
Change how the affector uses time.
- Locked To Timecode : The effect is synchronised with the timecode, so changes in time will always yield the same results.
- Running / Loopable : The effect is generated on a separate time to the timecode, ignoring composition loops. Useful for Real-Time exports, where content needs to play indefinitely. Not suitable for looping videos.
Dampening
Softens the motion applied to the objects to smooth out any erratic motion from the affected physics objects.
These properties control the falloff of the node. Falloff controls how much influence the node has on anything it affects.
Parameter Details Falloff Mode
Which mode to use to calculate the falloff.
- Off : No falloff is used. Everything will be affected equally.
- Spherical : Falloff is drawn outward from a central point, forming a spherical falloff.
- Cylindrical : Falloff is drawn outward from a line, forming a cylindrical falloff.
- Planar : Falloff is drawn outwards in one or more directions from a plane, forming a planar falloff.
- Procedural : Uses a connected procedural system to describe the falloff area. A procedural node must be input for this property to function.
- Cubic : Falloff is calculated from within a cube.
Falloff Axis
Which axis the falloff should be oriented on.
Falloff Direction
When using “Planar” mode, which direction to use to calculate the falloff.
- Bidirectional : The node’s effect will be the most along the plane. It will then falloff in both directions.
- Negative : The node’s effect will be the most along the plane and in the positive direction. It will then falloff in the negative direction.
- Positive : The node’s effect will be the most along the plane and in the negative direction. It will then falloff in the positive direction.
Falloff Easing Mode
Interpolation method used to calculate the falloff within its range of influence.
- Linear : Falloff will be calculated linearly across the falloff range.
- Sine : Falloff will be calculated using a sine function across the falloff range.
- Quadratic : Falloff will be calculated using a quadratic function across the falloff range.
- Cubic : Falloff will be calculated using a cubic function across the falloff range.
- Circular : Falloff will be calculated using a circular function across the falloff range.
- Bounce Back : Falloff uses a function which as values reach the edge of the falloff range, they will overshoot and bounce back.
- Elastic : Falloff uses a function similar to bounce back, but the value will initially move in the opposite direction, creating a “pull and release” effect.
Falloff Size X
Size of the falloff range along the X axis.
Falloff Size Y
Size of the falloff range along the Y axis.
Falloff Size Z
Size of the falloff range along the Z axis.
Outer Range
Outer range of the falloff.
Inner Range
Inner range of the falloff.
Curve Power
Controls the rate of change of the falloff between the inner and outer range.
Invert
Inverts the effect of the falloff.
The properties control the time at which the node is active. See Timeline for editing time segments.
Parameter Details Duration
Control the duration of the node’s time segment.
- Composition Duration : Use the length of the composition for the node’s time segment duration.
- Custom : Set a custom duration for the node’s time segment.
Node Time
The custom start and end time for the node.
Duration (Timecode)
The length of the node’s time segment (in time).
Duration (Frames)
The length of the node’s time segment (in frames).
Time Segment Enabled
Set whether the node’s time segment is enabled or not in the Timeline.
Inputs
These properties control the 3D transforms of the node. Transforms will generally be inherited by child nodes, although they can be ignored through the Inherit Transform Channels attributes.
| Parameter | Details |
|---|---|
| Position X | The objects position along the local x-axis. |
| Position Y | The objects position along the local y-axis. |
| Position Z | The objects position along the local z-axis. |
| Rotation Heading | The objects rotation around the local y-axis. |
| Rotation Pitch | The objects rotation around the local x-axis. |
| Rotation Bank | The objects rotation around the local z-axis. |
| Scale X | The objects scale along the local x-axis. |
| Scale Y | The objects scale along the local y-axis. |
| Scale Z | The objects scale along the local z-axis. |
Control the inheritance of the transforms from the parent.
| Parameter | Details |
|---|---|
| Position | Toggle inheritance of the Position from the parent. |
| Rotation | Toggle inheritance of the Rotation from the parent. |
| Scale | Toggle inheritance of the Scale from the parent. |
| World Position Only | Inherit the world position from the parent only, rotation and scale will be ignored. Overrides above properties. |
| Inherit Time | Toggle inheritance of time from the parent. |
| Parameter | Details |
|---|---|
| Amount | Strength the affector has on the affected physics objects. |
| Noise Scale | Scale the size of the generated noise. Higher values will given denser and more erratic motion, while lower values will creater smoother and more stable motions. |
| Noise Threshold | Sets a minimum amount the noise must be pushing beyond to have an effect on the affected physics objects. |
| Animation Rate | How quickly the turbulence animated and changes over time. |
| Animation Time Offset | Manually control how the turbulence animation is changing oer time by offsetting it in time directly. |
| Update Time Mode |
Change how the affector uses time.
|
| Dampening | Softens the motion applied to the objects to smooth out any erratic motion from the affected physics objects. |
These properties control the falloff of the node. Falloff controls how much influence the node has on anything it affects.
| Parameter | Details |
|---|---|
| Falloff Mode |
Which mode to use to calculate the falloff.
|
| Falloff Axis | Which axis the falloff should be oriented on. |
| Falloff Direction |
When using “Planar” mode, which direction to use to calculate the falloff.
|
| Falloff Easing Mode |
Interpolation method used to calculate the falloff within its range of influence.
|
| Falloff Size X | Size of the falloff range along the X axis. |
| Falloff Size Y | Size of the falloff range along the Y axis. |
| Falloff Size Z | Size of the falloff range along the Z axis. |
| Outer Range | Outer range of the falloff. |
| Inner Range | Inner range of the falloff. |
| Curve Power | Controls the rate of change of the falloff between the inner and outer range. |
| Invert | Inverts the effect of the falloff. |
The properties control the time at which the node is active. See Timeline for editing time segments.
| Parameter | Details |
|---|---|
| Duration |
Control the duration of the node’s time segment.
|
| Node Time | The custom start and end time for the node. |
| Duration (Timecode) | The length of the node’s time segment (in time). |
| Duration (Frames) | The length of the node’s time segment (in frames). |
| Time Segment Enabled | Set whether the node’s time segment is enabled or not in the Timeline. |
| Name | Description | Typical Input |
|---|---|---|
| Falloff Node | Use an input node to control the transformation values of the falloff. | Falloff |
| Transform Modifiers | Apply the transforms of another node to this node. | Null |
| Target Node | Modifiy the rotations of the node to always direct the z axis towards the input. | Null |
| Local Transform Override | Apply the transforms of another node to this node, relative to its parent. | Null |