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Rope Body

Rope body enables physical simulation of ropes, cables, wires, etc. Ropes can be pinned to the following types of bodies:

To pin a rope to a body so it would hang freely, or tie several bodies, use a Particles joint. The Rope body can be torn as a Cloth body. Rope enhances the realism of simulated environment and saves the time of game artists as it replaces animation. However, simulation of this type of body is quite costly and it is strongly recommended to use distance optimization to avoid performance hits.

Notice
Rope body can be assigned only to Mesh Dynamic objects.

See also#

Mesh Requirements#

The only acceptable mesh type for a Rope body is a cylinder. You can use a standard primitive cylinder to create a rope. The workflow in this case is as follows:

  1. On the Menu bar, click Create -> Primitive -> Cylinder.
  2. Specify desired rope parameters (length, radius) for a cylinder, e.g. the following:

    Create Cylinder

  3. Click OK and place the cylinder somewhere in the world. It is created as a Static Mesh object. The object itself can be deleted, its mesh however is still available in the data/ folder.
  4. Create a Dynamic Mesh object and use the cylinder mesh for it.
  5. Assign the rope body to the created dynamic mesh object.

Mass-Spring Simulation Model#

A Rope body is modeled as set of point masses (particles) located in the mesh vertices. Each particle is represented with a sphere shape and is linked together with other particles by inner spring joints that are located along the mesh edges. Inner joints allow to recreate mesh topology, on the one hand, and constrain stretching and folding, on the other.

Mass-Spring Simulation Model

Each particle is characterized by a position, mass and velocity and has a constant spherical shape with a set radius. The total mass of the whole body is equally distributed among them. In accordance with Newton's second law particles can be acted upon by a force or an impulse applied by inner joints and external forces (collision, gravity, air resistance, wind, etc.).

Self-collision of the particles and collisions between different rope bodies are not calculated. However, the rope interacts with environment by colliding with other physical bodies if the Collision box is checked. Its behavior in case of contact is controlled by such parameters as friction and restitution. Selective physical interaction is available via corresponding bitmasks.

Thus, Rope body can be regarded as a constrained system of rigid particles and therefore shares some parameters with Rigid body:

Particle Radius#

As already mentioned, each particle is a sphere with a set radius. Thus, particles use continuous collision detection. The rope never lies flat on the ground or tightly adheres to the surfaces. There is always a gap equal to particle radius.

As collisions between the particles are not calculated, they should not be considered when setting a radius:

  • Higher values are preferable for more robust behavior. However, too big radius may result in incorrect interaction with the environment (twitching or blowing up of the rope).
  • Lower values decrease the gap between the Rope body and the surface. However, too low radius results in poor collision handling.
Notice
An object can pass through the rope, when the particle radius is small and the rope is stretched. The reason is that continuous collision detection is performed only for particle spheres located in vertices of rope mesh.

Joints Solver Iterations#

The number of iterations controls the accuracy of the solution of rope inner joints. This number indicates how many times the joints are solved per physics frame. Joints are solved in a random order to provide more predictable stretching results.

  • Low number of iterations results in faster simulation. However, in this case the rope is more prone to stretching and looks more elastic. The minimum value is 1.
  • High number of iterations provides more accurate solution of constraints. In this case the rope looks stiffer. The maximum value is 16.

    Notice
    Increased number of iterations is considerably expensive and at some point ceases to bring a noticeable benefit, so it should be kept within a reasonable cost-effectiveness limit.

Increasing the number of iterations may help to avoid twitching of a rope.

Stretching and Folding#

A rope may be deformed by stretching and folding. These deformations are controlled with joint constraints of two types:

With these types of constraints, it is possible to obtain the desired look and feel of the rope and simulate a variety of different deformable materials ranging from a stiff metal wire to an elastic rubber cord.

Linear Restitution#

Linear restitution determines how far the rope particles can be stretched apart from each other. It enforces rope joints to restore the distance that was between the vertices of the original mesh:

  • By the maximum value of 1, the particles spring back with great force and the rope is hard to stretch. It gives the effect of stiff non-stretch rope, e.g. a metal wire.
  • The lower the value, the easier the particles are moved away from each other and the more stretchable and elastic the rope is, e.g. a rubber cord.

    Notice
    0 and near zero values are not allowed because they cause unstable simulation and blowing up of the rope.

Angular Restitution#

Angular restitution determines the possible angle between rope triangles that are formed by particles. It constrains the folding of the rope by enforcing joints to keep the angle between the triangles of the original mesh:

  • By the maximum value of 1, the angles tend to be retained and the rope resists folding. The rope appears to be stiff.

    Notice
    The maximum value may provide unsteady behavior.
  • By the minimum value of 0, the rope can be easily folded and bent in any direction, regardless of the original topology of the mesh.
Notice

If the rope is too stretchy and rubbery, try one of the following:

  • Set linear restitution to 1.
  • Increase the number of joints solver iterations.
  • Use the mesh with fewer vertices.

Rigidity of Motion#

The Rigidity parameter is an additional constraint of the rope motion to make it stiffer and more inflexible. For that purpose, linear and angular velocities of each rope particle are corrected according to the total velocities interpolated for all the particles.

  • The minimum value of 0, makes the rope elastic, flexible and easily deformable.
  • The maximum value of 1, makes the rope stiffer and less prone to deformation.

Tearing#

When the rope is stretched or folded beyond its elastic limit, it tears and shreds into pieces. Tearing is caused by applying the force or collision with a physical body, and depends on the rope stiffness (controlled by linear and angular restitution parameters). The rope is torn only along the edges of rope triangles, splitting mesh vertices and duplicating particles.

Notice
If torn pieces of rope fall onto one plane, they cause Z-fighting.

Linear Threshold Distance#

Linear threshold sets the distance limit for stretching the rope. When two particles move away from each other further than this limit, joints that connect them break and a the tear appears.

  • If set to infinity (inf), the rope is stretched without tearing. This value is set by default.

Angular Threshold Angle#

Same as linear threshold, angular threshold represents a maximum angle to fold the rope relative to its initial state.

  • If set to infinity (inf), the rope is folded without tearing. This value is set by default.

    Notice
    It is recommended to keep the angular threshold lower or equal to 180 degrees.

Optimizing Simulation#

Updating each frame a huge number of objects located far away from the camera that are hardly distinguishable or observed as a mass is a waste of resources.

To improve performance and avoid the excessive load, simulation of the rope can be updated with a reduced framerate. When the player is out of the area specified by the Update Distance Limit, the rope stops to be updated and freezes statically.

The set of frame rates given below enables you to specify how often the rope simulation should be updated when the object is visible, when only its shadow is visible, or when it is not visible at all.

Parameters -> Physics tab -> Periodic Update section
FPS When Object Is Rendered To Viewport Update rate value for the case when the object is rendered to viewport.
FPS When Only Object Shadows Are Rendered Update rate value when the object itself is outside the viewing frustum, and only its shadow is rendered to viewport.
FPS When Object Is Not Rendered At All Update rate value when both the object and its shadow are not rendered to the viewport.
Update Distance Limit Distance from the camera up to which the object should be updated.
Notice
These values are not fixed and can be adjusted by the Engine at any time to ensure best performance.

This feature is enabled with default settings ensuring optimum performance and can be adjusted per-object in the UnigineEditor or via API at run time.

Warning
Be aware that using reduced update frame rate for an object should be carefully considered in your application's logic, as it may lead to various issues with rendering Mesh Skinned and Mesh Dynamic (flickering due to misalignment, e.g. in case of attaching a rope to a Mesh Skinned).

Assigning a Rope Body#

To assign a Rope body to an object via UnigineEditor perform the following steps:

  1. Open the World Hierarchy window.
  2. Select a dynamic mesh object to assign a Rope body to.

    Notice
    Make sure that the object's mesh meets requirements!
  3. Go to the Physics tab in the Parameters window and assign a physical body to the selected object by selecting Body -> Rope.

    Adding a body

  4. Set the body's name and change other parameters, if necessary.

Attaching a Rope#

Rope attached to a Mesh Skinned

Rope attached to animated character

Ropes can be attached to the following types of bodies:

To attach a rope to a body, use the Particles joint. In case of Rigid body (either static or dynamic) and Dummy body, pinned particles stay fixed in their position and follow transformations of attached objects pulling the rope with it.

  1. Select Rigid body, RagDoll body or Dummy body.
  2. Add Particles joint.
  3. Specify Rope body.
  4. Adjust the pinning area using the Threshold and Size parameters of the Particles joint.
Notice
To ensure stable simulation it is important to set appropriate masses of the rope and the attached body. Unbalanced masses may cause twitching of rope joints.

Attachment to Skinned Mesh#

Convincing simulation of the rope on a Mesh Skinned character requires a different approach. To follow bones transformations, each vertex of the rope that is found in the Particles joint area is mapped to the nearest Mesh Skinned vertex (up to the distance specified by the Threshold parameter of the particles joint).

Notice
It is not recommended to attach the rope directly to the Mesh Skinned character, because difference in topologies may result in visual artifacts. Instead, it is better to create an identical rope surface on the Mesh Skinned character, make it invisible and attach a physical rope to it.

For example, we need to create a rope that is glued to the hand of a Mesh Skinned character while the rest of the rope hangs and moves loosely. It is done in the following steps:

  1. When creating a Mesh Skinned, add a rope segment surface identical to the clipped part that needs to be pinned. In our case, it's the rope part in a hand.
  2. Add Mesh Skinned that has a RagDoll body assigned. Make sure that the rope segment surface is enabled.
  3. Add a separate dynamic rope mesh and synchronize its position with Mesh Skinned character. Turn off physical simulation (CTRL + SPACE) and assign a Rope body.
  4. Attach Rope body to RagDoll body. If the Threshold distance of the particles joint is set low enough, the physical rope will be automatically attached only to the rope segment surface (i.e. hand). After that, the rope segment surface is simply disabled and does not provide any load at all.
Last update: 2024-08-16
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