Fix #104497 (Soft body: "Stiff quads" changed to "Stiffness") #104757

Merged
Matthew Hinson merged 1 commits from Matthew-Hinson/blender-manual:soft-body-stiffness into main 2024-03-29 17:03:15 +01:00

View File

@ -3,25 +3,22 @@
Interior Interior
******** ********
In between each neighboring vertex of a mesh, you typically create edges to connect them. By default, the edges of a soft-body mesh act like springs. This means that,
Imagine each edge as a spring. Any mechanical spring is able to stretch under tension, like a mechanical spring, they can stretch under tension and squeeze under pressure.
and to squeeze under pressure. All springs have an ideal length, Their initial length is also their "ideal" or "rest" length, which they try to return to.
and a stiffness that limits how far you can stretch or squeeze the spring.
In Blender's case, the ideal length is the original edge length which you designed as a part of your mesh, Having edges act like springs is what holds the mesh together. If you were to disable this
even before you enable the Soft Body system. Until you add the Soft Body physics, behavior (as well as the :doc:`/physics/soft_body/settings/goal`), each vertex would be free
all springs are assumed to be perfectly stiff: no stretch and no squeeze. to go anywhere independently of the others, which would stretch the mesh until it's
no longer recognizable.
You can adjust the stiffness of all those edge springs, allowing your mesh to sag, to bend, Having springs along edges alone typically isn't enough, however:
to flutter in the breeze, or to puddle up on the ground. vertices in quads are still free to move towards their diagonal opposite,
potentially collapsing the quad into a line.
---- You could solve this by creating diagonal edges everywhere, but fortunately,
you don't have to: simply enable the *Stiffness* option to have Blender create
To create a connection between the vertices of a soft body object there have to be forces diagonal springs internally. This way, you don't have to change your mesh.
that hold the vertices together. These forces are effective along the edges in a mesh,
the connections between the vertices. The forces act like a spring.
Fig. :ref:`fig-softbody-force-interior-connection` illustrates how a 3×3 grid of vertices
(a mesh plane in Blender) are connected in a soft body simulation.
.. list-table:: .. list-table::
@ -31,7 +28,7 @@ Fig. :ref:`fig-softbody-force-interior-connection` illustrates how a 3×3 grid o
:width: 180px :width: 180px
:figwidth: 180px :figwidth: 180px
Vertices and forces along their connection edges. Base springs along edges.
- .. _fig-softbody-force-interior-stiff: - .. _fig-softbody-force-interior-stiff:
@ -39,40 +36,28 @@ Fig. :ref:`fig-softbody-force-interior-connection` illustrates how a 3×3 grid o
:width: 180px :width: 180px
:figwidth: 180px :figwidth: 180px
Additional forces with Stiff Quads enabled. Additional springs when Stiffness is enabled.
But two vertices could freely rotate if you do not create additional edges between them. Another method of preventing mesh collapse is applying *Bending Stiffness*,
The logical method to keep a body from collapsing would be to create additional edges between the vertices. which adds rotational resistance: making edges try to keep their relative angles.
This works pretty well, but would change your mesh topology drastically.
Luckily, Blender allows to define additional *virtual* connections. Both of these methods are described in more detail below. You can configure them,
On one hand you can define virtual connections between the diagonal edges of a quad face as well as other settings, in the :doc:`Soft Body Edges panel </physics/soft_body/settings/edges>`.
(*Stiff Quads* Fig. :ref:`fig-softbody-force-interior-stiff`),
on the other hand you can define virtual connections between a vertex and any vertices connected
to its neighbors' *Bending Stiffness*. In other words, the amount of bend that is allowed between
a vertex and any other vertex that is separated by two edge connections.
Settings Stiffness
======== =========
The characteristics of edges are set with the *Springs* and *Stiff Quads* properties in the *Soft Body Edges* panel. To show the effect of the Stiffness setting, we will drop two cubes onto a plane
See the :doc:`Soft Body Edges settings </physics/soft_body/settings/edges>` for details. (see :doc:`Collisions </physics/soft_body/collision>`). The blue cube uses quads,
while the red one uses tris. Both cubes have their Goal setting disabled.
If *Stiffness* is disabled, the quad-only cube will collapse completely,
Tips: Preventing Collapse while the tri cube only temporarily deforms from the impact:
=========================
Stiff Quads
-----------
To show the effect of the different edge settings we will use two cubes
(blue: only quads, red: only tris) and let them fall without any goal onto a plane
(how to set up collision is shown on the page :doc:`Collisions </physics/soft_body/collision>`).
.. _fig-softbody-force-interior-without: .. _fig-softbody-force-interior-without:
.. list-table:: Without Stiff Quads. .. list-table:: Without Stiffness.
* - .. figure:: /images/physics_soft-body_forces_interior_quadvstri-sb-001.png * - .. figure:: /images/physics_soft-body_forces_interior_quadvstri-sb-001.png
:width: 200px :width: 200px
@ -89,13 +74,12 @@ To show the effect of the different edge settings we will use two cubes
Frame 401. Frame 401.
In Fig. :ref:`fig-softbody-force-interior-without`, the default settings are used (without *Stiff Quads*). If *Stiffness* is enabled, the quad cube maintains its shape as well thanks to the
The "quad only" cube will collapse completely, the cube composed of tris keeps its shape, extra springs:
though it will deform temporarily because of the forces created during collision.
.. _fig-softbody-force-interior-with: .. _fig-softbody-force-interior-with:
.. list-table:: With Stiff Quads. .. list-table:: With Stiffness.
* - .. figure:: /images/physics_soft-body_forces_interior_quadvstri-sb-001.png * - .. figure:: /images/physics_soft-body_forces_interior_quadvstri-sb-001.png
:width: 200px :width: 200px
@ -112,16 +96,15 @@ though it will deform temporarily because of the forces created during collision
Frame 401. Frame 401.
In Fig. :ref:`fig-softbody-force-interior-with`, *Stiff Quads* is activated (for both cubes).
Both cubes keep their shape, there is no difference for the red cube,
because it has no quads anyway.
Bending Stiffness Bending Stiffness
----------------- =================
The second method to stop an object from collapsing is to change its *Bending* stiffness. The second method to stop an object from collapsing is to give it *Bending Stiffness.*
This includes the diagonal edges (damping also applies to these connections). Just like the other settings, this can be combined with *Stiffness* to add bending
resistance to the diagonal springs as well.
We first do the same cube experiment as before, using only *Bending Stiffness*:
.. _fig-softbody-force-interior-bending: .. _fig-softbody-force-interior-bending:
@ -142,15 +125,15 @@ This includes the diagonal edges (damping also applies to these connections).
Frame 401. Frame 401.
In Fig. :ref:`fig-softbody-force-interior-bending`, *Bending* is activated with a strength setting of 1. Both cubes keep their shape. Now, we try the same thing with subdivided planes,
Now both cubes are more rigid. again a quad-based one and a triangulated one:
.. list-table:: .. list-table::
* - .. figure:: /images/physics_soft-body_forces_interior_quadvstri-bending-001.png * - .. figure:: /images/physics_soft-body_forces_interior_quadvstri-bending-001.png
:width: 200px :width: 200px
Two planes going to collide. Two planes falling.
- .. _fig-softbody-force-interior-no-bending: - .. _fig-softbody-force-interior-no-bending:
@ -164,10 +147,8 @@ Now both cubes are more rigid.
High bending stiffness (10). High bending stiffness (10).
Bending stiffness can also be used if you want to make a subdivided plane more plank like. Without any *Bending Stiffness*, the faces can rotate freely as though their edges were hinges.
Without *Bending* the faces can freely rotate against each other like hinges Enabling *Stiffness* to add diagional springs would not change this (just as triangulating doesn't).
Fig. :ref:`fig-softbody-force-interior-no-bending`.
There would be no change in the simulation if you activated *Stiff Quads*,
because the faces are not deformed at all in this example.
Bending stiffness is the strength needed for the plane to be deformed. With a high *Bending Stiffness*, however, the edges resist this rotation, and the planes
act more like planks than towels.