+$3D rigging, like other CGI techniques, can be confusing to newcomers. This guide aims to break it down so that every artist can learn how to rig a 3D model.
+$A lot of time creating3D艺术+$is spent on how the shell of an object looks. This is great for stills, but when animating, it is just as important to concentrate on where the movement comes from. For most objects, creatures and characters, this is from within.
+$There is no getting around the fact that rigs are one of the most complex systems in CGI, and like most tools in CGI there is not, unfortunately, a unified workflow between the major applications (see our list of the最好的3D软件）。
+$That being said the principles of animating a rig are reasonably similar, and processes like forward kinematics (FK), where a joint chain animation originates from the base joint (such as the shoulder of an arm), and inverse kinematics (IK), where the animation of an arm would originate from the tips of the fingers, are universal principles that can be applied across applications.
+$Let’s take a look at some more of the basics of 3D or animation rigging.
+$What is 3D rigging?
+$3D rigging is in effect the process of creating an invisible skeleton that defines how an object moves. An animation or 3D rig usually comprises a system of ‘invisible’ objects that can be seen in a 3D viewport but not in a final render.
+$At the most basic level, these objects are nulls/groups and joints. Joints are objects that essentially act as the bones of the skeleton, where the nulls/groups/ targets act as the cartilage to define the range of movement. Nulls can also create controllers that are tied to specific objects within a skeleton, to allow an artist to move and control elements much more easily than actually trying to select the specific points themselves.
+$When parented correctly, a joint and null system creates a logical way of moving elements, and when this system is bound to an organic mesh it can create a convincing range of movements. 3D rigs can work just as well with hard-bodied systems such as cars, where controllers can be an invaluable part of an animation setup.
+$Rigging A Character
+$A typical animation/3D rig for a humanoid form will consist of parented joints or bones, which act as a basic skeleton.
+$These joints are controlled by a series of nulls that allow an artist to manipulate the model in a more logical fashion than by animating each joint. Always remember when rigging characters to have the model and rig in a neutral pose, such as a T-pose.
+$Creating Hard-body Rigs
+$Hard-bodied objects can be animated with a rig as well, but this depends on a logical parenting of objects and control nulls. While joints can be used, they tend not to be used as much in hard-bodied rigs.
+$A good example of a hard-bodied rig is a car rig, such as the one shown for Cinema 4D by Ahmed El-Hofy (above) that provides a single control for steering and spins the wheels at the correct speed. These sort of rigs can be as complex or as simple as required by the need of the shot.
+$Binding A Mesh
+$After creating an animation rig, it is not always obvious how to connect it to the geometry that needs to be animated.
+$This is not achieved by just parenting an object, the mesh needs to be attached via a binding process where the 3D applications apply the rig to various elements throughout the rig, which can be modified after the binding process through weights and constraints. These controls differ between each application, but the underlying process is the same.
+$Inverse and forward kinematics
+$These define the direction a rig works in when it is being animated. Forward kinematics are the most logical for newcomers, controlling the movement of the rig from the base joint in the process, such as the shoulder or hip joint.
+$Forward kinematics can require a lot of work if a character needs to sit, whereas with inverse kinematics creating a sitting animation is easy – the rig is controlled by the end points such as the feet or hands, and works backwards through the rig.