Places and links the selected object to the current curve. The current curve becomes the motion path.
Opens the Attach to Motion Path Options.
Specifies the method Maya uses to position an object as it moves along a curve. There are two methods: the parametric space method and the parametric length method.
In the parametric space method, the markers represent positions in the U-parameter space of the curve. In the parametric length method, the markers represent positions as a percentage of the total curve length. The parametric length method is also known as the “fraction mode” method because the evaluation of the path is based on a fraction of the length of the path curve.
To understand the difference between the two methods, consider a curve that has uniform parameterization and unevenly spaced CVs.
The curve above was created with five CVs and uniform knot spacing. The beginning of the curve is at U=0.0 and the end of the curve is at U=2.0. The cone was animated with path animation from time 1 to 30.
If the path animation for the cone is created with the parametric length method, the cone will move evenly along the curve from times 1 to 30.
If the path animation for the cone is created with the parametric space method, the cone moves quickly from the first to the second CV, then slowly through the second to fourth CV, then quickly again from the fourth to fifth CV. This is because the second and fourth CVs are positioned at approximately U=0.5 and U=1.5 parameterization points of the curve. These points take up half the total parameterization of the curve.
In parameter space, the object moves smoothly from U=0.0 to U=2.0. In world space, there is little movement of the object from (roughly) times 8 to 23, which coincide with the large parameter distance that must be covered in the correspondingly small curve length.
The advantage of using the parametric space method is that if you have spent time adjusting the timing of the object’s movement along the curve, CVs can be added to the beginning or end of the curve without affecting the timing of the motion on the existing part of the curve.
The advantage of using the parametric length method is that it is easy to obtain smooth timing of the object’s motion without having to insert timing markers to refine the timing of the object along the path curve.
Turning off Parametric Length selects the parametric space method. Turning on Parametric Length selects the parametric length method.
If on, Maya computes the object’s orientation as it moves along the curve. It is on by default.
Maya uses a front vector and an up vector to compute the orientation of the object. Maya aligns the object’s local axes with the front vector and the up vector so that it knows how the object should be pointing upwards and frontwards as it moves along the curve.
At any point along the curve, the front vector aligns with the tangent to the curve, pointing in the direction of movement. The up vector is perpendicular to the tangent, but you must still tell Maya which perpendicular direction from the tangent is the up direction that you want. To do so, you specify a world up vector with which the up vector aligns. Use the World Up Type, World Up Vector, and World Up Object options to specify the world up vector.
You need to tell Maya which of the object’s local axes should be aligned with the front vector, and which should be aligned with the up vector. To view the object’s local axes, select the object and select Display > Component Display > Local Rotation Axes. Next, specify which local axis aligns with the front vector with Front Axis. Also specify which local axis aligns with the up vector with Up Axis. Finally, you specify the type of world up vector (World Up Type) with which the up vector itself aligns.
The world up vector gives you the ability to control what the up vector considers to be the up direction. One benefit of this is that you can correct any sudden flipping problems as the object moves along the curve. For example, you can have the world up vector be the local axis of some other object such as a locator. You can then directly control the orientation of the world up vector by manipulating the locator.
Specifies which of the object’s local axes aligns with the front vector. This specifies the frontwards orientation of the object as it travels along the curve.
X aligns the local X axis with the front vector, specifying the X axis as the forward facing axis of the object.
Y aligns the local Y axis with the front vector, specifying the Y axis as the forward facing axis of the object.
Z aligns the local Z axis with the front vector, specifying the Z axis as the forward facing axis of the object.
Specifies which of the object’s local axes aligns with the up vector. This specifies the upwards orientation of the object as it travels along the curve. The up vector aligns with the world up vector specified by the World Up Type.
X aligns the local X axis with the up vector, specifying the X axis as the upward facing axis of the object.
Y aligns the local Y axis with the front vector, specifying the Y axis as the upward facing axis of the object.
Z aligns the local Z axis with the front vector, specifying the Z axis as the upward facing axis of the object.
Specifies the type of world up vector that the up vector aligns with. Selections include Scene Up, Object Up, Object Rotation Up, Vector, and Normal.
specifies that the up vector try to aim at the origin of a specified object instead of aligning with the world up vector. The world up vector is ignored. The object whose origin the up vector tries to aim at is called the world up object. You can specify the world up object with the World Up Object option. If no world up object is specified, the up vector tries to aim at the origin of the scene’s world space.
specifies that the world up vector is defined relative to some object’s local space instead of the scene’s world space. The up vector tries to align with the world up vector after transforming it relative to the scene’s world space. The object whose origin the up vector tries to aim at is called the world up object. You can specify the world up object with the World Up Object option.
specifies that the axis specified by Up Axis will try to match the normal to the path curve. The interpretation of the curve normal is different depending on whether the path curve is a curve in world space, or a curve on surface curve.
If the path curve is a curve in world space, then the normal of the curve is the direction that points to the center of curvature of the curve at any point on the curve. This is best illustrated by the arrows in the diagram below, which indicate the normal to the curve at various points:
Note that the normal to a curve will flip 180 degrees when the curve changes from a convex to concave (or vice versa) shape. This makes the Normal option for the Up Direction not very desirable when using a world-space curve in your path animation.
If the path curve is a curve-on-surface, then the normal to the curve is the normal to the surface at that point on the curve. The Normal option will give the most intuitive results when the path curve is a curve-on-surface.
Reverses the frontwards direction an object is pointing along the curve. This is especially useful when you are trying to orient a camera so that it points frontwards along a curve. For example, you have got the camera pointing backwards along the curve, but are having difficulty getting the camera to point frontwards. By clicking Inverse Front on, you can have the camera point forwards along the curve as desired.
Banking means the object will lean in towards the center of the curvature of the curve that it travels along (like a motorcycle going around a corner). The bank option is only available if the Follow option is on, as banking also affects the rotations of the object.
The path animation automatically computes how much banking should occur depending on how curved the path curve is. You can adjust the banking using Bank Scale and Bank Limit.
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