XML:OBAN: Difference between revisions

OBAN : Object Animation	XML modding tips See HERE to start learning about XML modding. See HERE if you are searching for information on how to handle object coordinates. See HERE for some typical modding errors and their causes.
XML Mtrl << Other file types >> OFGA switch to OBD page

General information

• The XML on this page was tested with OniSplit v0.9.61.0, v0.9.68.0, v0.9.82.0, v0.9.96.0.
  • With v0.9.82.0, you can also convert the OBAN into a DAE file:

"-extract:dae output src\OBANElevator.oni" exports the animation with a null node

In Mod Tool the null node is named "unique" and holds keyframes; it can be replicated with activesceneroot.AddModel , "unique"

"-extract:dae output src\OBANElevator.oni -geom:M3GMdebris.oni" exports animation with specified geometry

"-extract:dae output src\OBANElevator.oni -geom:camera" exports animation with camera

• With v0.9.90.0, you can convert a camera DAE to OBAN (a camera root is not supported)

"-create:oban output src\file.dae"

• Laser trigger and door files use global OBANs.
• Some cutscene TRAMs, animated cutscene objects and camera shots/animations use level-specific OBANs.
• If you want to update level-specific OBANs used by an ONLV, you must provide the ONLV along with the OBANs in the package.
• Trivia: the Dream Lab images use OBANs.
• Tutorial: Creating camera animations

BSL support

XML structure

Transform matrices

Like all matrices in Oni, they are composed of 3 vectors defining rotation/scaling/shearing and a 4th vector defining a translation.

In the above table, the 4 vectors are presented as rows per Direct3D convention, although OpenGL and Oni use them as columns.

Affine transformations use a 4x4 matrix with 4 extra coefficients (in the presentation above, one would add one column on the right):

Three projection transform coefficients (all of them are zero here); one final coefficient (always 1.0 for an affine transform matrix).

Alternately, one can think of the 3x4 matrix as a 3x3 rotation/scaling matrix and a position vector:

• Let X=(x, y, z) be the position of a vertex in the M3GM
• Let M=(m11, m21, m31; m12, m22, m32; m13, m23, m33) be the 3x3 matrix
• Let R=(m14, m24, m34) be the translation vector

Then the absolute position of the vertex in the 3D world will be: X M + R

(left multiplication is used because of the row-major notation above)

Initial transform matrix

It is used to position the object in the environment before the animation is played.

When the animation is played, they use the fixed transform matrix and a quaternion.

Fixed transform matrix

This transformation is applied before the quaternion+position transform at every keyframe.

The only transform that can't be handled by the quaternion+position is scaling/mirroring.

Thus, the fixed transform is a scaling matrix most of the time (no rotation or translation).

In the example on the OBD page, the fixed transform scales the van up by 1.82 (along all three axes).

Quaternions

Those are used in Oni whenever interpolation of 3D rotation is involved (e.g. TRAM rotation).

In this case, the rotation in intermediate frames is interpolated from the keyframe quaternions.

XML sample

Below, [...] means other blocks of <OBANKeyFrame>...</OBANKeyFrame>.

<?xml version="1.0" encoding="utf-8"?>
<Oni>
   <OBAN id="0">
       <Flags></Flags>
       <InitialTransform>1 0 0 0 1 0 0 0 1 -225 9.3 -778.5</InitialTransform>
       <BaseTransform>-1 0 0 0 -1 0 0 0 1 0 0 0</BaseTransform>
       <FrameLength>80</FrameLength>
       <FrameCount>71</FrameCount>
       <HalfStopFrame>0</HalfStopFrame>
       <KeyFrames>
           <OBANKeyFrame>
               <Rotation>1 1 1 1</Rotation>
               <Translation>-225 9.3 -778.5</Translation>
               <Time>0</Time>
           </OBANKeyFrame>
           [...]
           <OBANKeyFrame>
               <Rotation>1 1 1 1</Rotation>
               <Translation>-217 34.5 -778.5</Translation>
               <Time>70</Time>
           </OBANKeyFrame>
       </KeyFrames>
   </OBAN>
</Oni>

Calculating a quaternion

An early attempt to harvest quaternions and positions from TRAM files with OniSplit v0.9.54.0 can be found over here. But that script runs inside an Excel file, and Excel isn't a free program, nor is the code compatible with OpenOffice.

VBS code snippets for use with Mod Tool can be found here:

• Euler rotation to quaternion
• quaternion to Euler rotation

Calculating a transform matrix

In some scenarios we need to build a new transform matrix, e.g. when making a new weapon particle emitter. The first 9 values belong to a 3x3 rotation matrix. The last 3 values are the start positions.

Single rotation matrices
${\displaystyle R_{x}(\theta )={\begin{bmatrix}\color {Salmon}1&\color {YellowGreen}0&\color {CornflowerBlue}0\\\color {Salmon}0&\color {YellowGreen}\cos \theta &\color {CornflowerBlue}-\sin \theta \\\color {Salmon}0&\color {YellowGreen}\sin \theta &\color {CornflowerBlue}\cos \theta \end{bmatrix}}}$

x = 60

<InitialTransform>1 0 0 0 0.5    0.8660254 0 -0.8660254 0.5    0 0 0</InitialTransform>
                  1 0 0 0 cos(x) sin(x)    0 -sin(x)    cos(x)

y = 60

${\displaystyle R_{x}(\theta )={\begin{bmatrix}\color {YellowOrange}\cos \theta &\color {SpringGreen}0&\color {ProcessBlue}\sin \theta \\\color {YellowOrange}0&\color {SpringGreen}1&\color {ProcessBlue}0\\\color {YellowOrange}-\sin \theta &\color {SpringGreen}0&\color {ProcessBlue}\cos \theta \end{bmatrix}}}$

<InitialTransform>0.5    0 -0.8660254 0 1 0 0.8660254 0 0.5    0 0 0</InitialTransform>
                  cos(y) 0 -sin(y)    0 1 0 sin(y)    0 cos(y)

z = 60

${\displaystyle R_{x}(\theta )={\begin{bmatrix}\color {OrangeRed}1&\color {SeaGreen}0&\color {RoyalBlue}0\\\color {OrangeRed}0&\color {SeaGreen}\cos \theta &\color {RoyalBlue}-\sin \theta \\\color {OrangeRed}0&\color {SeaGreen}\sin \theta &\color {RoyalBlue}\cos \theta \end{bmatrix}}}$

<InitialTransform>0.5    0.8660254 0 -0.8660254 0.5    0 0 0 1 0 0 0</InitialTransform>
                  cos(z) sin(z)    0 -sin(z)    cos(z) 0 0 0 1

The final rotation matrix becomes calculated from multiplication of all single rotation matrices whereby the order must be Z, then Y, then X.

Rotation matrix Z * rotation matrix Y * Rotation matrix X

So the transform matrix is:

final rotation matrix; position X; position Y; position Z

Mod Tool VBS code (rotations only):

• Euler rotation to matrix
• matrix to Euler rotation

Wish list

• TRAM import: DAE + XML. The DAE section in the XML file should have an option to create a pelvis OBAN along with the TRAM (see XML:TRAM's RealWorld flag for details).
• DAE to .oni creation should also allow for OBANs (currently OBANs can only be imported via the level's master XML file). This would be very useful for editing/creating single OBAN files if the rest of the level doesn't need changes.