The objective of this repository is to propose a Unity3D module which allows to realize a camera trajectory tracking of an object by providing only a limited amount of information, namely a few points.

figure: an example of a camera tracking

• Create a basic 3D Unity project
• Add the script "trajectoire.cs" in the project assets
  • Add to the object "Main Camera" the component (scripts) "trajectoire.cs"
• Place an object in the scene: the subject
  • Create a tag "sujet"
  • Assign to this object the tag "sujet"
• Add observers around the object (e.g. 4 balls forming a square around the subject)
  • Create a tag "points"
  • Assign to all observers the tag "points"
• Play

The trajectory of the camera will be modeled by a spline model (approximation) from control points previously defined. The rotations of the camera will be calculated by a model of quaternions and a spherical approximation. These choices are justified by the nature we wanted to give to our project. We wish to model a camera tracking around a fixed subject for several observers distributed in the scene.

Scene description	Camera trajectory computing

The modeling of an approximating or interpolating curve by a single polynomial presents many disadvantages for our camera movement. In the case where the degree of the curve is high we end up with very few shape effects, which makes the movement monotomous. We also want to have local control the trajectory points. This is not possible with this kind of model. The oscillations that these polynomials can cause unstability. A closed spline model avoids all these problems!

Concerning the splines part, we used the B-splines algorithm. This subdivision method is divided into 2 steps:

• Duplicate the control points
• Take n times (n the degree) the middle of two consecutive points in the control polynomial.

This algorithm allows us to obtain the set of points which constitutes the closing curve. Concerning the quaternion part, we used a method provided by Unity "LookRotation". This method allows to obtain the rotation vector. Using these two algorithms, we obtain the desired result.