示例#1
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  /**
   * Calculates the result of concatenating this Rotation with a given Rotation.
   *
   * @param rotation The rotation to be appended to this Rotation.
   * @return The Rotation resulting from the concatenation of this Rotation and the given Rotation.
   */
  public Rotation append(Rotation rotation) {
    // multiply this rotation's quaternion with the given rotation's quaternion
    Quaternion product = this.quaternion.multiply(rotation.getQuaternion());

    // create and return new Rotation object using the calculated quaternion
    return new Rotation(product);
  }
示例#2
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  /**
   * Rotates this camera by a given amount. If <code>relative</code> is set to <code>true</code>
   * then the rotation will be performed relative to this camera's current orientation. Otherwise,
   * the rotation will be performed relative to the world coordinate system.
   *
   * <p>If this camera's focus is locked, then only rotation about the z axis (roll) will be
   * performed.
   *
   * @param rotation The amount of rotation to be applied to this camera.
   * @param relative A boolean flag stating whether the rotation performed should be relative to
   *     this camera's current orientation.
   */
  public void rotate(Rotation rotation, boolean relative) {
    // store current focus point
    Vector3D focusPoint = getFocusPoint();

    // perform rotation
    if (relative) super.setOrientation(getOrientation().append(rotation));
    else super.setOrientation(rotation.append(getOrientation()));

    // if focus is locked, look at the point of focus
    if (focusLocked) lookAt(focusPoint);
  }
示例#3
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  /**
   * Interpolates between this Rotation and a given Rotation by a given interpolation factor.
   *
   * @param rotation The terminal point of interpolation.
   * @param factor The interpolation factor. This value will be clamped to the range [0.0, 1.0].
   */
  public Rotation slerp(Rotation rotation, double factor) {
    // store quaternion components for easy access
    Quaternion startQuat = this.quaternion;
    Quaternion endQuat = rotation.getQuaternion();
    double x1 = startQuat.getX();
    double y1 = startQuat.getY();
    double z1 = startQuat.getZ();
    double w1 = startQuat.getW();
    double x2 = endQuat.getX();
    double y2 = endQuat.getY();
    double z2 = endQuat.getZ();
    double w2 = endQuat.getW();

    // calculate angle between start and end
    double cosHalfTheta = w1 * w2 + x1 * x2 + y1 * y2 + z1 * z2;

    // if start=end or start=-end, we can return start
    if (Math.abs(cosHalfTheta) >= 1.0) return this;

    // calculate temporary values
    double halfTheta = Math.acos(cosHalfTheta);
    double sinHalfTheta = Math.sqrt(1.0 - cosHalfTheta * cosHalfTheta);

    // if theta is 180°, then the result is not fully defined
    // we could rotate around any axis normal to start or end
    if (Math.abs(sinHalfTheta) < 0.001) {
      Vector3D v1 = startQuat.vectorComponent();
      Vector3D v2 = endQuat.vectorComponent();
      Vector3D vect = v1.add(v2).multiply(0.5);
      double scalar = (w1 + w2) * 0.5;
      return new Rotation(new Quaternion(vect, scalar));
    }

    double ratioA = Math.sin((1 - factor) * halfTheta) / sinHalfTheta;
    double ratioB = Math.sin(factor * halfTheta) / sinHalfTheta;

    // compute and return quaternion
    Vector3D v1 = startQuat.vectorComponent();
    Vector3D v2 = endQuat.vectorComponent();
    Vector3D vect = v1.multiply(ratioA).add((v2).multiply(ratioB));
    double scalar = (w1 * ratioA) + (w2 * ratioB);
    return new Rotation(new Quaternion(vect, scalar));
  }
示例#4
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  /**
   * Rotates this camera by a given amount around a given point. The rotation will be performed
   * relative to the world coordinate system. If the <cod>reorient</code> flag is set to <code>true
   * </code>, then the rotation will be applied as a standard rotational transformation would;
   * altering this camera's orientation. If set to <code>false</code>, this camera's orientation
   * will remain unchanged as the rotation is performed.
   *
   * <p>Note that the camera will maintain focus if the camera's focus is locked.
   *
   * @param rotation The amount of rotation to be applied to this camera.
   * @param point The point, in the world coordinate system, about which the rotation will occur.
   * @param reorient A flag stating whether or not to alter this camera's orientation as with the
   *     applied rotation.
   */
  public void rotate(Rotation rotation, Vector3D point, boolean reorient) {
    // store current focus point
    Vector3D focusPoint = getFocusPoint();

    // find vector between given point and camera, in local coordinates
    Vector3D vect = getPosition().subtract(point);

    // move camera to given point
    super.setPosition(point);

    // rotate camera for standard rotation
    if (reorient) super.setOrientation(rotation.append(getOrientation()));

    // rotate vector
    vect = vect.rotate(rotation);

    // move back to proper position
    super.setPosition(getPosition().add(vect));

    // if focus is locked, look at original focus point
    if (focusLocked) lookAt(focusPoint);
  }