Ejemplo n.º 1
0
  /**
   * Causes the View attached to the specified WorldWindow to animate to the specified sector. The
   * View starts animating at its current location and stops when the sector fills the window.
   *
   * @param wwd the WorldWindow who's View animates.
   * @param sector the sector to go to.
   * @throws IllegalArgumentException if either the <code>wwd</code> or the <code>sector</code> are
   *     <code>null</code>.
   */
  public static void goTo(WorldWindow wwd, Sector sector) {
    if (wwd == null) {
      String message = Logging.getMessage("nullValue.WorldWindow");
      Logging.logger().severe(message);
      throw new IllegalArgumentException(message);
    }

    if (sector == null) {
      String message = Logging.getMessage("nullValue.SectorIsNull");
      Logging.logger().severe(message);
      throw new IllegalArgumentException(message);
    }

    // Create a bounding box for the specified sector in order to estimate its size in model
    // coordinates.
    Box extent =
        Sector.computeBoundingBox(
            wwd.getModel().getGlobe(), wwd.getSceneController().getVerticalExaggeration(), sector);

    // Estimate the distance between the center position and the eye position that is necessary to
    // cause the sector to
    // fill a viewport with the specified field of view. Note that we change the distance between
    // the center and eye
    // position here, and leave the field of view constant.
    Angle fov = wwd.getView().getFieldOfView();
    double zoom = extent.getRadius() / fov.cosHalfAngle() / fov.tanHalfAngle();

    // Configure OrbitView to look at the center of the sector from our estimated distance. This
    // causes OrbitView to
    // animate to the specified position over several seconds. To affect this change immediately use
    // the following:
    // ((OrbitView) wwd.getView()).setCenterPosition(new Position(sector.getCentroid(), 0d));
    // ((OrbitView) wwd.getView()).setZoom(zoom);
    wwd.getView().goTo(new Position(sector.getCentroid(), 0d), zoom);
  }
  protected Box computeExtent(Globe globe, double verticalExaggeration) {
    List<Vec4> points = this.computeMinimalGeometry(globe, verticalExaggeration);
    if (points == null || points.isEmpty()) return null;

    // A bounding box typically provides a better fit for a partial capped cylinder than a bounding
    // cylinder.
    return Box.computeBoundingBox(points);
  }
Ejemplo n.º 3
0
  protected Extent computeExtent(Globe globe, double verticalExaggeration) {
    List<Vec4> points = this.computeMinimalGeometry(globe, verticalExaggeration);
    if (points == null || points.isEmpty()) return null;

    // Add a point at the center of this polygon to the points used to compute its extent. The
    // center point captures
    // the curvature of the globe when the polygon's minimal geometry only contain any points near
    // the polygon's
    // edges.
    Vec4 centerPoint = Vec4.computeAveragePoint(points);
    LatLon centerLocation = globe.computePositionFromPoint(centerPoint);
    this.makeExtremePoints(globe, verticalExaggeration, Arrays.asList(centerLocation), points);

    return Box.computeBoundingBox(points);
  }
Ejemplo n.º 4
0
  protected Extent computeExtent(Globe globe, double verticalExaggeration) {
    List<Layer> cakeLayers = this.getLayers();

    if (cakeLayers == null || cakeLayers.isEmpty()) {
      return null;
    } else if (cakeLayers.size() == 1) {
      return cakeLayers.get(0).computeExtent(globe, verticalExaggeration);
    } else {
      ArrayList<Box> extents = new ArrayList<Box>();

      for (Layer layer : cakeLayers) {
        extents.add(layer.computeExtent(globe, verticalExaggeration));
      }

      return Box.union(extents);
    }
  }