Scene graph for defining a stereoscopic graphical object

The invention claimed is: 1. A method for generating a stereoscopic graphical object, the method comprising: receiving a user input specifying a base image and a dependent image to be used for generating the stereoscopic graphical object; receiving a user input specifying a spatial and a temporal arrangement of image data of the base image and the dependent image to be used for generating the stereographic graphical object; arranging information about image data for the base image, image data for the dependent image, and the spatial and the temporal arrangement of the base image and the dependent image in a scene graph; and storing the image data for the base image, the image data for the dependent image, and the scene graph on a non-transitory storage medium, wherein the scene graph specifies: a first arrangement of the image data for the base image for generating a monoscopic version of the stereoscopic graphical object; a second arrangement of the image data of the base image and the image data of the dependent image for generating a stereoscopic version of the stereoscopic graphical object; the scene graph enabling switchable rendering between the stereoscopic version of the stereoscopic graphical object and the monoscopic version of the stereoscopic graphical object without re-initializing a graphics rendering module. 2. The method according to claim 1 , further comprising; arranging the image data for the base image in a base image mosaic or arranging the image data for the dependent image in a dependent image mosaic; and storing the base image mosaic and the dependent image mosaic on the non-transitory storage medium. 3. An apparatus for generating a stereoscopic graphical object, wherein the apparatus is configured to: receive a user input specifying a base image and a dependent image to be used for generating the stereoscopic graphical object; receive a user input specifying a spatial and a temporal arrangement of image data of the base image and the dependent image to be used for generating said stereoscopic graphical object; arrange information about image data for the base image, image data for the dependent image, and the spatial and the temporal arrangement of the base image and the dependent image in a scene graph; and store the image data for the base image, the image data for the dependent image, and the scene graph on the non-transitory storage medium, wherein the scene graph specifies: a first arrangement of the image data for the base image for generating a monoscopic version of the stereoscopic graphical object; a second arrangement of the image data of the base image and the image data of the dependent image for generating a stereoscopic version of the stereoscopic graphical object the scene graph enabling a switchable rendering between the stereoscopic version of the stereoscopic graphical object and the monoscopic version of the stereoscopic graphical object absent without re-initializing a graphics rendering module. 4. The apparatus according to claim 3 , wherein the apparatus is further configured to: arrange the image data for the base image in a base image mosaic and to arrange the image data for the dependent image in a dependent image mosaic; and store the base image mosaic and the dependent image mosaic on the non-transitory storage medium. 5. A method for initializing a rendering module, which is switchable between a 3D rendering mode and a 2D rendering mode, and whose output is fed to a graphics subsystem, the method comprising: determining whether rendering in the 3D rendering mode is possible in an execution environment of the rendering module; and on a condition that rendering in the 3D rendering mode is possible in the execution environment of the rendering module, initializing the rendering module independent of a current rendering mode of the graphics subsystem by allocating a first back buffer to generate a 3D output and a second back buffer to generate a 2D output in a memory for the rendering module, wherein re-initialization of the rendering module is unnecessary when switching between the 3D rendering mode and the 2D rendering mode. 6. The method of claim 5 , wherein the first and second back buffers are allocated during 2D rendering mode when the 3D rendering mode is possible. 7. A non-transitory storage medium comprising an application including a rendering module, which is switchable between a 3D rendering mode and a 2D rendering mode, and whose output is to be fed to a graphics subsystem, wherein the application is configured to perform: determining whether rendering in the 3D rendering mode is possible in an execution environment of the rendering module; and on a condition that rendering in the 3D rendering mode is possible in the execution environment of the rendering module, initializing the rendering module independent of a current rendering mode of the graphics subsystem by allocating a first back buffer for generating a 3D output and a second back buffer for generating a 2D output in a memory for the rendering module, wherein re-initialization of the rendering module is unnecessary when switching between the 3D rendering mode and the 2D rendering mode. 8. The non-transitory storage medium according to claim 7 , wherein the first and second back buffers are allocated during 2D rendering mode when the 3D rendering mode is possible.