Abstract:
Standard video footage even from a single video camera can be used to obtain, in an automated fashion, a stroboscope sequence of a sports event, for example. The sequence may be represented as a static images of a photographic nature, or by a video sequence in which camera motion remains present, in which case the video sequence can be rendered as a panning camera movement on a stroboscope picture or as an animated stroboscope sequence in which the moving object leaves a trailing trace of copies along its path. Multiple cameras can be used for an expanded field of view or for comparison of multiple sequences, for example.

Description:
The present invention claims priority to provisional application Ser. No. 60/195,233, filed on Apr. 7, 2000. 

   TECHNICAL FIELD 
   The present invention is concerned with techniques for generating stroboscopic images. 
   BACKGROUND OF THE INVENTION 
   A stroboscope is a device for analyzing fast motions; because of the latency properties in the human retina, a moving object seen through a rapidly switching shutter is perceived as a series of static images along the object&#39;s trajectory. In photography, a stroboscope effect can be achieved by repeatedly exposing the same film by means of a periodically switching shutter, to obtain, in the final image, repeated copies of the object along its trajectory. The same effects are achieved if, in lieu of a repeatedly switching shutter, a repeatedly switching illumination source is used. Such an illumination source is usually called a “strobo-light”. 
   In sports events, stroboscope techniques are of interest for analyzing the evolution over time and space of an athlete&#39;s gesture or stance, or other kinds of motion such as object trajectories, e.g. of balls, racquets, clubs and the like. Static photographic techniques are already in use, providing a “visual synopsis” of a fast sport action such as the 100 meter dash, for instance. Since, typically, the field of view of a static photographic camera cannot encompass the entire spatial extent of the athlete&#39;s course, relatively cumbersome solutions have been employed, in which several cameras are placed along the path of the athlete and synchronized so as to take a shot of the path when the athlete passes by. The resulting successive images can be joined together to compose a global view of the event in space and time. 
   SUMMARY OF THE INVENTION 
   We have recognized that standard video footage even from a single video camera can be used to obtain, in an automated fashion, a generalized stroboscope sequence of a sports event, for example. The notion of a generalized stroboscope sequence includes a static image of photographic nature, e.g. of the type generated by known stroboscoping techniques as described above. Also, a generalized stroboscope sequence can be a video sequence in which camera motion remains present, in which case the video sequence can be rendered as a panning camera movement on a stroboscope picture or as an animated stroboscope sequence in which the moving object leaves a trailing trace of copies along its path. Multiple cameras can be used for an expanded field of view or for comparison of multiple sequences, for example. 

   
     BRIEF DESCRIPTION OF THE DRAWING 
       FIG. 1  is a schematic block diagram of apparatus for automated stroboscoping. 
       FIGS. 2   a – 2   c  are frames from a stroboscoping sequence of an ice skating toe-loop triple jump. 
       FIG. 3  is a stroboscoping image of an ice skating pair throw jump. 
       FIGS. 4   a – 4   c  are frames from a stroboscoping sequence of a soccer event. 
   

   DETAILED DESCRIPTION 
     FIG. 1  shows exemplary apparatus for producing a stroboscope sequence from a single-source video sequence in accordance with a preferred embodiment of the invention. 
   The video sequence from a standard camera is fed to a Background-Foreground Extraction Module  101  for separating the video information into a sequence/stream BG of background images and a sequence/stream FG of foreground images, with one background image and one foreground image for each frame of the original video sequence. 
   The same video sequence is fed also to a Camera Motion Estimation Module  102  for extracting a stream MP of camera motion parameters. If the camera is equipped with motion tracking sensors, the Module  102  can receive an additional input from the camera. 
   The foreground video information stream FG is fed to a Triggering Module  110 , for selecting from the stream FG multiple instances FG 1  of representations of one or several foreground features to appear in the stroboscoping sequence, e.g. objects, individuals, body parts or outlines. For example, in a soccer game the ball and one or several players may be chosen for stroboscoping. For the ball, stroboscoping may be of interest for each frame, while copies of players may be placed only at key instants in the action. Thus, at different triggering instants the selection of features can differ as to their number and quality. 
   The foreground images FG 1  together with the stream of background images BG and the motion parameters MP are further processed by a Synthesis Module  120  which, according to a prescribed stroboscoping strategy, processes the visual information in the streams FG 1  and BG to produce streams FG 2  and BG 2  in which a composite parametric description of the stroboscope sequence is embedded. 
   Finally, following a prescribed rendering strategy, a Rendering Module  130  transforms the embedded representation and the visual information of the streams FG 2  and BG 2  into an output sequence suitable for display on a video device or photographic print medium. 
   The Foreground Extraction Module  101 , Camera Estimation Module  102 , Triggering Module  110 , Synthesis Module  120  and Rendering Module  130  are described below in further detail. 
   A. Background-Foreground Extraction and Motion Parameter Modules 
   First in producing a stroboscope sequence, in foreground-background estimation, objects moving in the foreground are segmented from the background, and, unless known from camera instruments, the camera motion parameters are estimated. Foreground-background estimation identifies the moving object(s) in the video frames, e.g. the foreground athlete(s) and equipment (e.g. a soccer ball) versus the background sport field. The motion parameters provide for a common visual referential for the video sequence, so as to enable blending together successive frames of the video sequence. Foreground-background and camera motion estimation can be carried out using established video processing techniques, in partially or fully automated fashion. 
   B. Triggering Module 
   The Triggering Module  110  serves for selecting those foreground features which will be inserted in the stroboscope sequence. Such selection can proceed according to one of the following strategies: 
   1. Frame-based triggering, in which foreground features are selected at fixed frame intervals, say every n frames. 
   2. Time-based triggering, in which foreground features are selected at fixed time intervals, say every t seconds. 
   3. Spatial triggering, in which foreground features are selected when in alignment with pre-specified locations in the background. 
   4. Event-based triggering, in which foreground features are selected when a specific action takes place (e.g. each time an athlete touches down in a triple jump). 
   5. User-defined triggering strategy, in which foreground features are selected ad-hoc as desired, e.g. involving a user clicking on features in frames. 
   C. Synthesis Module 
   The Synthesis Module  120  serves for the registering, pre-processing and re-framing of the selected foreground features and the background visual information. As the stroboscope process results in a composite picture or video sequence in which visual information from different instants in time is compounded, pre-processing serves to establish a common visual referential for the composite images. Such pre-processing includes the computation of a common focal plane, the construction of a composite background image, and the warping of the foreground features onto the chosen focal plane. These computations are performed according to a given synthesis strategy, such as: 
   1. Wide angle synthesis, in which the field of view is expanded to encompass a pre-defined portion of the foreground motion; e.g, in triple jump the field of view can be expanded to ensure that the whole excursion of the final jump fits on the field of view; 
   2. Narrow angle synthesis, in which a wide-angle shot of an event (e.g. a horse race such as steeple chase) is narrowed to encompass a user-defined portion of the background where the action is taking place; 
   3. Global synthesis, in which the field of view is determined so as to encompass the entire course of the foreground movement; e.g., in triple jump the field of view can be expanded to ensure that the leading run and all the jumps fit within the field of view. 
   D. Rendering Module 
   Once the synthesis parameters have been computed, the stroboscope sequence is created as a visual image by the Rendering Module  130  which can employ one of the following rendering strategies to produce either a video sequence or a static image: 
   1. Still picture stroboscoping, used to generate a single image from the video sequence, in which the field of view is in accordance with the synthesis strategy of module  120 , and in which the selected foreground features are inserted in the common reconstructed background; 
   2. Scanned stroboscoping, used to generate a video sequence from a still picture stroboscoping image obtained as per 1. above, in which the still picture is scanned horizontally or vertically or both for displaying on a video screen. Such scanning need not be uniform but may be with varying scanning direction, speed and focal length, for example. Scanning parameters may be chosen interactively, e.g involving a user manipulating a joy stick; 
   3. Dynamic stroboscoping, used to generate a video sequence re-framed according to the synthesis strategy of module  120 , in which the foreground objects are permanently inserted in the background when the triggering instants are reached and in which, in between triggering instants, the foreground motion proceeds normally; 
   4. De-multiplication, used to generate a video sequence re-framed according to the synthesis strategy of module  120 , in which copies of the foreground object are permanently inserted in the background when the triggering instants are reached and in which the foreground object leaves a semitransparent “trace” of its movement in between triggering instants. 
   5. Motion unrolling, used to generate a video sequence re-framed according to the synthesis strategy of module  120 , in which copies of the foreground object are inserted in a possibly synthetic background with an arbitrary spatial displacement. This is useful to apply stroboscoping to fast rotation movements which unfold “in place”, e.g. the fast spin of an ice skater around her axis. 
   Rendering a stroboscope further can include controlling foreground object persistency, e.g. so that earlier representations of the object are made to appear to fade and become transparent progressively as compared with later representations. Similarly, foreground objects can be suitably colored as a function of a time index. Thus, in a still picture of a football game, for example, it will be apparent at what time a player is where he is shown. Coloring can also be used for purposes other than time indexing, e.g. in a football game for player identification, with different players shown in different colors. 
   When sufficient information is available, e.g. as obtained from multiple representations of an action from different points of view, stroboscopic rendering can include spatially 3-dimensional reconstruction to enable viewing from points selected other than a camera location, e.g. in a virtual tour or fly-around fashion. Traces of features can be left over time, e.g to show position, trajectory and stance of an ice skater. In a soccer event, the ball can be made to appear in a stroboscopic fashion in three dimensions. 
   E. EXAMPLES 
   A stroboscoping video sequence was generated of an ice skating toe-loop triple jump, using wide-angle synthesis and dynamic stroboscoping rendering. Selected frames, shown as  FIGS. 2   a – 2   c  pertain to the beginning, the air time, and the landing of the athlete. As the athlete is seen moving in the sequence, a trail of copies is left behind in her path. 
   A stroboscoping image was generated from original video footage of an ice skating throw jump, using global synthesis and image rendering. The result, shown as  FIG. 3  is a single still image of the athletes&#39; movement, encompassing the entire duration and spatial extent of the jump. 
   From an original video sequence of a soccer event, a stroboscoping sequence was generated using narrow-angle synthesis and dynamic stroboscoping image rendering. The specific frames shown as  FIGS. 4   a – 4   c  show phases of a successful scoring event, with the ball being represented repeatedly, at positions it has traversed. 
   F. APPLICATIONS AND EXTENSIONS 
   A first application of the technique is the detailed analysis of sports in which a single athlete performs a fast gesture with a significant extension in space. Sports such as jumps (long jump, triple jump, high jump) or diving or ice skating can benefit from this type of analysis. 
   Stroboscoping is also of interest for tracing trajectories of objects like soccer balls, tennis balls and so on. In this case, as exemplified by  FIGS. 4   a – 4   c  described above, the sequences are obtained by inserting in the current video frame several copies of the video image of the ball at the location the ball occupied at previous instants in time Such copies are obtained from previous video fields which are warped onto the visual referential of the current video field. The advantage over known trajectory tracing methods is that the speed of the ball is implicitly shown in the stroboscoped trajectory, as the spacing between the images of the ball shows the speed of the ball. 
   The system can be extended to on-demand video delivery services. Thus, stroboscoping can be used to perform an exact comparison of two athletic performances by combining it with overlay capabilities as described in PCT International Applications PCT/IB99/00173 of 15 Jan. 1999 and PCT/US/0032117 of 24 Nov. 2000. 
   Stroboscope sequences can be used also to visually index sports events. For Internet-based content delivery, for instance, they can provide a quick and intuitive interface to select and recall a specific portion of an athletic gesture, as a starting point for more detailed analysis and graphical enhancements.