FLARE REDUCTION IN VIDEO CONFERENCING
This invention relates to a method and apparatus for reducing camera flare caused by strong illumination. In particular, it relates to a method and apparatus for reducing camera flare in front projection video conference facilities.
BACKGROUND TO THE INVENTION
Video conference systems are known for providing two-way communication between remote parties. The early systems required a high bandwidth link for exchange of video and audio signals between the remote sites. Typically, an ISDN or fiber-optic connection was a minimum requirement. Improvements in compression algorithms have reduced the bandwidth requirements and made video conferencing more widely available at more reasonable cost.
A typical video conference facility consists of a fixed video camera having a field of view that takes in the conference participants at one site. There are usually multiple microphones to capture separate voice input from each participant. There may be additional cameras for transmitting supplementary images such as documents or drawings. There may be additional graphic devices such as electronic white boards.
There is also a projector that projects images from the remote site onto a screen and speakers for playing the audio signals. Conventional video conference facilities use a rear projection video system in which the video projector is behind the screen relative to the viewing position of the participants. In order to provide reasonable eye contact between participants at the remote sites, the camera is positioned at approximately chest height of a seated user of
the facility. In order to achieve this arrangement it is necessary to position the camera behind the screen looking towards the participant. This arrangement causes a problem because the camera casts a shadow in the projected image from the remote site. This problem will be particularly significant for small screens.
An alternate arrangement is to use a front projection arrangement. This overcomes the shadow problem and has the added advantage of requiring less space than the rear projection arrangement. This latter advantage provides a significant impetus in favour of the front projection arrangement. In the front projection arrangement the camera is still positioned behind the screen in order to achieve good eye contact. Unfortunately, this leads to a problem with flare in the camera caused by projection into the camera from the video projector.
Attempts have been made to address the flare problem by using a lens hood on the camera to shade the camera lens from direct projection but this has proven ineffective since it is not possible to effectively shade the camera without obscuring the field of view.
Another method of eliminating the flare problem is to hang a disc in mid-air in the video conference room to block the direct line between the projector and the camera. Although the concept works, it is an aesthetically unsatisfactory solution. The disc is also subject to damage and misalignment.
Front projection video conference facilities are preferred but the flare problem requires solution.
DISCLOSURE OF THE INVENTION
In one form, although it need not be the only or indeed the broadest form, the invention resides in a flare-reduced front projection video conference facility comprising: a screen;
a camera viewing a scene from the vicinity of said screen; a projector projecting a remote scene onto said screen; and means for blanking pixels in said camera or said projector to electronically prevent flare in said camera from said projector. In one form the means for blanking pixels is a modification to the camera to avoid viewing the projector.
In another form the means for blanking pixels is a modification to the projector to avoid projecting into the field of view of the camera.
Preferably the system further comprises a video production unit in signal connection with the projector and the means for electronically preventing flare is a modification to the video production unit.
In a further form, the invention resides in a method of reducing flare in a front projection video conference facility including the steps of: recording a video signal of a scene with a video camera; transmitting the video signal to a remote location having a video projector and a screen; modifying the video signal to eliminate signals corresponding to a location of the video camera in a field of projection of the video projector; and projecting the modified video signal onto the screen.
BRIEF DESCRIPTION OF THE DRAWINGS
To assist in understanding the invention, preferred embodiments will be described with reference to the following figures in which: FIG 1 shows a schematic of a first embodiment of a front projection video conference system;
FIG 2 shows a schematic of a second embodiment of a front projection video conference facility;
FIG 3 shows one means of eliminating flare;
FIG 4 shows a further means of eliminating flare;
FIG 5 shows scenes with flare; and
FIG 6 shows the same scene without flare.
DETAILED DESCRIPTION OF THE DRAWINGS
Referring to FIG 1, there is shown a schematic of a typical video conference facility employing a front projection arrangement. The facility consists of a room 1 in which a user 2 sits on a chair 3 at a desk 4. In front of the user 2 is a screen 5 upon which is projected an image of a similar video conference room at a remote location.
The image is projected onto the screen 5 from a video projector 6. Video production unit 7 generates signals to the video projector 6 from signals received on lines 8 from a remote similar facility. A camera 9 is positioned in the screen 5 at approximately eye level with respect to the user 2. As can be seen in FIG 1, the video projector 6 projects into the field of view of the camera 9. This is virtually unavoidable if the camera 9 is to have a sufficiently wide angle lens to provide a full field of view at the remote facility. The inventor has found that the problem can be eliminated, or at least considerably reduced, by modifying the system to avoid projection into the camera. This may be achieved by modifying the video projector 6 so that it does not project into the area of the screen that is filled by the camera 9. This requires a modification of the projector 6. Alternatively, the camera 9 can be modified so that it does not view the area of the scene that contains the projector 6. This requires a modification of the camera 9.
In both of the examples, the modification may be physical or electronic. For example, a black spot may be located in the optical train
of either the camera or projector to eliminate the offending region. This physical approach is essentially identical to the approach described in the background. Alternatively, certain pixels in the camera or projector may be disabled. This electronic approach requires specific modification of the camera or projector for the specific video conference facility.
The principle of operation is exemplified in the schematic of FIG 2. A mixer 10 is included between the video production unit 7 and the video projector 6. The mixer alters the video signal on the fly and places a blank region over the camera. The inclusion of a mixer requires no modification of the usual hardware of a video conference facility and may therefore be implemented in new or existing facilities.
The operation of the mixer 10 can best be explained by reference to FIG 3. The video input signal 11 is mixed with a wipe pattern 12 in the mixer 10. A suitable mixer is a Panasonic WJ-AVE555 digital AV mixer. A joystick controller 13 adjusts the position of the wipe pattern 12 until the wipe pattern overlaps the camera lens position. The combined signal 14 is the video output that is directed to the projector 6. Similarly, the mixer could be placed between the camera 9 and the video production unit 7. An alternate approach using a video frame grabber is shown in
FIG 4. A frame grabber 15 digitizes the original analogue video signal 11. The frame grabber 15 consists of an analogue to digital converter 15a, a frame buffer 15b, and a digital to analogue converter 15c. For each video frame, special purpose logic 16 sets the luminance level to zero for each pixel corresponding to a circular mask overlapping the cameral lens position in the projected image. The modified frame buffer is converted back to an analogue signal that is sent to the projector 6. The frame grabber 15 could be incorporated in the video production unit 7 or included in the signal path before or after the VPU. The following pseudocode explains the algorithm required to blank the relevant pixels.
For row=0 to maxrows
For col=0 to maxcols
If (overcamera(row,col)) then
Outputpixel(row,col)=black
Else
Outputpixel(row,col)=inputpixel(row,col) Where overcamera is a Boolean function that returns true if the arguments row.col are in the area of the camera lens. A preferred approach is to modify the CODEC in the video production unit so that it does not fill the pixels that project onto the camera. This approach is completely flexible and can be used with any projector/camera combination. The inventor considers that a small modification to existing video production units would allow on-the-fly modification of the CODEC to eliminate the flare problem. As with the previous examples, a joystick could be used to position the overcamera pixel blanking mask. Of course, the positioning device need not be a joystick but could simply be an X and Y coordinate input for the center position of the mask. The effectiveness of the invention is evident in the images of FIG
5 and FIG 6. FIG 5 is a photograph of a screen of a video conference facility of the type depicted schematically in FIG 1 and FIG 2. The screen 17 is displaying a scene of a remote video conference facility. The projector 6 at the remote facility is not visible due to flare 18. The flare 18 also masks other aspects of the scene to some degree. It will be appreciated that in a small facility the problem will be magnified.
Fig 6 is a photograph of the same screen 17 shown in FIG 5 but the flare has been removed by applying the invention. The camera 6 is clearly visible in FIG 6. The invention has been applied to modify the video signal to eliminate the flare visible in FIG 5. The same result is
obtained with all embodiments of the invention described herein.