In a collaborative meeting or teaching situation, it is sometimes useful to image the audience using a camera located at the position of the projection screen at which the audience is looking. For example, during a teleconference, where an audience sees an image of a person addressing the audience from a remote location, with a return video image of the audience provided to the speaker, it is desirable that the cameras that view the speaker and the audience be located as near to the respective screens as possible, to provide a realistic appearance. Otherwise, the image provided to the audience is of a speaker not looking directly at the audience, and the image provided to the speaker is of a group of people all looking away.
Placing a video camera at the location of a projection screen presents certain challenges, however. If the screen is illuminated by a front-projector, then light from the projector can interfere with the camera. That is, the field of view of the camera can encompass the light from the projector, allowing light from the projector to interfere with the image taken by the camera. At best this can produce a distracting light spot in the image taken by the camera, and at worst the light spot can substantially wash out the camera image. Although repositioning the projector or re-aiming the camera can in some cases allow one to remove the projector from the camera's field of view while still keeping the camera at the projection position, in many cases this is not possible. Additionally, a camera physically positioned in front of a front projection screen and within the projection region of the projector will cast a shadow on the screen, thus interfering with the projected image.
Some prior approaches to this situation have attempted to physically block or mask light from the projector onto the camera. However, there may be some situations where this cannot be done effectively, due to the geometry of the projector/camera setup and the room or other environment. Additionally, this approach still casts a shadow on the screen, thereby eliminating part of the image, and still requires careful alignment to place the camera in the blanked out region. In cases where the camera is placed behind a transparent or semi-transparent front projection screen, scatter from the screen can still cause image artifacts even with shadowing or masking of the camera position.
Various features and advantages of the invention will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate, by way of example, features of the invention, and wherein:
Reference will now be made to exemplary embodiments illustrated in the drawings, and specific language will be used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended. Alterations and further modifications of the inventive features illustrated herein, and additional applications of the principles of the invention as illustrated herein, which would occur to one skilled in the relevant art and having possession of this disclosure, are to be considered within the scope of the invention.
A collaborative meeting or teaching situation is shown in
At the same time, to allow remote involvement of one or more persons that are the subject of the projected image, it is useful to image the audience 18 using a camera 20 located at or near the position of the projection screen or other surface 14 at which the audience is looking. The signal from the camera, represented by arrow 22, is directed to the remote location (e.g. via telephone lines, the Internet, etc.) allowing the person(s) at the remote location to see the audience as if in the room 16, and to interact (e.g. discuss and respond to questions) with the audience.
Unfortunately, in the situation shown in
Another collaborative meeting situation is illustrated in
It is to be appreciated that the collaborative meeting situations shown in
Unfortunately, while the camera 42 is behind the projection screen 36, light still passes through the screen. Consequently, there can still be substantial light interference from the projector. A number of approaches to resolving the problem of light interference in a projector/camera system have been attempted. One approach involves repositioning the projector or re-aiming the camera. For example, shown in
Another approach is to try to move the projector location, though in some cases this also is not possible or practical. In
Other prior approaches to this type of situation have tried to physically block light from the projector onto the camera, such as by configuring the projector to provide a mask or shadow which blocks light from the location of the camera. Unfortunately, this approach can eliminate part of the projected image (placing a black spot where the camera is located), and still requires careful alignment to place the camera in the blanked out region. Additionally, in cases like
Advantageously, the inventors have developed a projector/camera system in which the camera and projector are synchronized, but are out of phase, to help eliminate light interference from a projector that is aimed at a camera. The projector/camera system is compatible with a classroom setting like that shown in
A schematic diagram of a chromatically out-of-phase projector/camera system 50 is shown in
The camera 52 includes a light sensor 68 and a color wheel 70, and takes images sequentially. The color wheel includes multiple color filter segments, and causes the camera to take a sequence of individual component color images that are blended to produce a full color image. The projector 56 is a sequential color projector, and also includes a color wheel 72 having a series of color filter segments. The color wheel rotates rapidly to cause the projector to project a sequence of component color images, which are perceived by viewers as a single full color image.
Sequential color projectors and cameras using rotating color wheels are well known and commercially available. Examples of color wheels that can be used for sequential color projection are shown in
The light filter segments of the color wheel sequentially pass in front of the projection light path as the color wheel rotates very rapidly, so as to produce sequential red, blue, and green sub-portions of a single image frame. For example, during each image frame of a video image (each image frame lasting, e.g. 1/30 second), a white light source in the projector will sequentially project three different sub-images (each lasting e.g. 1/90 second) through the color wheel filters in sync with the rotation of the color wheel. For example, the sub-image that is projected while the red filter segment of the color wheel is in the projection path will correspond to the red portions of the final image, the sub-image portion that passes through the green segment of the color wheel corresponds to green portions of the final image, and the sub-image portion that is projected while the blue segment of the color wheel is in the projection path corresponds to blue portions of the final image. Given the speed of projection of the three color images, the viewer does not perceive three different colors at different times, but instead sees a single image including the entire range of visible colors.
Another example of a color wheel is provided in
Referring back to
The color wheel 70 of the camera is operationally linked with the color wheel 72 of the projector via a synchronization device 74, which simultaneously controls the speed of rotation and the relative positions of the color filters of the two color wheels. It is common for display systems (cameras and displays) to have a “genlock” capability, wherein one device generates a timing signal which is accepted by other devices in order for their video processing (frame rates) to be synchronized. The synchronization device 74 represents the components required to provide this capability, and though shown in
The color wheels in the projector and camera can be of identical design (i.e. having the same number and sequence of color filters), and rotate at the same frequency, but are caused to rotate out of phase. That is, when the projector is projecting a given color in its sequence, the camera is filtering out that color and imaging a different color. This is done for each color in sequence. As noted above, the color filters on the color wheel 70 of the camera 52 are designed to accept only the equivalent colors from the projector. Thus, the red filter on the camera accepts only the red light from the projector, and rejects blue and green. It is not necessary for the band passes to be identical, so long as rejection of the alternate colors is adequate. It is also not necessary for the color wheel segments of the camera to be as large as the projector's. They can be somewhat smaller in order to simplify timing.
An example of two simultaneous but out of phase color sequences for a projector/camera system wherein the camera and projector each have a three-segment color wheel having red (R), green (G) and blue (B) segments, is provided in
The camera, on the other hand, takes the red, green and blue images in the same order, but shifted by one step in the sequence. That is, while the projector is projecting a red image, the camera is imaging a blue (“B”) image, followed by red (“R”) and green (“G”), while the projector projects green and blue, respectively. The same color projection and imaging procedure follows for Frame 2. Because the camera 56 and projector 54 are out of phase, the camera will not capture any light coming from the projector.
Another example of a projection sequence for a chromatically out-of-phase projector/camera system is shown in the table of
A white portion of a projection sequence in a sequential color projector is often provided to increase the overall brightness of the projected image. During the white sub-frame, image data that is roughly equivalent to a “black and white” version of the background image is provided for parts of the scene that are fairly bright. This white image enhances the brightness of the image overall. A white color sub-frame can be desirable in a camera/projector system of this type in order to compensate for ambient lighting. The increased brightness makes the projected image more easily visible in a room in which the lights are not dimmed.
Since white light projected during the white sub-frame cannot be eliminated by a color filter segment, the color wheel in the camera includes a black (K) segment which is timed to block all light to the camera during the white phase. The black segment of the color wheel in the camera is part of the image-forming process during a frame, and is not really perceivable by a user. No specific compensation is needed in the camera or processor to account for the black segment. Due to the color wheel (including the color portions), the image captured by the camera will tend to be a little darker, but this is a common situation. Compensation for this condition can be easily provided by “faster” camera optics.
As noted above, in addition to varying the color sequence, the temporal sequence of projection and camera imaging can be shifted out of phase to eliminate light interference between a camera and projector. Specifically, the projection of the projector and imaging of the camera can be temporally out of phase (without respect to color), so that the projector only projects an image part of the time, and the camera only captures an image part of the time, the two time intervals being opposite each other.
An example of a temporally out-of-phase projector camera system 100 is depicted in
At the time instant shown in
The projection interval, illustrated in
As yet another alternative, the camera and projector can be spatially out of phase. One embodiment of a spatially out-of-phase camera/projector system 150 is shown in
Unlike the other embodiments described above, however, the camera 158 and projector 152 are configured to scan their images in a spatial sequence. For example, the projector can be a scanning laser projector, which produces a moving image by repeatedly scanning horizontal lines of pixels from the top of the screen to the bottom. Likewise, the camera can be configured to take an image in a corresponding way, scanning horizontal lines of pixels repeatedly from top to bottom. The successive scanning lines of the projector are indicated generally by lines 162, and the successive scanning positions of the camera are indicated generally by lines 164.
Where both the camera 158 and projector 152 deal with images by spatially scanning in this way, the two devices can be coordinated to scan at a common frequency, but out of phase. That is, as shown in
The spatial scanning of the camera 158 and projector 152 is controlled by a synchronization device 166, which ensures that the two devices operate at the same frequency, but out of phase. Thus the camera will not detect the image that is projected to the screen because its projection at any given time will be toward a different location of the screen than where the camera is taking an image. It is to be noted that the system is not limited to a top-to-bottom scanning configuration. A variety of spatially out-of-phase scanning configurations can be used. For example, the camera and projector can scan from side to side, rather than from top to bottom, or in any one of many other scanning modes.
Yet another embodiment of an out-of-phase camera/projector system is illustrated in
The relative positions of the camera 208 and projector 206 behind the screen 204 can be manipulated to avoid the camera casting a shadow upon the screen. That is, the camera can be placed outside of the light cone 210 of the projector. There are many ways this can be done. One example is shown in
Transparent or semi-transparent rear projection screens are well known and commercially available from a variety of sources. While rear projection screens are configured to produce an image on their front side, when a standard diffusive rear-projection screen is used, an image is also visible from the rear. Attempting to capture an image with a camera looking through a rear projection screen would thus ordinarily present the same problem as with a transparent front-projection screen: the projected image would tend to interfere with the camera capture. With the camera/projector system disclosed herein, however, the camera 208 is a sequential camera, and the projector 206 is a sequential projector, and these are out of phase (either chromatically, temporally, or spatially) in the manner described above. That is, images taken by the camera are out of phase with images projected to the screen by the projector so that the camera does not “see” the image projected to the screen. The projected image is always out of phase (either chromatically, temporally, or spatially) with the image capture of the camera, allowing the camera to operate without light interference from diffuse images visible on the rear of the screen.
With the system disclosed herein, in its various embodiments, light interference from the projector can be reduced or eliminated without significantly affecting the quality of the scene to be imaged. Advantageously, the projector can operate at full brightness, without being modified.
The out-of-phase projector/camera system thus provides a system where the camera can be located within the projection area of a projector without experiencing light interference. The camera takes images in a specific color, temporal or spatial sequence that is out of phase with a sequence of light projected by the projector, so that light interference from the projector is reduced or eliminated without affecting the quality of the scene to be imaged by the camera.
It is to be understood that the above-referenced arrangements are illustrative of the application of the principles of the present invention. It will be apparent to those of ordinary skill in the art that numerous modifications can be made without departing from the principles and concepts of the invention as set forth in the claims.
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Number | Date | Country | |
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20080094588 A1 | Apr 2008 | US |