FIELD OF INVENTION This invention relates to projection displays, and specifically to a projection display that is visible from one side of the screen but not the other.
DESCRIPTION OF RELATED ART Generally speaking, advertising is the paid promotion of goods, services, companies and ideas by an identified sponsor. Advertisements on the side of buildings were common in the early-20th century U.S. One modern example is the NASDAQ sign at the NASDAQ Market Site at 4 Times Square on 43rd Street. Unveiled in January 2000, it cost $37 million to build. The sign is 120 feet high and is the largest LED display in the world. NASDAQ pays over $2 million a year to lease the space for this sign. This is actually considered a good deal in advertising as the number of “impressions” the sign makes far exceeds those generated by other ad forms. However, advertisements on the side of a building cover up what otherwise would be space for windows in the building.
Thus, what is needed is an apparatus that would provide advertisements on the side of buildings while still allowing for windows in the advertisement space.
SUMMARY In one embodiment of the invention, a projection display system includes (1) a first polarizer, (2) a transparent screen, (3) a second polarizer on the transparent screen, and (4) a projector for projecting an image through the first polarizer and onto the transparent screen. The first and the second polarizers have different polarization directions so that the image is visible from a first side of the transparent screen and invisible from a second side of the transparent screen.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 illustrates a polarized front-projection system in one embodiment of the invention.
FIG. 2 illustrates a polarized rear-projection system in one embodiment of the invention.
FIGS. 3 and 4 illustrate views through a transparent screen of the systems inFIGS. 1 and 2 in embodiments of the invention.
FIGS. 5, 6,7,8,9,10, and11 illustrate various applications of the systems inFIGS. 1 and 2 in embodiments of the invention.
FIG. 12 illustrates a projection system in one embodiment of the invention.
FIG. 13 illustrates a polarized rear-projection system in one embodiment of the invention.
Use of the same reference numbers in different figures indicates similar or identical elements.
DETAILED DESCRIPTIONFIG. 1 illustrates a polarized front-projection system100 in one embodiment of the invention.System100 includes aprojector102 that generates an image “Q.”Projector102 can be a liquid crystal display (LCD) projector, a digital light processing (DLP) projector, or a laser projector. Depending on the application, image Q can be a still advertisement, a slideshow of still advertisements, or a video advertisement.
Image Q propagates through apolarizer104 having apolarization direction105. In one embodiment,polarizer104 is a polarizing film on the lens ofprojector102. After passing throughpolarizer104, image Q only has light aligned alongpolarization direction105.
Image Q then propagates onto apolarizer106 on atransparent screen108. Polarizer106 has apolarization direction107 different frompolarization direction105 so that image Q cannot propagate throughpolarizer106. Thus, image Q is visible on a first side oftransparent screen108 and invisible on a second side oftransparent screen108.
In one embodiment,transparent screen108 is a window or a glass door on the side of anoffice building110. Thus, apedestrian112 sees image Q projected ontowindow108 while anoffice worker114 does not see image Q from within the office.Office worker114 does see other objects that are illuminated by non-polarized light, such as object “A+.” Overall, a large image Q can be projected onto the side ofoffice building110 without disturbing the office workers within while still providing a view to the office workers. Polarizer106 can be a film mounted on either side ofwindow108, it may be easier for installation and maintenance ifpolarizer106 is mounted on the inside ofwindow108. In one embodiment,polarizer106 has a white side facing the outside that improves the visibility of image Q topedestrian112 and a dark side facing the inside that increases the transparency tooffice worker114.
FIG. 2 illustrates a polarized rear-projection system200 in one embodiment of the invention.System200 is similar tosystem100 except thatprojector102 is now placed behindtransparent screen108. In one embodiment,projector102 is now placed withinoffice building110 to prevent theft and damage. Aprojection mirror202 is provided to bend image Q and project it ontotransparent screen108.
FIG. 3 illustrates the view provided tooffice worker114 in one embodiment. As can be seen,office worker114 seespedestrian112 and object A+ throughwindow108 but not image Q onwindow108.FIG. 4 illustrates the view provided topedestrian112 in one embodiment. As can be seen,pedestrian112 sees object A+ beforewindow108,office worker114 throughwindow108, and image Q onwindow108.
Usingsystems100 and200, every transparent screen becomes a window and every window becomes a screen. There are many applications forprojection systems100 and200.FIG. 5 shows thatsystems100 and200 used to project image Q onto windows502 of abuilding504 in one embodiment. In this application, passersby see image Q (e.g., a large advertisement) but the workers insidebuilding504 are not disturbed by image Q and continue to enjoy their view to the outside.
FIG. 6 shows thatsystems100 and200 can be used to project multiple images Q (e.g., multiple advertisements) ontoprotective glass602 of astadium604 in one embodiment. In this application, the audience sees throughprotective glass602 directly before them to view the game but also sees images Q on protective glass across and besides them. Furthermore, television cameras capture images Q for advertisement purposes.
FIGS. 7 and 8 show thatsystems100 and200 can be used to project image Q on amonitor702 for amotor vehicle704 in one embodiment. In this application, the rear passengers see image Q onmonitor702 while the driver sees throughmonitor702 and out of arear windshield706. Thus,monitor702 can be made larger than conventional monitors because it does not obstruct the view of the driver. In one embodiment, the front windshield ofmotor vehicle704 is polarized differently from the polarization ofmonitor702 so that external light sources, such as the sun during sunrise or sunset, do not propagate pass the front windshield and throughmonitor702. This embodiment prevents external light sources from interfering with image Q onmonitor702.
FIGS. 9 and 10 show thatsystems100 and200 can be used to project acamouflage902 on acockpit canopy904 of anairplane906 in one embodiment. In this application,canopy904 is camouflaged along with the rest ofairplane906 without obstructing the view of the pilot throughcanopy904.
FIG. 11 shows thatsystems100 and200 can be used to project an image R (e.g., a toll amount) on awindow1102 of atoll booth1104 in one embodiment. In this application, image R onwindow1102 is visible to the drivers without obstructing the toll taker's view throughwindow1102.
FIG. 12 illustrates aprojection system1200 in one embodiment of the invention. AnLCD1202 projects an image “S” having apolarization direction1203. A matrix of fiber-optic cables1204 (only a few are illustrated for clarity) are mounted toLCD1202 to correspond with the pixels ofLCD1202. The matrix of fiber-optic cables1204 are then mounted to atransparent screen1206. The matrix of fiber-optic cables1204 project image S onto apolarizer1208 having apolarization direction1209 different thanpolarization direction1203. Polarizer1208 may be a film mounted ontransparent screen1206. In one embodiment,polarizer1208 has a white surface that improves the visibility of image S. Thus, image S is visible on a first side oftransparent screen1206 and invisible on a second side oftransparent screen1206.System1200 can be used in various application described above.
FIG. 13 illustrates a polarized rear-projection system1300 in one embodiment of the invention.Projector102 projects image Q throughpolarizer106 ontransparent screen108. After propagating throughpolarizer106, image Q only has light aligned alongpolarization direction107.
Image Q then propagates through aretarder plate1302 that changes the light polarization fromdirection107 todirection105. In one embodiment,retarder plate1302 orthogonally rotates the polarization direction of image Q.
Image Q then reflects fromprojection mirror202 back ontopolarizer106 ontransparent screen108.Polarizer106 haspolarization direction107 different frompolarization direction105 so that image Q cannot propagate throughpolarizer106. Thus, image Q is visible on a first side oftransparent screen108 and invisible on a second side oftransparent screen108.System1300 can be used in various application described above.
Insystem1300, a small image Q may be visible ontransparent screen108 tooffice worker114. This occurs whenprojector102 projects images with randomly polarized light that is partly transmitted throughpolarizer106 and partly reflected bypolarizer106. The small reflected image Q can be avoided by using anLCD projector102 that produces images with light aligned alongpolarization direction107. Alternatively, an additional polarizer havingpolarization direction107 can be placed before or on the lens ofprojector102.
Various other adaptations and combinations of features of the embodiments disclosed are within the scope of the invention. Numerous embodiments are encompassed by the following claims.