Abstract:
A method for a film recorder includes displaying a plurality of images on a modified liquid crystal display movably coupled to the film recorder, wherein the modified liquid crystal display panel comprises a liquid crystal display panel with only a single polarizing media layer, disposing a linearly polarizing filter in an optical path of the film recorder, orienting the linearly polarizing filter in a first orientation relative to the modified liquid crystal display panel to thereby configure the film recorder to receive the plurality of images as positive images, and orienting the linearly polarizing filter in a second orientation relative to the modified liquid crystal display panel to thereby configure the film recorder to receive the plurality of images as negative images.

Description:
CROSS-REFERENCES TO RELATED APPLICATIONS 
   The present invention claims priority and incorporates by reference for all purposes application Ser. No. 10/392,399 filed Mar. 20, 2003 titled Flat Panel LCD and to PCT application No. PCT/US03/11492 filed Apr. 25, 2003 titled Flat Panel Digital Film Recorder. The present invention is also related to and incorporates by reference for all purposes, application Ser. No. 10/637,744 filed Aug. 8, 2003 titled Improved Flat Panel Image to Film Transfer Method and Apparatus and Provisional Application No. 60/493,539 filed Aug. 8, 2003 titled Flat Panel Digital Film Recorder and Method. 

   BACKGROUND OF THE INVENTION 
   The present invention relates to image to film transfer. More particularly, the present invention relates to techniques and apparatus for efficient recording of images to film media. 
   Throughout the years, movie makers have often tried to tell stories involving make-believe creatures, far away places, and fantastic things. To do so, they have often relied on animation techniques to bring the make-believe to “life.” Two of the major paths in animation have traditionally included, drawing-based animation techniques and physical animation techniques. 
   Drawing-based animation techniques were refined in the twentieth century, by movie makers such as Walt Disney and used in movies such as “Snow White and the Seven Dwarves” and “Fantasia” (1940). This animation technique typically required artists to hand-draw (or paint) animated images onto a transparent media or cels. After painting, each cel would then be captured or recorded onto film as one or more frames in a movie. 
   Physical-based animation techniques typically required the construction of miniature sets, props, and characters. The filmmakers would construct the sets, add props, and position the miniature characters in a pose. After the animator was happy with how everything was arraigned, one or more frames of film would be taken of that specific arrangement. Physical animation techniques were developed by movie makers such as Willis O&#39;Brien for movies such as “King Kong” (1932). Subsequently, these techniques were refined by animators such as Ray Harryhausen for movies including “The Mighty Joe Young” (1948) and Clash Of The Titans (1981). 
   With the wide-spread availability of computers in the later part of the twentieth century, animators began to rely upon computers to assist in the animation process. This included using computers to facilitate drawing-based animation, for example, by painting images, by generating in-between images (“tweening”), and the like. This also included using computers to augment physical animation techniques. For example, physical models could be represented by virtual models in computer memory, and manipulated. 
   One of the pioneering companies in the computer aided animation (CAA) industry was Pixar Incorporated. Pixar developed both computing platforms specially designed for CAA, and animation software now known as RenderMan®. By moving to CAA, Pixar was faced with additional challenges. One such challenge was how to accurately and effectively transfer CAA images onto film. In response to this problem, Pixar invented a proprietary laser film recording system named Pixarvision™. 
   Despite these advances, the inventors of the present invention believed that further advances could be achieved in image to film transfer. One such advance was to reduce the amount of time needed to record an image onto frame. Previously, laser film recording could take up to 50 seconds per frame, however with advances in technology, such as Pixarvision™, this time was reduced to about 5 seconds per frame. Because a typical feature-length movie may have approximately 160,000 frames, even at 5 seconds per frame, it would take over nine days straight to transfer the movie to film. 
   Another such advance was to increase the quality of release prints. As is known in the industry, an original camera print is typically printed to form one or more prints termed “interpositives” from which one or more prints termed “internegatives” from which release prints are made. In the present case, the inventors recognized that if they could reduce the cost of creating an original camera print sufficiently, one or more generation of intermediate could be eliminated. In such a case, the release print would be closer to the original camera print in quality. Currently, as merely an example, a typical film transfer service bureau may charge from $2 to $3 per frame, thus a feature-length movie may cost up to $500,000 per master negative. Further, typical films require a minimum of three master negatives. Because of this high cost, typically three or fewer master negatives are printed. 
   In light of the above, the inventors of the present invention have realized that it is desirable to make further enhancements in the area of image to film transfer. 
   BRIEF SUMMARY OF THE INVENTION 
   The present invention relates to image to optical media transfer. More specifically, the present invention relates to digital image to film transfer. More particularly, the present method relates to new apparatus and techniques for increasing film transfer speed and film transfer quality. 
   According to one aspect of the invention, a method for a film recorder is disclosed. One technique includes displaying a plurality of images on a modified liquid crystal display movably coupled to the film recorder, wherein the modified liquid crystal display panel comprises a liquid crystal display panel with only a single polarizing media layer, and disposing a linearly polarizing filter in an optical path of the film recorder. The process may also include orienting the linearly polarizing filter in a first orientation relative to the modified liquid crystal display panel to thereby configure the film recorder to receive the plurality of images as positive images, and orienting the linearly polarizing filter in a second orientation relative to the modified liquid crystal display panel to thereby configure the film recorder to receive the plurality of images as negative images. 
   According to another aspect of the invention, an apparatus for recording images to film media is described. One apparatus includes a liquid crystal display substrate configured to display a plurality of images, wherein the liquid crystal display substrate includes only a single polarizing layer, and a film recorder movably coupled to the liquid crystal display substrate, wherein the film recorder includes a lens having a polarizer coupled thereto, wherein when the polarizer is oriented in a first orientation, the film recorder is configured to receive the plurality of images as positive images, and wherein when the polarizer is oriented in a second orientation, the film recorder is configured to receive the plurality of images as negative images. 
   According to still another aspect of the invention, a method for an optical media recorder to record a plurality of images displayed on a on a display substrate is described. One technique includes positioning a polarizing filter disposed on a lens of the optical media recorder in a first orientation with respect to an orientation of a polarizing layer on the display substrate, wherein when the polarizing filter is in the first orientation with respect to the orientation of the polarizing layer, the optical media recorder is configured to receive the plurality of images as images in a first polarity. Various techniques include displaying the plurality of images on the display substrate, and thereafter recording the plurality of images as images in the first polarity on an optical media. 
   According to yet another aspect of the invention, a method for forming a image transfer apparatus is disclosed. One method includes providing a liquid crystal display panel having a first linearly polarizing film disposed on a bottom surface of first transparent media, first transparent electrodes disposed upon a top surface of the first transparent media, a second linearly polarizing film disposed on a top surface of a second transparent media, second transparent electrodes disposed on a bottom surface of the second transparent media, and a liquid crystal media disposed between the first transparent electrodes and the second transparent electrodes. Additionally, techniques may include removing the second linearly polarizing film from the top surface of the second transparent media, and providing a optical media recorder movably coupled to the liquid crystal display panel. The process may also include positioning a linearly polarizing filter in the optical path of the optical media recorder, and orientating a polarizing direction of the linearly polarizing filter relative to the liquid crystal display. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     In order to more fully understand the present invention, reference is made to the accompanying drawings. Understanding that these drawings are not to be considered limitations in the scope of the invention, the presently described embodiments and the presently understood best mode of the invention are described with additional detail through use of the accompanying drawings in which: 
       FIGS. 1A-C  illustrate an embodiment of the present invention; 
       FIGS. 2A-B  illustrate additional embodiments of the present invention; 
       FIGS. 3A-B  illustrate a flow diagram according to an embodiment of the present invention; 
       FIGS. 4A-D  illustrate an example of an embodiment of the present invention; 
       FIGS. 5A-B  illustrates a flow diagram according to an embodiment of the present invention; and 
       FIG. 6  illustrates an embodiment of the present invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
     FIGS. 1A-C  illustrate embodiments of the present invention. More particularly,  FIGS. 1A-C  illustrate a digital film recorder system. In  FIG. 1A , a system  100  includes an optical recording device  102  (e.g. a film recorder), a display device  104  (e.g. a flat-panel display), a track  112 , and a central processing unit (CPU)  106 . The track  112  may run in a Z-direction and may include support members such as rails, rods, or the like for attaching film recording device  102  and display device  104  thereto. Devices  102  and  104  may be attached to the track and be moved towards and away from each other with the use of movable platforms, for example. In one embodiment, devices  102  and  104  may be semi-permanently secured to the track by any known device or method. In one embodiment, the positions of devices  102  and  104  are adjustable. 
   In the present embodiment, film recording device  102  may be any conventional optical recording device, such as a 16-millimeter, 35-millimeter, or 70-millimeter film movie cameras. Further, the optical recording media may be any conventional media, such as film media, or the like. In other embodiments, recording device  102  may be a video camera of any format, such as an HDTV camera, of any resolution, or the like. 
   In the present embodiment, film recording device  102  is mounted upon a movable platform  122  that is mounted to track  112 , with wheels  122   a . The movable platform may be motorized and controlled by a control unit or other device, such as CPU  106 . Accordingly, the distance “D,” a distance between the front of display device  104  and a lens of the film recording device  102  may be adjusted by sliding the movable platform  122  along the track in either direction. 
   In the present embodiment, cameras used as the film recording device  102  may be auto focus or manual focus cameras. Additionally, such cameras may include an adjustment unit (not individually shown) for adjusting the focal length and aperture size of a lens, media (e.g. film) exposure time, media advancement, and any other conventional adjustable parameters of film cameras. The adjustment unit of the film recording device  102  may also be coupled to CPU  106 . Accordingly, CPU  106  may adjust any of the characteristics of the camera remotely, may control the camera motor to advance film, may control the camera shutter, and the like. 
   Display device  104  may be a thin-film technology flat panel liquid crystal display (LCD) and may be coupled with CPU  106 . In one embodiment, CPU  106  is also configure to drive (provide) display device  104  with images. In another embodiment, a separate CPU may be used to drive display device  104 . These images are typically provided in digital format, however, the images may also be provided in analog format in other embodiments. In other embodiments, displays built on other display technology are also contemplated. 
   In one embodiment, display device  104  is based upon a 23-inch thin-film transistor (TFT) active matrix liquid crystal panel, having approximately 4000 by 2500-pixel resolution. In one non-limiting example, such a panel is manufactured by International Display Technology Co., Ltd., Japan, and available through IBM. In another embodiment, display device  104  is based upon a 23″ 1920×1200 pixel resolution LCD. In one non-limiting example, such a panel is manufactured by L. G. Philips, and available through Apple computer. In various embodiments, displays  104  are configured to be driven with 24-bit data (16.7 million colors), although in other embodiments, a greater bit-depth may become available. One of ordinary skill in the art will recognize that embodiments of the present invention may use high-resolution displays that currently exist or may use displays and display technologies that will be developed in the future. In contemplated embodiments, display device  104  may be based upon active-matrix (or passive) organic light emitting diode (OLED) technology, DLP digital light technology, LCOS technology, plasma technology, EL technology, or the like. Additional embodiments may include other novel features described in the above-referenced applications such as a display with additional stroboscopic illumination, a display with additional LED illumination, an LCD display pumped with DLP illumination, or the like. 
   It will be understood by one skilled in the art that many desired effects may be achieved by varying the size of the display, the resolution of the display, the brightness of the display, the distance between the display area of the display and the lens of the recording device, and the like. The camera characteristics of the recording device may be varied to achieve any effect desired. Further, many techniques may also be used to enhance the image displayed on display device  104 . 
   In one example, spatial dithering techniques can be used to effectively increase the number of apparent colors of display device  104 . As is known, display devices typically have a limited number of colors that may be reproduced, for example, a display device may support output 256 colors (8-bits) for each primary color component. In one example, spatial dithering techniques may be used to drive two adjacent pixels with a first and second color to give an effective appearance of a third color on the display. In one example, it has been determined that using spatial dithering techniques, the display device can appear to have an effective output of up to 1024 colors (10-bits) for each primary color component. 
   In operation, if an un-reproducible color for a pixel is desired that lies between two reproducible colors on the display device, pixels of the display device may are assigned the two reproducible colors. In one embodiment, determining which pixel is assigned which one of the two (or more) colors may be random and weighted with the color that is closest to the desired one. When exposed to these display pixels, the film media integrates the colors to form the desired color. 
   In one example, using a 3480×2400 pixel display and having every four pixels in a square represent a dithered color, the effective optical resolution of the display decreases by approximately half to 1740×1200. The effective resolution is smaller than typically desired for film transfer, accordingly other dithering methods to increase the number of colors recorded by the film may be used in addition to, or instead of spatial dithering. 
   In another example, temporal techniques can be used to effectively enhance the number of apparent colors of display device  104 . In this embodiment, a frame of film media is exposed to a series of images on display device  104 . For a particular pixel on display device  104 , in the series of images, that value may vary. The values for that pixel may both be greater or lesser in value than the target color. Since the film media integrates the colors, the color recorded at that pixel location may be one display device  104  is not normally able to produce. Accordingly, the apparent bit-depth for each primary color component is effectively increased. 
   In still other embodiments, combinations of spatial and temporal dithering techniques may be used to increase the number of colors that are recorded onto a film media. Dithering techniques thus effectively increase the number of effective bits per color recorded onto film media. In one embodiment, the increase is estimated to increase the effective bit-depth from 8 bits per color to 10 bits per color, or greater. 
   In the present embodiment, because even the highest quality display  104  are not completely perpendicular to surface  112 , a precision adjustment device  114  may be attached to the rear of display device  104  to adjust the orientation of the display. Adjustment device  114  may also be used as a movable mount for display device  104  to track  112  to allow display device  104  to be moved towards or away from recording device  102 . In one embodiment of the present invention, adjustment device  114  may be an XYZ gimbal attached to the rear of display device  104 . In this embodiment, the XYZ gimbal includes extremely fine adjustment capabilities should be used to more precisely orient the active display area of display device  104  with the lens of the recording device  102 . For example, the gimbal may allow display device  104  to be positioned relative to recording device  102 , facing to the right or left (pan), tilting up or down (tilt), rotated clockwise or counterclockwise (roll), and even moving up or down. One having ordinary skill in the art will readily understand that many instruments may be used to help ensure that display device  104  is “flat” relative to recording device  102 . Additionally, dithering may be used to achieve relatively flawless effects on large display panels. 
   In the present embodiment, recording device  102  is focused upon the display portion of display device  104 . More specifically, one or more lenses of recording device  102  are adjusted until an image of display device  104  is focused upon the image plane where the film media, or the like, is located. In one embodiment, this may be facilitated by projecting one or more test patterns on the display portion of display device  104 . The size and resolution of the image may be adjusted by moving the display device  104  closer or farther away from the film recording device  102  along the track  112 . The size of the display device  104  may be adjusted as well. The display portion of display device  104  is located at the focal plane of recording device  102 . 
   In the present embodiment, an integrated controller (e.g., CPU  106 ) may be used to monitor and/or drive the images being displayed on display device  104 . CPU  106  may also be used as well as used to physically adjust recording device  102  and display device  104 , as described above. For example, resolution of an image may be changed by changing the distance D between recording device  102  and display device  104 , and/or by changing the display area size (image resolution) of the image being displayed on display device  104 . In the present embodiment, the appropriate software may be executed or CPU  106  in order to accomplish the described features. In other embodiments, display device  104  may be driven separately from recording device  102 . However, in such embodiments, it is still desirable to coordinate the operation of these devices in some way. 
     FIG. 1B  is a block diagram of system  100  according to an embodiment of the present invention. System  100  may include a film recording device  102 , a display device  104 , a controller  106 , a film recorder device adjustment unit  108 , and a storage device  110  (e.g., data warehouse, disk farm, etc.). These devices may be configured as already described above with reference to  FIG. 1A . 
   In this embodiment, the display device  104  is coupled with the controller  106 . Controller  106  is coupled with the storage device  110  and film recorder adjustment unit  108 . The film recorder adjustment unit  108  is also coupled with the film recorder device  102  and is configured to adjust the distance D between the film recording device  102  and the display device  104  and to adjust the camera characteristics of the film recording device  102 , such as focal length, focus, etc. 
   In this embodiment, the controller  106  may include a CPU and is typically configured to control the display of images stored on storage device  110  onto display  104  as well as configured to coordinate and control the film recording device  102  via the film recorder adjustment unit  108 . Further, the film recorder adjustment unit  108  may include actuators and motors which may or may not be part of the film recording device  102 . Additionally, film recorder adjustment unit controls the advancement of the film, opening and closing of the shutter, etc. 
     FIG. 1C  illustrates an embodiment of the present invention, More specifically,  FIG. 1C  illustrates a three-dimensional view of one embodiment. Illustrated in  FIG. 1C  are a track  112 , movable platform  122 , a recording device  102  mounted thereon, and another movable platform  124  for mounting one or more display devices  104 . As shown, a shroud or a shutter mount  125  is provided which may be used in conjunction with the recording device  102  in order to better control exposure. 
   In the present embodiment, track  112  can include one or more cross member supports and feet. In one embodiment, platform  122  (and/or platform  124 ) includes one or more tie down hand bolts  126  for securing platform  122  relative to the track  112 . Further, one or more wheels  122   a  may be provided to facilitate movement of platform  122  on track  112 . In other embodiments platform  122  may also be laterally adjustable with respect to platform  124 . 
     FIGS. 2A-B  illustrate additional embodiment of the present invention. In particular,  FIGS. 2A-B  illustrate construction of a typical flat panel display  104 , as illustrated in  FIG. 1A . 
   In one example, flat panel display  104  includes a first substrate  1010  and a second substrate  1020 . In various embodiments, these substrates are typically transparent, and are typically made from glass. In other embodiments, other types of media may be used for one or both of the substrates. For example, first substrate  1010  may be fabricated as a layer of silicon, and second substrate  1010  may be fabricated from a doped silicon dioxide layer. 
   In the present embodiment, sandwiched between first substrate  1010  and second substrate  1020  are liquid crystal cells, or pixels,  1050 . As is known, such liquid crystal cells  1050  may include transparent bottom and top electrodes, liquid crystal media, spacers, colored filter material, and the like. 
   In one embodiment, first substrate  1010  is a glass layer. On the “back” or “bottom” side of first substrate  1010 , a first polarizing media  1030  is attached. Further, on the “front” or “top” side of the second substrate  1020 , a second polarizing media  1040  is attached. In the present embodiment, polarizing media  1030  and  1040  is typically a film of polarizing media that transmits radiation, such as visible light, in a linear polarization. 
   In the present embodiment, a linear polarization direction of polarizing media  1030  is oriented orthogonal or perpendicular to a linear polarization direction of polarizing media  1040 . For example, polarizing media  1030  may transmit light in a right-left polarization and polarizing media  1040  may transmit light in a up-down polarization, and the like. 
   In this example, polarizing media  1030  and  1040  may be attached to first substrate  1010  and second substrate  1020 , respectively with an adhesive. Typically, the adhesive is relatively transparent when dry. In one embodiment, polarizing media  1030  and  1040  may include self-adhesive surfaces, and in another embodiment, an external adhesive is used. 
   In this embodiment, polarizing media  1040  may also include anti-reflective and/or anti-glare properties. For example, a surface of the polarizing media  1040  away from the top side of the second substrate  1020  may include a finely roughened surface so as to reduce reflections and/or glare. In the present embodiment, the feature size of the roughened surface is typically much smaller than a pixel size. 
   In another example, an anti-reflective, anti-glare layer, a retardation layer, or the like may be disposed upon polarizing media  1040 . Such layers may also be self-adhesive, deposited directly upon the polarizing media  1040  (anti-reflective coating (ARC)), require an external adhesive, or the like. 
   In one embodiment, flat panel display  104  may be based upon a 23″ diagonal, cold cathode fluorescent light, panel having a resolution of 1920 horizontal by 1200 vertical pixels by 24-bits, manufactured by LG Philips. One such monitor based upon this panel is available from Apple Computer. In another embodiment, flat panel display  104  may be based upon a 23″ diagonal panel having a resolution of about 3480×2400 pixels manufactured by International Display Technology Co., Ltd., Japan. One such monitor based upon this panel is available from IBM. 
   In other embodiments of the present invention, monitors based upon panels with similar resolutions or higher resolutions can be used. It should be understood that later developed monitors having a greater resolution, based upon later developed display technologies, or the like are all considered within the scope of contemplated embodiments. Accordingly, the embodiments disclosed herein are merely illustrative, and should not be considered as limiting the scope of the claimed invention. 
     FIG. 2B  illustrates another embodiment of the present invention. 
   In another example, flat panel display  104  includes a first substrate  1060 . In various embodiments, first substrates  1060  is typically transparent, and may be made from glass, Mylar, poly hexylthyiophene, or the like. Typically a transparent electrode  1070 , such as ITO, is disposed on the “back” side of first substrate  1060 . Conventional OLED pixels  1080  including hole-injection material, electron-transport material, and organic emitters is then coupled to transparent electrode  1070 . 
   In some embodiments, OLED pixels  1080  are sandwiched between transparent electrode  1070  and a patterned electrode layer  1090 . In embodiments of the present invention, patterned electrode layer  1090  may or may not be fabricated upon a second substrate. In some embodiments the second substrate may be a silicon-based such as glass, amorphous silicon, or the like. 
   In  FIG. 2B , an anti-reflective, anti-glare layer (“frosted” layer), a retardation layer, or the like  1095  maybe disposed upon the “front” side of first substrate  1060 . Such layers may also be self-adhesive, deposited directly upon the first substrate  1060  (anti-reflective coating (ARC)), require an external adhesive, or the like. 
   High resolution embodiments of OLED displays are not yet commercially available. However, after studying engineering samples, the inventor believes that in light of the present disclosure, embodiments can easily be adapted to work with OLED displays. 
   The inventors have discovered that capturing images with film recording device  102 , an optical recorder, from flat panel display  104  has some additional limitations, over and above the problems and solutions detailed in the preceding figures and specification. One such limitation is that images received by optical recorder  102  may include undesired optical distortions. 
   In the image to film capture embodiments described above, the inventors have recognized that even small optical distortions have a significant impact in the quality of the film images. As an example, the LG Philips panel has a display size of approximately 19.5 inches by approximately 12 inches, and the images captured from the panel will be projected onto a theater screen. Current theater screens typically range from 30′ across and 20′ high up to 60′ across and 30′ high. Accordingly, the images captured from the panel may be magnified from 20 to 30 times, or greater. 
   Some optical imperfections or defects on a flat panel display are visible or noticeable to typical users of flat panel displays. However, it is believed that some optical imperfections or defects on a flat panel display may not be visible or noticeable to typical users of flat panel displays. Such defects are typically characterized as coherent (definite) patterns that are stationary and pronounced (apparent). When an image on a screen is panned up or down, such as is common with movies, such stationary defects are more perceptible to a trained eye. Because, the flat panel displays are being used herein specifically for displaying images and because defects will be greatly magnified, the inventors have determined that such apparent defects should be reduced. It is not believed that any prior art have considered the new and novel problems discovered herein, much less discovered the new and novel solutions herein. 
   After careful investigation, the inventor believes that one source of the undesired optical distortions is associated with the addition of layers on top of the top substrate. More specifically, the inventor believes that one or more of the following can introduce undesired optical distortions to the image produced by pixels  1050 : polarizing media  1040 , anti-glare properties, anti-reflective coatings, adhesive materials, and the like. For example, as disclosed above, polarizing media  1040  may have a front surface that is diffuse similar to frosted glass, to reduce reflections for a viewer. As another example, an adhesive layer used to secure an anti-glare layer to a substrate may include small air-bubbles, streaks or the like that act as light diffusers. Some examples of defects include streaks in various directions and in various widths. For example, streaks may vary from 1 inch or less to up to one-third or one half the screen width or greater, and may run top-to-bottom, left-to-right, diagonal, or the like. In embodiments of the present invention, defects of any characteristic are contemplated. 
   In light of the above, the inventor has developed additional embodiments to address these problems. Specifically, on one case, the inventors have discovered that optical techniques can be used to help reduce the optical defects when recording images to film. Other embodiments may include digital techniques to reduce optical defects. In still other embodiments, combinations of digital adjustment and optical adjustment techniques can both be performed. 
     FIGS. 3A-B  illustrates a flow diagram according to an embodiment of the present invention. In particular,  FIGS. 3A-B  illustrate a method for reducing the undesired optical distortions. 
   Initially, film recording device  102  is positioned with respect to flat panel display  104  to enable film recording device  102  to capture the entire display portion of flat panel display  104 , step  1100 . Next, flat panel display  104  is driven from CPU  106  with a first pre-determined image, step  1110 . In one embodiment, the predetermined image is an image with uniform output pixel values, for example, where all pixels are turned on. In various embodiments, all of the pixels are driven to a uniform brightness, for example, at their maximum value, e.g. R=256, G=256, B=256; or at any other pre-determined value, e.g. R=128, G=128, B=128. 
   In another embodiment, flat-panel display can be driven with a series of pre-determined images corresponding to primary color component. For example, first R=250, G=0, B=0; then R=0, G=250, B=0; then R=0, G=0, B=250. In these embodiments, the following steps may be repeated for each respective color component. 
   In the present embodiment, while flat panel display  104  is driven with uniform output pixel values, flat panel display  104  displays a image that includes optical distortions, step  1120 , such as those described above. For example, the image may correspond to the pre-determined image that is blurred slightly because of the anti-glare diffuse layer or the adhesive layer, or the like. 
   In one embodiment, film recording device  102  captures the image displayed on flat panel display  104 , step  1130 . Typically film recording device  102  exposes the image to one or more frames of film media, although any photo-sensitive, or radiation-sensitive media may also be used. These steps may be repeated in embodiments where color components are separately excited. 
   Next, the exposed frames are developed, and a complementing image is produced, step  1140 . As will be illustrated below, the complementing image will be used to help reduce optical distortions in subsequent images recorded onto film media. In one embodiment, the complementing image may be enlarged to be approximately the same size of the display area of flat panel display  104 , for example 23″ diagonal. In another embodiment, the complementing image will be kept as the same size. 
     FIGS. 4A-D  illustrate an example of an embodiment of the present invention.  FIG. 4A  illustrates an “ideal” image  1200  that should be recorded to a frame of film media without optical distortions. In this embodiment, this should correspond to the pre-determined image. For example, ideal image  1200  may be an image that is uniform in gray scale value and color. 
   In this example,  FIG. 4B  illustrates an image  1210  on a frame of film media including optical distortions  1220  with respect to ideal image  1200 . In this example, ideal image  1200  may have a uniform value of 256 or each color component. In contrast, image  1210  may have a uniform value of 256, but optical distortions  1200  have a value of 250. 
   In the present example,  FIG. 4C  illustrates an example of a complementing image  1230  formed in response to image  1210  in  FIG. 4B . In this example, complementing image  1230  includes a region  1240  that has a uniform value, and regions  1250  at a different value. Using the example in  FIG. 4B , region  1240  may have the value of 250, and regions  1250  may have the value of 256. As will be illustrated below, the values of complementing image  1230  approximately complement the affect of the optical distortions. 
   Returning to  FIGS. 3A-B , in one embodiment, the complementing image, is typically disposed in or near a focal plane of film recording device  102 , e.g. directly in front of flat panel display  104 , step  1150 . This embodiment assumes the complementing image is enlarged, as discussed above, and placed “in front” of a lens of film recording device  102 . In another embodiment, the complementing image is kept as the same size as the film media, and is disposed at the image plane of film recording device  102 , i.e “behind” the lens of film recording device. At this stage in the process, film recording device  102  is configured to optically reduce the optical distortions described above. 
   Next, flat panel display  104  is driven with one or more frames of image data, for example, frames of a movie, step  1160 . In response, flat panel display  104  displays the images, step  1170 . These images will typically exhibit the same type of optical distortions characterized above. 
   In one embodiment, these images are focused by one or more focusing elements of film recording device to the focal plane. The image is passed through the complementing image, before being exposed to the film media, step  1180 . As a result of this process, the frames of image data are recorded onto the film media with a reduced optical distortion. 
   As illustrated in the example in  FIG. 4D  a subsequent image  1260  that includes optical distortions  1270  is received. In one example, subsequent image  1260  has a grayscale value of 200, with optical distortions  1270  at value 194. Exposing subsequent image  1260  through the complementing image  1230 , produces image  1280 . In this example, image  1280  may have a uniform grayscale value of about 200. In other examples, the subsequent image  1260  may be a color image. 
   In the present embodiment, an additional step of increasing the exposure time, increasing the amount of illumination of flat panel display  104 , or the like may be necessary because of light attenuation due to the addition of the complementing image at the focal plane. 
   In other embodiments of the present invention, an optical distortion may be determined for each component color. For example, an optical distortion is characterized for a red channel, blue channel, and a green channel. In embodiments of the present invention, the optical distortions may bias one or more colors. In such a case, a composite complementing image may be formed by combining complementing images from each color component. If there is a channel bias, when viewed, the composite complementing image may illustrate the color bias. Subsequent images acquired through the complementing image will thus be corrected for color-based optical distortions. 
   In additional embodiments, display driver compensating techniques are also envisioned to reduce optical defects. In such embodiments, before subsequent images are sent to drive the flat panel display, they will be adjusted digitally, for example, combined with a digital compensation image. In such embodiments, the digital compensation image may be captured with an optical sensor, such as a CCD. Such a CCD should have a resolution at least double than the resolution of the flat panel display in each direction. In other embodiments, the digital compensation image may be determined by scanning and processing the image recorded in step  1130 , above. By recording the image in step  1130  onto film and digitizing the result, it is believed that the digital compensation image would be more accurate. In other embodiments, combinations of digital compensation and optical adjustment techniques can both be performed to reduce any optical distortion. 
     FIGS. 5A-B  illustrate a flow diagram according to an embodiment of the present invention. In particular,  FIGS. 5A-B  illustrate an alternative method for reducing the undesired optical distortions. 
   Initially, flat panel display  104 , is provided, step  1300 . As described above in  FIG. 10 , a typical flat panel display includes a number of layers, including polarizing media  1040  adhered to display substrate  1020 . Further, polarizing media  1040  may have an anti-glare feature, and/or additional layers disposed on top of it. 
   In this embodiment, flat panel display  104  is typically disassembled or removed from its plastic or metal housing, step  1310 . This may be done with care, with custom or special tooling. 
   Next, polarizing media  1040  is removed from display substrate  1020 , step  1320 . In one embodiment, polarizing media  1040  is typically a film or layer of polarizing material disposed within a plastic sheet, or the like. In such a case, removing polarizing media  1040  may be done by physically pulling upon the plastic sheet. It is contemplated that this step may remove all layers on top of display substrate  1020 . 
   In one embodiment, after removal of polarizing media  1040 , display substrate  1020  may still have a residual adhesive layer. This layer is removed, and/or display substrate  1020  is cleaned, step  1330 . The inventor tested a wide variety of cleaners and solvents in determining a solution necessary to clean the adhesive layer. In this example, to remove the adhesive layer from display substrate  1020 , the inventor has discovered that a solution including propanol and Glycol ethers is suitable for removing adhesive and cleaning display substrate  1020 . One such solution is marketed under the name “Expo White Board Cleaner.” 
   Next, film recording device  102  is provided and positioned relative to the modified flat panel display (flat panel substrate) typically in a manner described above, step  1340 . As disclosed above, film recording device  102  is one type of optical media recorder including one or more camera lenses depending upon specific configuration. 
   In the present embodiment, a linearly polarizing filter is coupled to the front of the camera lens, step  1350 . In embodiments of the present invention, the linearly polarizing filter may be placed in virtually any location on the optical path between the flat panel display  104  and film media in film recording device  102 . For example, the linearly polarizing filter may be placed adjacent to an image plane, may be placed in front or in back of a shutter of film recording device  102 , may be placed at the focal plane, or the like. In one embodiment, the linearly polarizing filter is positioned as a filter in front of the lens. 
   In one embodiment of the present invention, the linearly polarizing filter is typically freely rotatable around the optical axis of the camera lens such that the direction of polarization can be freely selected. Examples of a linearly polarizing filter are Mounted Linear Glass Polarizing Filters available from Edmund Industrial Optics, Royln Optics, Hiliopan, CVI Laser Corporation, or the like. In another embodiment, the polarizing filter may be in a fixed position, thus the direction of linear polarization will be in a fixed direction. 
   As illustrated in  FIGS. 5A-B , a determination is then made as to what polarity of images will be recorded onto the film media, step  1360 . More specifically, a determination is made by the user whether to record positive images onto film media or to record negative images onto film media. In other embodiments of the present invention, this step need not be performed. Instead, the system may be pre-configured to record only positive images or to record only negative images. This may be facilitated by having the polarizing filter be in a fixed position, as described in one embodiment, above. 
   In the case where the system is to record positive images, the linearly polarizing filter is rotated until a positive image is received by the film media, step  1370 . This can he determined by, for example, looking through a viewfinder of film recording device  102  and rotating and adjusting the polarizing filter until a positive image is viewed and is vivid in appearance. In this position, the linear direction of polarization of the linear polarizing filter will be oriented approximately 90 degrees from the linear direction of polarization of polarizing media  1030 . Further, the linear direction of the polarization of the linear polarizing filter will be oriented in approximately the same direction as the linear direction of polarization of polarizing media  1040 . In this embodiment, the system is thus configured to record positive polarity images to film media. 
   In the present embodiment, subsequent images output to the modified flat panel display are exposed to the film media as positive images, step  1380 . This “camera positive” may also be used as an “interpositive” from which master negatives for release prints can be made. In the case where the system is to record negative images, the linearly polarizing filter is rotated until a negative image is received by the film media, step  1390 . This can be determined by, for example, looking through a viewfinder of film recording device  102  and rotating and adjusting the polarizing filter until a negative image is viewed and is vivid in appearance. In this position, the linear direction of polarization of the linear polarizing filter will be oriented approximately in the same direction as the linear direction of polarization of polarizing media  1030 . Further, the linear direction of the polarization of the linear polarizing filter will be oriented approximately orthogonal to the linear direction of polarization of polarizing media  1040 . In this embodiment, the system is thus configured to record negative polarity images to film media. 
   In the present embodiment, subsequent images output to the modified flat panel display are exposed to the film media as negative images, step  1395 . This “original negative,” digital duplicate negative “dupe” or master negative may also be used an “internegative” from which “release prints” can be made. 
   The inventor has discovered that the ease of reconfiguring the system above, to record positive images or negative images to film media is unprecedented. For example, the process above may be repeated, as illustrated in  FIGS. 5A-B , to configure the system from recording positive images to recording negative images to film media, or to configure the system from recording negative images to recording positive images to film media. 
     FIG. 6  illustrates an embodiment of the present invention. In a first configuration  1400 , the system is configured to expose film media to a positive polarity image. Next with a simple turn of the linear polarizing filter, the system is a second configuration  1410 , and configured to expose film media to a negative polarity image. 
   In the foregoing specification, the invention has been described with reference to specific exemplary embodiments thereof. Many changes or modifications are readily envisioned. In light of the above disclosure, one of ordinary skill in the art would recognize that any number of applications of the above concepts are possible. For example, various embodiments of flat panel displays are contemplated such as LCD, OLED, Plasma, EL, and the like; various supplemental illumination sources are contemplated, such as xenon flash, argon flash, led, and the like; various positioning mechanisms are contemplated, such as movable platform on a track, gimbaled mechanism, and the like. 
   In other embodiments of the present invention, the removal of film or layers on top of the front substrate may simply be removed to increase image quality. In the case of a LCD panel, this removes the front polarization layer thus requiring compensation, as described in  FIGS. 5A-B . However in the case of OLED, Plasma, and other types of display without a polarizer, images may be directly acquired by the film recording device. 
   In the above embodiments, it is contemplated that the amount of time required to record an image from the flat panel display to the film media may be on the order of one second. In other embodiments where additional lighting embodiments are provided, the exposure time may be reduced further. In contrast, previous laser film recorders required exposure times of five or ten seconds, or greater. Accordingly, the recording process time is advantageously reduced. 
   In embodiments of the present invention, because the film recording process is reduced, users now have ability to directly create interpositive or internegative images not only camera negatives. The practical implications are that fewer film transfer processes or dupes are required between the exposed film media and the release print. Accordingly, release prints will have better quality by at least one or two generations, thereby increasing the quality of the release print and audiences&#39; theater experience. 
   In embodiments of the present invention, the inventors have determined that other advantages are provided. In the present embodiment, when a front polarizing film is removed from the flat panel display, to a casual observer, an image displayed on the flat panel display will disappear. This is because the human eye cannot typically distinguish between radiation polarization. More specifically, without the front polarizing film, a user cannot distinguish between linear polarization in an up-down direction and a left-right direction, for example. 
   Accordingly, images output by the modified flat panel display cannot be seen to an unaided user. An example of this is illustrated in  FIG. 6  where film media may be recorded however a casual observer  1420  cannot see what is being recorded on the flat panel display without assistance. 
   The inventor has recognized that this effect has practical advantages. One such advantage is a security function. For example, in an embodiment, a computer-image to film transfer is performed by an outside service organization. In such a case, the service personnel can configure the system in the manner described above, and can monitor the film transfer process, however they cannot actually view the images from the modified flat panel display. The secrecy of the film is thus more easily preserved, which is very important for blockbuster movies. Because the images cannot be easily viewed from the modified flat panel display, embodiments of the present invention can reduce unauthorized or pirated copies of a feature during the image to film transfer. 
   In another embodiment, personnel monitoring the transfer process may be authorized to view a restricted images or a set of images from the feature. In such cases, these personnel may be issued special Polaroid glasses (linearly polarized glasses) during such times, so they can directly view the image on the modified flat panel display. 
   Embodiments of the present invention may be applied to any type of image that may be displayed on a flat panel monitor. For example, the images may be computer generated, the images may be a combination of computer generated and live action, the images may be derived from any number of video sources such as 720i (30 fps), 720p (24 or 60 fps), 1080i (30 fps), 1080p (24 or 60 fps), or the like. Accordingly, the concepts disclosed above are extremely valuable in a variety of applications, e.g. military. 
   Further embodiments can be envisioned to one of ordinary skill in the art after reading the attached documents. In other embodiments, combinations or sub-combinations of the above disclosed invention can be advantageously made. The block diagrams of the architecture and flow charts are grouped for ease of understanding. However it should be understood that combinations of blocks, additions of new blocks, re-arrangement of blocks, and the like are contemplated in alternative embodiments of the present invention. 
   The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense. It will, however, be evident that various modifications and changes may be made thereunto without departing from the broader spirit and scope of the invention as set forth in the claims.