The present invention relates generally to film scanning, and more particularly to a film bridge for use in the transportation and scanning of film in a film scanning system.
Color photographic film generally comprises three layers of light sensitive material that are separately sensitive to red, green, and blue light. During conventional color photographic film development, the exposed film is chemically processed to produce dyes in the three layers with color densities directly proportional to the blue, green and red spectral exposures that were recorded on the film in response to the light reflecting from the photographed scene. Yellow dye is produced in the top layer, magenta dye in the middle layer, and cyan dye in the bottom layer, the combination of the produced dyes revealing the latent image. Once the film is developed, a separate printing process can be used to record photographic prints, using the developed film and photographic paper.
In contrast to conventional film development, digital film development systems, or digital film processing (DFP) systems, have been proposed. One such system involves chemically developing exposed film to form scene images comprised of silver metal particles or grains in each of the red, green, and blue recording layers of the film. Then, while the film is developing, it is scanned using electromagnetic radiation, such as light with one predominant frequency, for example, in the infrared region. In particular, as the film develops in response to chemical developer, a light source is directed to the front of the film, and/or a light source is directed to the back of the film. Grains of elemental silver developing in the top layer (e.g., the blue sensitive layer) are visible from the front of the film by light reflected from the front source; however, these grains are substantially hidden from the back of the film. Similarly, grains of elemental silver developing in the bottom layer (e.g., the red sensitive layer) are visible from the back of the film by light reflected from the back source; however these grains are substantially hidden from the front. Meanwhile, grains of elemental silver in the middle layer (e.g., the green sensitive layer) are substantially hidden from the light reflected from the front or back; however, these grains are visible by any light transmitted through the three layers, as are those grains in the other two layers. Thus, by sensing, for each pixel location, light reflected from the front of the film, light reflected from the back of the film, and light transmitted through the film, three measurements can be acquired for each pixel. The three measured numbers for each pixel can then be solved for the three colors to arrive at three color code values for each pixel, and the plurality of colored pixels can then be printed or displayed to view the image.
If desired, such scanning of each frame on the film can occur at multiple times during the development of the film. Accordingly, features of the frame that may appear quickly during development can be recorded, as well as features of the frame that may not appear until later in the film development. The multiple digital image files for each frame can then be combined to form a single enhanced image file.
In another such digital film processing (DFP) system, a developer solution is applied to the film and dyes form on the film. As the film is developing via the applied solution, visible light and/or infrared light are applied to one side of the film. On the opposite side of the film, a sensor detects the light passing through the film and produces a digital representation of the image developing on the film.
With these and other digital film processing and scanning systems, the film can be moved across a scanning area, and the radiation can be applied to the scanning area to obtain the image data. A film bridge or similar support mechanism can be utilized to control the position of the film as it passes over the scanning area. For optimum accuracy in scanning of the film, the positioning of the film should be tightly controlled. In particular, vertical vibration and movement of the film should be avoided as such movements can jolt the film out of the focus of the optics, resulting in unfocused image data. Moreover, the film should remain substantially flat across the imaging area in order to obtain accurate results. In addition, the mechanisms used to transport and control the position of the film during scanning should avoid imparting scratches or other physical defects to the image area of the film, as such scratches and defects can result in an inferior digital image.
It is further advantageous to keep the film as close to the illumination cavity as possible. This produces the maximum illumination intensity through the film.
A conventional film bridge and illumination assembly or device is shown in
The present invention relates to a method and apparatus in which the magnitude and frequency of defects that are applied to the film during film transportation and scanning are reduced. More specifically, the invention provides for a film bridge design that reduces or eliminates film scratching and reduces the susceptibility of film to debris to prevent defects to the image.
The present invention further provides for a film bridge that is adapted to maintain the film in a flat state at a constant height, while at the same time permitting the application of a desired illumination intensity through the film.
The present invention therefore provides for a film bridge assembly for a film scanning system which comprises: a first bridge member having a first film facing surface; a second bridge member having a second film facing surface, with the first and second bridge members being spaced from each other to define a slot there-between that provides for a passage of illumination light from an opening of the slot through film traveling across the film bridge along a film path; and a cylindrical lens provided on the opening and extending between the first film facing surface and the second film facing surface, such that the film traveling across the film bridge contacts the cylindrical lens at or near an apex of the cylindrical lens and does not contact opposing edges of the cylindrical lens on each side of the apex.
The present invention further relates to a method of scanning film which comprises the steps of: locating a first bridge member having a first film facing surface and a second bridge member having a second film facing surface relative to each other so as to define a slot there-between that provides for a passage of illumination light from an opening of the slot through film traveling across the film bridge along a film path; providing a cylindrical lens on the opening so as to extend between the first film facing surface and the second film facing surface; and transporting film to be scanned across the film bridge in manner in which the film contacts the cylindrical lens at or near an apex of the cylindrical lens and does not contact opposing edges of the cylindrical lens on each side of the apex.
Another embodiment of the invention is to utilize the cylindrical lens at a shoe. The cylindrical lens could be placed just before or after the illumination slot to provide a shoe which the film slides over thereby maintaining a small gap from the illumination slot to the film. The shoe concept could be applied using single shoe before of after the illumination slot or to a dual concept with each part straddling the illumination slot.
The present invention therefore further relates to a film bridge assembly for a film scanning system which comprises a first bridge member having a first film-facing surface; a second bridge member having a second film facing surface, with the first and second bridge members being spaced from each other to define a slot there-between that provides for a passage of illumination light from an opening of the slot through film traveling across the film bridge along a film path; and a cylindrical part provided on one of the first or second film facing surfaces, such that the cylindrical part maintains a gap between film traveling across the cylindrical part and the opening from the slot.
Referring now to the drawings, wherein like reference numerals represent identical or corresponding parts throughout the several views,
Source 110 is positioned on the side of the film 112 opposite the optic sensors 102. This placement results in sensors 102 detecting radiation emitted from source 110 as it passes through the images 104 and 108 on the film 112. Another radiation source 111 can be placed on the same side of the film 112 as the sensors 102. When source 110 is activated, sensors 102 detect radiation reflected by the images 104 and 108. The process of using two sources positioned on opposite sides of the film being scanned is referred to as duplex scanning.
The optic sensors 102 are generally geometrically positioned in arrays such that the electromagnetic energy striking each optical sensor 102 corresponds to a distinct location 114 in the image 104. Accordingly, each distinct location 114 in the scene image 104 corresponds to a distinct location, referred to as a picture element, or “pixel” for short, in a scanned image, or digital image file, which comprises a plurality of pixel data. The images 104 and 108 on film 112 can be sequentially moved, or scanned relative to the optical sensors 102. The optical sensors 102 are typically housed in a circuit package or unit 116 which is electrically connected, such as by cable 118, to supporting electronics for storage and digital image processing, shown together as computer 120. Computer 120 can then process the digital image data and display it on output device 105. Alternatively, computer 120 can be replaced with a microprocessor or controller and cable 118 replaced with an electrical connection.
Optical sensors 102 may be manufactured from different materials and by different processes to detect electromagnetic radiation in varying parts and bandwidths of the electromagnetic spectrum. For instance, the optical sensor 102 can comprise a photodetector that produces an electrical signal proportional to the intensity of electromagnetic energy striking the photodetector. Accordingly, the photodetector measures the intensity of electromagnetic radiation attenuated by the images 104 and 108 on film 112.
As discussed above, in order to scan film 112, it is preferred that film 112 travel across a film bridge A film bridge assembly for a scanning system in accordance with the present invention is shown in
Cylindrical lens 200 is provided on the opening 212 so as to extend between the first film facing surface 204a and the second film facing surface 206a. Therefore, the film 112 traveling across the film bridge in direction 220 contacts the cylindrical lens 200 at or near an apex 224 of the cylindrical lens 200 and does not contact opposing edges 200a, 200b of the cylindrical lens 200 on each side of the apex 224. Therefore, the contact patch or the amount of contact between the window and the film is minimized with this geometry, thus keeping the film as flat as possible, eliminating window or lens edge scratching of the film, and minimizing the accumulation of debris.
It is preferred that the material for the cylindrical lens 200 be very hard in order to avoid scratching. The preferred materials are Sapphire and Diamond although any visibly clear hard material can also be used. The cylindrical lens 200 should be manufactured with minimum thickness to minimize illumination loss.
As shown in
Additionally, a cylindrical lens or part 200′ could be used as a shoe instead of a window as shown in
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.