DE19813125A1 - Position hole scanning equipment for use in a film scanner. - Google Patents

Abstract

The postioning/sprocket holes of the film (1) are scanned into the relevant scanned frame by the film scanner which illuminates (7) the positioning holes and diverts (11) the image to an optical scanner (14).

Description

The invention relates to a film scanner with a light source for illuminating Perforation holes of a film to be scanned and an optical scanner for scanning palpation of the illuminated perforation holes.

Various are used in film scanners to derive correction signals Regulation of the transport speed or the image position of the perforation holes Films optically scanned. For example, a film scanner is known from US 4,855,836, where another near an arrangement for optically scanning the film images Arrangement for optical scanning of the perforation holes of the film is arranged. At this film scanner comprises the arrangement for optically scanning the perforations Both a light source for illuminating the perforation holes as well as an optical scanner for scanning the perforation holes. The film is here guided by means of a roller which has guide webs on its side parts.

Ideally, when scanning perforation holes, that perforation hole should be be scanned, which in the recording camera for positioning the respective Film image was used. With the majority of footage to be scanned this is the pair of perforations leading a film image, which is more common wisely referred to as Mitchel holes. Because the Mitchel holes in particular are very close to the film image to be scanned in each case is a direct scanning of the Mitchel holes are particularly difficult. There is often no space at this a lighting source or a camera to scan the Mitchel Make holes because this is exactly where the film picture is made by guide elements is led to mechanical improvement of the image state. If necessary, a Attachment of lighting source and perforation hole scanner at this point too denied by the film scanning head, which is used to scan the film image.  

The object of the invention is to provide a film scanner in which there is a scan perforation holes close to the scanned image.

This object is achieved in that an optical deflection device is provided is.

By means of such a deflection device, the image of the perforation hole is made from the Projected area of the guide element so that the sensor for scanning the Perforation hole can be placed away from the film scanning head. Because one optical deflection device can be made much smaller than one for Ab sensing the perforation hole suitable sensor, is subject to the construction of the Film scanning head, or the entire film scanner in terms of perforations hole scanning with minimal restrictions. Optionally, the optical deflection device can also be used to illuminate the perforation holes.

This configuration offers the advantage that the light source for illuminating the or Perforation holes or the sensor for scanning the perforation hole or holes can be arranged almost anywhere on the film scanner, at one point which least disturbs them.

For example, mirrors or prisms are suitable as optical deflection devices.

The invention is now based on an embodiment shown in the figures described and explained in more detail.

Show it:

Fig. 1 A film scanner

In the exemplary embodiment, a film 1 is continuously scanned in a film scanner. For this purpose, the film 1 to be scanned is driven by means of a capstan 2 and passed through a between an illumination source 3 for the purpose of exposing the film image and an image sensor 4 . In this embodiment, lighting source 3 and image sensor 4 form a structural unit, which is referred to below as a scanning head. Due to the structural unit of the illumination source 3 and image sensor 4 , when the scanning head is changed, for example to scan a different film format, it can be exchanged in one piece for another scanning head.

To guide the film 1 within the scanning head 3 , 4 , the film 1 runs on a film carrying device 5 on a curved path. This web run is forced by means of skid-like guide elements 6 , on which the film rests and slides outside the film images.

In the embodiment shown in FIG. 1, only one of the two perforation holes that come into question for scanning is scanned to correct vertical and horizontal image position errors. In the exemplary embodiment, infrared light is used to illuminate the perforation hole, which surprisingly reproduces the edges of the perforation holes with particularly high contrast. This infrared light is generated by means of an infrared diode 7 . The infrared diode 7 is loosely coupled to a light guide 8 , which guides the light of the infrared diode to a recesses 9 within the skid-shaped guide elements 6 . The recess 9 is closed with an optically transparent cover plate 10 , so contamination of the recesses 9 by film abrasion is avoided. In this way, the guide elements 6 can be designed completely freely for optimal film running, without having to make constructive compromises in favor of the lighting of the perforation holes.

An optical deflection device is arranged above the exit surface of the infrared light, by means of which the image of the respective perforation hole is guided to a spatially separated line camara 14 . In the exemplary embodiment, this optical deflection device consists of an adjustable mirror 11 which is fastened to a supporting rod 12 , the supporting rod in turn being fastened by a holding device 13 which is brought outside the scanning head.

In the embodiment, the support rod 12 is made of a round rod, the outer surface of which is milled segment-shaped on one long side. In this way, the round rod can be shifted in length but can be rotated in a correspondingly prepared recess in the holding device and, for example, can be releasably connected to the holding device 13 with a screw, which is not shown for reasons of clarity. Before changing the optical scanning unit 3 , 4 , the support rod 12 together with the deflecting mirror 11 can be removed after loosening the screw. After reinserting a scanning head 3 , 4 , the carrying rod is pushed back into its holder and the screw tightened. Because of the torsion-proof design of the support rod 12 , the support rod 12 or the deflecting mirror 11 which is fixedly connected to the support rod only needs to be adjusted by axial displacement after the support rod 12 has been inserted into the holder 13 ; an adjustment with respect to other spatial axes is omitted.

Two separate line cameras can be used to detect two perforation holes, the optical deflection device projecting the images of both perforation holes out of the area of the scanning head 3 , 4 . However, since suitable line cameras are not cheap and would also have to be adjusted accordingly, the only line camera 14 has a prism 16 in front of it, by means of which the two images of the perforation holes lying opposite one another are imaged onto the one line camera 14 .

In the exemplary embodiment described above, the illumination of the perforation holes by the film carrying device 5 and the scanning by means of an optical deflection device 11 have been described. Depending on the specific configuration of the film scanner, an arrangement may also be useful in individual cases in which the perforation holes are illuminated from above via the deflection device 11 and the image of the perforation hole or holes through the optically transparent area of the guide element, for example also via an im or further optical deflection device arranged below the film carrying device 5 is led to the optical scanning sensor.

Claims (3)

1. Film scanner with a light source for illuminating perforation holes in the film to be scanned and an optical scanner for scanning the illuminated perforation holes, characterized in that an optical deflection device ( 11 ) is provided. 2. Film scanner according to claim 1, characterized in that the deflection device ( 11 ) is designed to be adjustable. 3. Film scanner according to claim 2, characterized in that mirrors ( 11 ) or prisms are provided as optical deflection devices.