DE3235659A1 - Device for recording television pictures on a photographic film - Google Patents

Abstract

The invention relates to a device for recording television pictures on a photographic film, comprising a reproduction device for video signals, an optic device and a film camera, in which the reproduction device consists of light-emitting diodes (11), the amount of light of which per picture element can be changed by a control circuit (10) in accordance with the video signal and which are coupled via optical fibres (12) to the film camera in such a manner that the television pictures are imaged element by element on the film (14) of the film camera. <IMAGE>

Description

Device for recording television pictures on a

Photographic Fij m The invention relates to a device for Recording television images on photographic film with a playback device for video signals, an optical device and a movie camera. Such devices are used for permanent storage of -son television images, especially X-ray recordings.

In DE-PS 23 11 210 such a device is described, in which a camera is aimed at a television monitor and through a lens that takes television pictures. If an exposure is required after fluoroscopy, the camera has to be aligned with the monitor each time, because in particular a large-format camera covers the screen, making observation impossible power.

Therefore, hard copy units are used for image acquisition. One such ge image pickup device is described in DE-OS 29 36 228, in which A television monitor is installed in a housing, from which an exchangeable Optics the television picture is transferred to large-format sheet films. Such a one The device has a large volume and a high weight. Through the television monitor and the optics must be operated a relatively large effort for this device, Furthermore, due to cathode fatigue, aging occurs, which is caused by the adjustment of electrodnspa.anungs It has to be compensated and as a result the recordings are more blurred towards the end of the Letensdiuer will. Also falls with such a device, because of the non-ideal intensity distribution the electrons in the light spot and the modulation transfer function of the lens optics, the modulation transfer function decreases towards higher spatial frequencies.

The invention is based on the object of providing a device of the initially mentioned called type that can be kept small and only light in weight and which can be produced easily and without problems.

The object is achieved according to the invention in that the playback device from by a control circuit in their amount of light per pixel according to the Video signal is made up of changeable light-emitting diodes, which are connected to the film camera via glass fibers are coupled in such a way that the television pictures point by point on the film of the film camera can be mapped. This arrangement eliminates the need for a large and heavy television monitor with the associated, elaborate lens optics.

The effort is further simplified when the control circuit Light emitting diodes feeds a control signal line by line when the end points of the glass fibers arranged in a row that is in close, mechanical contact with the Film transmitted the television picture line by line, and if the film camera with a motor is provided, which enables the film to be advanced.

It has been shown to be beneficial when the line of endpoints The glass fibers form an angle of 900 with respect to the direction of advance of the film and when the film is fed step-by-step with line spacing. The more complex one Stepper motor can be omitted if the line of the end points of the optical fibers with the The direction of advance of the film varies from 900 different angles forms when the light emitting diodes the control signal according to its temporal occurrence is fed in succession and when the film is fed continuously. Different formats can be used when using each of the light emitting diodes several glass fibers are assigned whose (luerschnitte different dimensions exhibit.

The invention is based on an embodiment shown in the drawing explained in more detail. The figures show: FIG. 1 a known device for recording television images in an X-ray television ehailage, Figure 2 shows a representation to explain the principle a device according to the invention, Figure 3 is a plan view of the device according to FIG. 2 and FIG. 4, a block diagram of the control circuit shown in FIG.

In the figure 1, a high voltage generator 1 is shown, the one X-ray tube 2 operates, which emits a beam of rays that a patient 3 penetrates and falls on the one, fluorescent screen of an X-ray image intensifier 4. The television camera 5 coupled to the X-ray image intensifier 4 sets its output image in video signals that are reproduced on a monitor 6. On the screen A film camera 7 is aligned with the monitor 6. An optical device 8 forms the monitor image on the Film the camera 7, so that these pictures can be recorded. This is a known prior art Device which corresponds to that in DE-PS 29 11 210 already mentioned.

The complex image recording device, the monitor 6 with the camera 7 and the optical device 8, is represented by the device shown in FIG replaced. In the figure 2, a control circuit 10 is shown, which the video signal the television camera 5 is supplied. To the control circuit 10 is a number of Light-emitting diodes 11 attached, of which only two are shown for the sake of clarity are. The number of these light emitting diodes 11 depends on the desired resolution of the Film recording. In order to achieve a normal resolution, for example 1,024 light-emitting diodes 11 can be connected to the control circuit 10.

However, by increasing the number of the light emitting diodes 11, each desired matrix achievable.

A glass fiber 12 is attached to each of the light-emitting diodes 11. the End points 17 of the glass fibers 12 are arranged in a row and next to one another are in close mechanical contact with a sheet of film 14 that of transport rollers 15, of which at least one can be driven by a motor 16 i-t ;, held and is moved.

In the figure 3 is a plan view of the device according to the figure 2 shown. The light-emitting diodes 11 are connected to the control circuit 10, which can have any arrangement. For a better overview there are only three LEDs 11 shown. The glass fibers 12 attached to the light-emitting diodes 11 are aligned with the sheet film 14. The end points 13 of the glass fibers 12 are located close to one another, so that when all the LEDs 11 are controlled, a television line on the sheet film 14 is recorded and exposed.

The transport rollers 15 grip the sheet film on the side and move him past the row of end points 13 of the glass fibers 12.

The control circuit 10 controls the brightness of the light-emitting diodes 11 according to the video signal of the TV camera 5. Due to the different amount of light, which is produced by the light emitting diodes 11 in cooperation with the control circuit 10 is, an exposure of the sheet film 14 takes place in different shades of gray.

By the motor 16, the sheet film 14 is at the end points 13 of the Glass fibers 12 transported past so that the entire sheet film is exposed one after the other will.

The control of the light-emitting diodes 11 by the control circuit 10 can either at the same time by interposing spokes or one after the other according to the timing of the video signal. Forms the line the end points 13 of the glass fibers 12 with the direction of advance (arrow 17) of the film at an angle of 900, the motor 16 advances the sheet film 14 step by step in line spacing. On the other hand, it forms the line of end points 13 of the glass fibers 12 the direction of advance of the film at an angle different from 900 and become the LEDs 11 controlled according to the temporal occurrence of the video signal, the sheet film 14 can be advanced continuously by the motor 16.

In the figure 4 is a digital embodiment of the control circuit 10 shown. The video signal of the television camera 5 is in an analog / digital converter (A / D converter 20) digitized and stored in an image memory 21. The exit of the image memory 21 is connected to a multiplier 22 at whose second Input a memory 23 (for example E2.PROM) for correction values of the brightness differences the light emitting diodes 11 is connected. The multiplied digital values will be a further memory 24, for example a PROM, is supplied for g correction. The video signal corrected in this way is saved line by line in a buffer 25, a RAM. A subtracter 26 is connected to the buffer 25, which reduces the stored values by one with each run. The exit of the subtracter 26 is connected to a series of D flip-flops 27, which with are each connected to a driver 28 and the control of the light emitting diodes 11, which are connected to ground via resistors 29, cause.

A controller 30 is connected to the memories 21, 23 via address lines and 25 connected. The controller 30 also supplies clock signals for the buffer memory 25 and the D flip-flops 27.

After the television picture has been read into the picture memory 21, it is read line by line. The multiplier 22 is used to compensate for the differences in brightness of the light emitting diodes 11 carried out. The digital line signals are sent to the memory 24 supplied, in which the gamma correction for the television camera 5 is stored. The corrected signals are read into the buffer memory 25, one after the other read out pixel by pixel and reduced by one in the subtracter 26. These difference signals are again stored in the intermediate memory 25 aD. That Carry bit that is one as long as the difference signal is greater than one is, is buffered in the associated D flip-flop 27, so that the light-emitting diodes 11 can be controlled by the driver 28. The light-emitting diodes 11 remain so switched on for a long time until the digital value associated with the corresponding pixel of Video signal by continuously subtracting one in the subtraction stage 26 goes negative so that the carry bit goes to zero. The rest of the bars remain corresponding light emitting diode 11 switched off. That way are the digital values the stored in the buffer 25 line according to the number of different gray levels has been reduced, the sheet film 14 becomes one line transported further and can read the next line into the buffer 25 will.

Several glass fibers 12 of different diameters can be attached to the light-emitting diodes be assigned. This can either be done in that the glass fibers 12 together are attached to a light emitting diode 11 or that via Schaltvorricht.ungen that are inserted into the glass fibers 12, a selection of the different glass fibers he follows. Due to the different strengths of the glass fibers, different Film formats are exposed.

By eliminating the monitor's cathode ray tube and the The optical devices of the film camera are small and nevertheless high quality systems possible to record TV pictures. Aging also occurs due to cathode fatigue on. In principle, such a recording device cannot decrease the modulation transfer function towards higher spatial frequencies, not even at e.g. approx. 4000 pixels per Line, whereby today with commercially available electron beam picture tubes a significant Would adjust sharpness fall-off. This advantage is particularly evident at the edges of the image clear, since cathode ray tubes and lens optics always one from the center of the image have decreasing maximum resolution.

5 claims 4 figures Lee rode

Claims (5)

Claims device for receiving television images on a photographic film with a reproducing device for video signals, an optical one Device and a film camera, which is not marked, that the playback device is controlled by a control circuit (io) in its amount of light there are light-emitting diodes (11) that can be changed per pixel according to the video signal, which are coupled to the film camera via glass fibers (12) in such a way that the television images are imaged point by point on the film (14) of the film camera. 2. Apparatus according to claim 1, d a d u r c h g e -k e n nz e 1 c h n e t that the control circuit (10) sends a control signal line by line to the light emitting diodes (11) supplies that the end points (13) of the glass fibers (12) are arranged in a row, which in close mechanical contact with the film (14) line the television picture transmitted, and that the film camera is provided with a motor (16), the one Allows advance of the film (14). 3. Apparatus according to claim 2, d a d u r c h g e -k e n n z e i c h n e t that the line of end points (13) of the glass fibers (12) opposite the direction of advance (17) of the film (14) forms an angle of 900 and that the advance of the film (14) is carried out step by step with line spacing. 4. Apparatus according to claim 2, d a d u r c h g e -k e n n z e i c h n e, that the line of end points (13) of the glass fibers (12) with the feed direction (17) of the film (14) form an angle of 900 different det, that the light-emitting diodes (ii) the control signal according to its temporal occurrence is fed in succession and that the advance of the film (14) is continuous he follows. 5. Device according to one of claims 1 to 4, d a -d u r c h g e k e n n n e i c h n e t that each of the light emitting diodes (11) several glass fibers (12) are assigned, the cross sections of which have different dimensions.