DE2344040C3 - System for transmitting images - Google Patents

Description

The invention relates to a system for transmitting images of the type specified in the preamble of claim 1 Genus.

If images are transmitted using a conventional television system, an electron beam must be which has been modulated by a video signal can be produced on a fluorescent layer so that the observer can see the resulting image. In such a system, however, the Transmitting and receiving devices are relatively large, resulting in a complicated structure; besides, they are Difficulty producing, setting up and maintaining these facilities

Finally, it also prepares the handling of the picture tube Difficulties as it is very fragile and has a short lifespan. These disadvantages apply to a greater extent also for a color television system that has an even more complex structure with complicated Has circuits so that handling, adjustment

ίο and maintenance become even more difficult.

The manufacture of a color picture tube also requires very advanced technology. Will eventually The television images are transmitted by radio waves, the transmission may be disturbed by electrical waves

be, although in principle the transmission of television images is possible over great distances

A television transmission and reception system is known from "Electronics" of February 8, 1965, pp. 75 to 78, in which laser beams are used instead of electromagnetic waves. The laser beam is through Video signals in a transmitter are modulated at a remote location and received into electrical signals implemented; the television picture can then be viewed by means of a conventional television receiver.

From "Electronics" from May 11th! 970 is a multi-channel £ es Recording system known in which an argon laser beam, which modulates with the incoming data is recorded on 16 mm wide film by means of a mirror rotating at high speed will.

Finally, from DT-AS 18 00 665 a system of the type specified is known, which is used in a facsimile color image receiver is used. The color components red, green and blue are corresponding Receive color signals which originate from a certain point in the color image in the transmitting part. The three color signals are passed on to light control units via receiving and amplifying units which each contain a xenon discharge lamp. The output light rays from these discharge lamps through the corresponding color signal outputs of the associated receiving and amplifying units controlled whereby the intensity of the light beams according to the respective color signals will be changed.

The outputs of the light control units then become a single one by means of a half mirror system Composite light beam This composite, brightness-modulated light beam is then by a focusing system or by an oscillating mirror arranged in this system, which synchronously oscillates with the scanning period of the transmitter part and is driven by sawtooth pulses, in a horizontal direction Deflected direction; for scanning in the longitudinal direction, the recording material can, for example a photosensitive film, moved accordingly.

Finally, it is also known that the light beams obtained by scanning an original image are on the receiving side through red, blue and green filters to photomultiplier and then to the transmission line to pass on.

The known system for transmitting images has a relatively complicated structure, since, for example various light control units, each with a xenon discharge lamp and color filter, are provided are; in addition, either a photosensitive film or

a projection surface or a screen may be provided.

The invention is therefore based on the object qai system for the transmission of images of the specified To create a species in which both the transmitting part and the receiving part have a simple structure, em are light in weight and relatively small in size.

This object is achieved according to the invention by those listed in the characterizing part of claim l Features solved

The advantages achieved by the invention are in particular that this system is due to its simple structure particularly suitable for use in the private sector; however, it can also be used for Communications are used in the open air, as, for example, only secret information between can be transferred to two specific people. The system can also be used to to determine the direction between a transmitting part and a receiving part. The system is very handy, easy to transport and has low energy consumption. Its manufacturing costs are low, it is easy to operate and maintain.

Even if the light beam is relatively weak, as is the case, for example, when the receiving part is far away from the transmitting part, with the help of adapter devices, such as a telescope, a brighter, more luminous image can be obtained in the receiving part without great difficulty . Therefore, the light source in the receiving part can also be small, for example a point light source with high radiation density can be used. The energy consumption of the system itself can be then reduced again, when high brightness is he ^r orderlich so that even small light sources such as a light emitting diode or a laser source may be used; the light beams from such sources can easily be modulated with high-frequency signals.

Finally, the system has the particular advantage that images are flawless even in daylight can be transmitted, as the lighting conditions in the vicinity of the transmitter and receiver Do not affect transmission. So only the information that is related to the scanning of the image is received goes back in the transmission part

The invention is explained below on the basis of exemplary embodiments with reference to the schematic Drawings explained in more detail It shows

F i g. 1 shows the structure of a system for the transmission of images according to the invention,

F i g. FIG. 2 is an explanatory view of an image grid as seen in the eyes of an observer in FIG Receiving part of a system for the transmission of images occurs after the invention,

F i g. 3 is an explanatory view with an adapter unit, which in the receiving part of a further Embodiment of a system for the transmission of images according to the invention is provided,

F i g. 4 is an explanatory view showing the structure of a deflector included in the receiving section according to a further embodiment of the invention is provided,

F i g. 5 is an explanatory view which shows the mode of operation of the in F i g. 4 represents the deflector shown, and

F i ε. 6 shows the structure of a system for the transmission of color images according to a further embodiment of the invention.

According to FIG. 1 the system consists of a transmitting part 1 and a receiving part 2.

In the transmitting part 1 a light source 5 is provided, which emits a beam of light whose light modulates its brightness shall be. The light beam from the light source is brightness modulated by a video signal selectively through a video amplifier 4 from a television camera, video tape recorder (VTR) or other sources for the transmission of images has been supplied by the transmitting part 1 emitted brightness-modulated light beam 11 is received by the receiving part 2, which is in some The light beam 11 received there is passed through an objective lens 6 passed in the receiving part 2, passed through a half mirror 19 and then successively a flat reflector mirror 9, on a vertical, rotatable, multifaceted deflection mirror 13, on one horizontal, rotatable, multifaceted deflecting mirror 12 and reflected on a reflector mirror 10: subsequently the light beam is passed through an eyepiece 7 onto the eyes 18 of an observer. Part of the through the objective lens 6 guided light beam 11 is reflected on the half mirror 19 and in one photoelectric converter 14 is detected. The output signal of the converter 14 is used in a circuit 15 separated a synchronization signal, which in a drive amplifier 16 is reinforced; thereby the output signal of the drive amplifier 16 can be a motor 17 drive synchronously in a rotary movement.

Due to the synchronous rotation of the motor 17, the horizontally deflecting, rotatable, polyhedral rotate Mirror 12 and the vertically deflecting, rotatable, multifaceted mirror 12 in a synchronous relationship the video signal of the transmitter part 1.

As a result, the light beam emanating from the transmitting part 1 is both horizontal and horizontal vertical direction deflected so that a certain synchronous relationship is maintained; in this way a scanning raster of the light source 5 is created on the retina of an observer 18.

When an observer looks at the light source 5 of the transmitting part by looking into the eyepiece 7 of the receiving part looks, then a grid 21 of the light source 5 can be visually detected as a two-dimensionally developed image due to a physiological afterimage effect on the retina and a memory effect arises in the observer; in this way a clear image 22 in space is obtained, as in FIG. 2 is shown.

The underlying principle can easily be explained in the following case: If a punctiform Light source, such as B. a flashlight, swinging vertically and horizontally in the dark then a two-dimensional image appears in space.

If, on the other hand, the transmitting part is viewed through the receiving part, the environment is based on the Above-mentioned deflection scanning completely disturbed; the visual formed by the light source 5 of the transmitting part Place therefore represents a characteristic image that is not exposed to any influence from the environment

The system for transmitting images according to FIG. 1 thus enables image information to be transmitted at a relatively large distance if a telescope is used in the receiving part instead of the objective lens 6 will; with it you can also make transmissions at

cover even greater distances at sea or at night.

If the light beam emanating from the transmitting part and received by the receiving part, relative is weak, as shown in FIG. 3 is shown, then the Receiving part can be provided with a device 23 serving as an adapter for light amplification; For this can e.g. B. an image intensifier tube behind the objective lens 6 can be used.

Furthermore, an infrared radiation source can be used as the light source 5 in the transmitting part while A device for converting light can be used as an adapter in the receiving part, which converts invisible light into visible light; to an image converter tube is suitable, for example.

Furthermore, a laser oscillator can be used as light source 5 in the transmitting part, while a device for light conversion that converts invisible to visible light, such as B. an image converter tube, can be used as an adapter in the receiver to protect the eyes. In this case it can if necessary, a light amplifier device such. B. an image intensifier in combination with a Light amplifier can be used.

In the following, F i g. 4 will be explained, the one represents another embodiment of the invention; it uses a piezoelectric element as a deflection device used for the light beam instead of the rotatable, polyhedral mirror as described above would.

The light beam 11 from the light source 5 is guided through the objective lens 6 and reflected on the plane Mirror 9 reflects; then it becomes two-dimensional on a vertical deflector 24 and a horizontal deflection device 25 using an electrical deformation element, such as B. a piezoelectric element developed; thereafter, the light beam thus developed is reflected on the reflecting mirror 10 and then as it was explained in connection with the previous embodiment, to the eyes 18 one Observer.

The construction of the vertical deflector 24 and the horizontal deflector 25 using piezoelectric elements is shown in FIG. 5 shown. In other words, F i g. 5 shows the vertical deflection device 24 according to FIG. 4, but the horizontal deflector 25 has the same structure as that in FIG. b is shown. Here, the light beam 11 guided through the objective lens 6 is reflected on a reflecting mirror 27 'which is provided on the surface of one side of an electrode plate 27 of the piezoelectric element 26; the light reflected in this way is then at a, the mirror 27 'opposite-

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, Bigiger Mate zwxsc & en reflect warning on the Qewinii <L h, which is through the light beam 11 in the vertical direction developed. The light so developed is deflected on the horizontal deflector 25 in FIG. 4 that the in F i g. 5, developed two-dimensionally; then it is applied to the reflective Mirror 10 reflected light given through the eyepiece lens 8 onto the eyepiece 7 and onto the observer's retina 18 developed two-dimensionally as described above with reference to FIG. 2 was explained.

ίο In F i g. Fig. 6 shows an embodiment of the system for transmitting images according to the invention which is suitable for transmitting a color image; Here, a light source 30 is provided in the transmission part 1, which contains light emitting elements R, G and B , which emit the three primary colors; this light source 30 replaces the light source 5 in the transmitting part 1 according to FIG. 1. The three light-emitting elements of the light source 30 are arranged side by side, seen from the front; its light is modulated in brightness by a three-color signal supplied via an input 3 and an amplifier 4 from a television camera, video tape recorder or other source of video signals. The light of the three primary colors from the light source 30, the light of which is brightness-modulated by the three-color signal, is developed two-dimensionally as a clear color image on the retina of the eyes 18 of an observer as if it were in space in the direction of the transmitter part 1.

If a diffuser plate 31 in front of the light source 30 from the three color emitting elements in the transmitting part 1 is provided, the result is a better color mixing effect d. H. the obtained color image as it seen by an observer's eyes has almost the natural colors.

In all of the aforementioned embodiments, the image in the receiving part 1 z. B. in a rows and columns having a grid, similar to a television picture on the screen of a conventional television receiver, reproduced. The brightness of the individual image signals (e.g. raster image points or image lines) is in each case controlled by the video amplifier 4 in the transmitting part 1 The position of the individual video signals (z. B. raster pixels or image lines) is in each case by the rotatable multifaceted deflecting mirrors 12 and 13 or the piezoelectric Devices 24 and 25 influenced which in turn in turn by the circuit for separation of the synchronization signal 15 and the drive amplifier 16 are controlled.

For example, in the embodiments of FIGS. 1, 3 and 6, the multifaceted deflecting mirror 12 is driven directly by the motor 17, whereas the multifaceted deflecting mirror 13 is driven by the motor 17 via a scfaaeA "affin <rif ^ anffitriefcea ^ wffdtsedaft!"
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! guided light beam is expediently placed so that its speed and phase position with the ister image point recording frequency and recording phsystem coincide or correspond to this so is the picture is displayed correctly.

To do this, 5 sheets of drawing cards

Claims (6)

Patent claims: ^ I. System for the transmission of images, in which the image to be transmitted is scanned and a light beam is modulated in its brightness with the video signal obtained in this way and is directed from a transmitting part to a receiving part, where the light beam by means of a deflection device that is made by the received brightness-modulated light beam is controlled, a horizontal deflection undergoes a horizontal deflection, characterized in that only the transmitting part (1) a light source (5, 30) emitting the brightness-modulated light beam and the receiving part (2) an eyepiece (7) for direct viewing of the received , brightness-modulated light, wherein the light beam (11) in the receiving part (2) is previously not only deflected horizontally but also vertically by a further deflection device (13, 24), controlled by the synchronization signals. 2. System for the transmission of images according to claim 1, characterized in that the light source (30) has the three primary colors emitting radiation elements (R. G, B) , wherein the light beam (II) is brightness-modulated by the three-primary color signal as a color image signal. 3. System for the transmission of images according to one of claims 1 or 2, characterized in that that the deflection devices have a vertical, rotatable, multifaceted deflecting mirror (13) and a horizontal, rotatable, multifaceted deflecting mirror (12) which are synchronized with the video signa! rotate. 4. System for the transmission of images according to one of claims 1 or 2, characterized in that that the deflection devices have electrical deformation elements (26) by a voltage synchronized with the video signal can be controlled. 5. System for the transmission of images according to one of claims 1 to 4, characterized in that that the synchronizing signals through a photoelectric conversion element (14) in the brightness modulated Light beam (11) detected and separated by a circuit (15). 6. System for the transmission of images according to one of claims 1 to 5, characterized in that that the receiving part (2) for detecting the light beam (11) from the transmitting part (1) with a telescopic lens (23) is provided