DE3438322A1 - Method and device for transmitting signal data - Google Patents

Abstract

A method and devices for contactless transmission of signal data between a photographic lens and a camera are described. In this arrangement, a defined radiation is generated and at least one of its characteristics is varied in accordance with at least one mechanical manipulated variable. The radiation which has been subjected to variation is converted into an electrical signal which is used to display the manipulated variable and/or to control camera functions.

Description

Procedures and facilities for

Transmission of signal data The invention relates to a method and devices for the transmission of signal data between lens and camera System cameras.

Procedures and facilities of this type are required, for example Sizes such as set distance, work aperture and others on the corresponding billing and / or to transmit display devices in the camera.

This is the case with modern System X cameras with interchangeable lenses, for example from DE-OSs 32 41 778, 32 09 364, 31 06 592 and others, known, electrical To use contacts as transmission elements.

However, these facilities are advantageous in some respects a number of disadvantages that have a negative impact on manufacturing. Because there are within of the lens means required which the mechanical Manipulated variables (e.g. those of the aperture setting ring or the distance setting ring) convert it into electrical signals. This is done with potentiometers, contact slides or the like, which interact with resistor and / or diode networks that in the very limited space available only when it is extremely small and therefore more sensitive to adjustment Construction can be accommodated, small components of this type require a high Manufacturing effort and are not necessarily reliable in terms of operational safety.

Also the ones required to transfer the signal data to the camera Camera-side contacts or contact strips have how they make contact also disadvantages with regard to possible interference. The resilient contacts or contact strips must namely against unintentional bending and soiling be protected so that the contact is not prevented or changed in a fluctuating manner will.

The invention is therefore based on the object of a method and To name facilities for its implementation, in which the transfer of Signal data between lens and camera takes place without contact. In addition, should the facilities are easy to assemble, and there should not be any susceptible to interference Components are used.

The invention relates to a method of the type mentioned at the beginning Kind of which (a) a defined radiation is generated, (b) this radiation corresponds to at least one mechanical manipulated variable in at least one of its properties is varied, (c) this varied radiation into an electrical one Signal is converted, and at which (d) this electrical signal for display the manipulated variable and / or is used to control camera functions.

The device according to the invention for carrying out the process is characterized is characterized by the fact that Ca> the camera housing generates a defined radiation Contains means, (b) the objective optical means for receiving and guiding them Radiation as well as its return to the camera housing, Cc> the lens additionally with said radiation corresponding to at least one mechanical Manipulated variable equipped in at least one of their properties varying means is, and that (d) means in the camera housing for evaluating these variation (s) of Radiation with regard to the display of the manipulated variable and / or the control unit Camera functions are provided.

Advantageous further developments of the device according to the invention are Subject of the subclaims.

In the drawing, the invention is shown schematically in exemplary embodiments and described in more detail below.

1 shows a signal transmission device operating with ambient light, FIG. 2 shows a signal transmission device operating with artificial light, FIG. 3 shows a Device according to the invention with lateral radiation reflection, Fig. 4a u. 4b shows exemplary embodiments for a single-channel transmission device in detail, Fig. 5 shows a with the invention.

Device usable mold screen, Fig. 6 shows a device with a gray filters influencing the radiation, Fig. 7a to Fig. 7c eIR S signal data transmission direction with the radiation varying pole filter and FIGS. 8 to 10 exemplary embodiments for a multi-channel transmission device, FIG. 11 shows a device according to the invention with scaling that influences the radiation.

The device shown in Fig. 1 for the optical transmission of Signal data uses the ambient light (daylight ). Faith is in here Camera housing 1, only hinted at, through lens 2 and bayonet bracket 3 illustrated lens adjusted.

For the optical transmission of a lens date, e.g. B. the relative Opening, the camera housing 1 is reflective on its side facing the lens Areas 4 provided, from the surrounding light (daylight) one here by a dash-dotted line Line 5 directs indicated radiation to the lens.

The one derived from the ambient light (daylight) and deflected by the surface 4 Radiation enters the lens through an opening 6 in the bayonet mount 3. Her Intensity is varied by a diaphragm 7, which is connected to a bayonet mount 3 rotatably mounted aperture setting ring 8 is firmly connected.

A deflecting mirror 9 is mounted in the interior of the lens, from which the radiation is reflected towards the camera. After their exit from the to the camera body 1 open bayonet carrier 3, it falls on a photoelectric receiver 10, which is arranged behind a protective cover 11 in the camera housing 1.

The camera electronics, which are not shown here, can provide its output signal without further signal conversion as an electrical variable for suitable further processing are fed.

The main advantage of a device designed in this way can can be seen in the fact that at the coupling place between objective and the transmission channel on the camera side, an (air) gap can remain, its Width is completely uncritical and there is no risk of abrasion. The inlet and outlet openings on the lens and camera can also be covered with a transparent one Medium to be filled, with which a hermetically sealed seal of the camera resp. the inside of the lens can be reached (no risk of corrosion or contamination).

This is particularly the case with the exemplary embodiments in FIGS 3 can be seen, in which the same components in FIG. 1 are provided with the same reference numerals are. In order to be independent of the fluctuations in the intensity of the ambient light (daylight) to be, the facilities shown there work with artificial light.

In the embodiment of Fig. 2 is located behind a Lens contact surface 12 of the camera housing 1 a light source 13, such as. B. an incandescent lamp, a light emitting diode or the like. After their activation, something emanating from them occurs Light tufts - also indicated here by the dash-dotted line 5 - through a Exit opening 14 in the lens contact surface 12. This opposite is in the Arranged on the rear surface of the objective 2, 3 is an inlet opening 15 through which the light bundle reaches the inside of the lens. On the inside of the lens surface and on the inner barrel of the lens is one with the aperture setting ring 8 through one Stud 16 firmly connected diaphragm 17, which the emitted from the light source 13 Light tufts of information to be transmitted varies accordingly.

The one used here, as in the case of the device according to FIG. 1, In the simplest case, light-influencing means can consist of an opaque one Aperture - of which a detailed description is given below - exist, which the path of the bundle of rays e.g.

only releases or darkens when using the aperture adjustment ring 8 the smallest aperture is set.

A deflecting prism 18 is fixed behind the diaphragm 17 in the lens space arranged, which the light bundle through the bayonet bracket open towards the camera housing 1 3 leads back to the camera, where it, as described for Fig. 1, after enforcing the Protective screen 11 acts on the photoelectric receiver 10.

The embodiment of Fig. 3 shows a "side" lighting of the information transmission channel. For this purpose, the camera housing 1 has at least in a part of the rear part of the bayonet support 3 overlapping formation 19, behind the inner wall of which the artificial light source 13 is arranged. A The light bundle derived from the radiation passes through an exit opening 20 in the recess 19 and an inlet opening 21 in the outer wall of the bayonet support 3 inside the lens. A half-cube prism 22 deflects the light bundle by 900 and on a panel rotatably mounted on the inner rear wall of the bayonet support 3 23, which is connected to the aperture setting ring via driver ring 24.

After the intensity variation of the light bundle through the diaphragm 23 leaves this through an outlet opening 25 in the rear surface of the bayonet support 3 the interior of the objective and passes through an inlet opening 26 in the objective contact surface 12 of the camera housing 1 back into the interior of the camera. There it meets the one behind the protective screen 11 arranged photoelectric receiver 10, which is from the lens transmitted information containing output signal, as already described above, is further processed in the camera electronics.

Fig. 4a shows that it is possible according to the invention in which Use of a deflecting prism according to FIG. 2, the transmission channels not just one above the other (= Fig. 2) but also to be arranged side by side. In addition - the better one For the sake of clarity, only the essential and functional components of the device according to the invention shown - the deflecting prism 18 arranged in the lens so that his incoming or outgoing axis beam 27 with the side by side on the same Height and in the same plane center lines of the exit and entry openings 28, 29, the movable screen 17, a free opening 30 and return opening 31, 32 flees. The distance between the center lines is then simply determined by the distance the reflection surfaces of the deflecting prism 18 determined, of which the radiation the light source 13 diverted light bundles in the lens interior and to Camera body is returned.

According to the invention, however, it is also possible that a fixed light-influencing means is used. Such an embodiment is shown in Fig. 4b.

As in FIG. 2, the return openings 31, 32 are perpendicular below the exit and entry opening 28, 29 for the light bundle emanating from the light source 13. Since, as stated above, the diaphragm is fixed here, the deflecting prism 18 can here with a device not described in detail in front of the openings 28, 29, 31 and 32 be swiveled and thus set the device in function. When swiveled out Prism, the photoelectric receiver 10 receives only a dark information. It takes place so no signal data transmission.

If information can take on several values, this can also can be easily transferred.

Deviating from those shown in the previous exemplary embodiments circular apertures, the light-attenuating agent can gradually decrease of the light directed into the camera housing depending on the position of the Effect adjusting ring. Such a diaphragm is shown in FIG.

As FIG. 6 shows, the step-by-step reduction in the data transmission The light used also takes place by means of a gray wedge 33, which is not the case here is coupled with the diaphragm adjustment ring 8 and the radiation variation connected in the lens interior between light source 13 and photoelectric receiver 10 will. This can be a continuous gray wedge or a "gray step wedge" Act.

It lies within the scope of the invention that other than described up to here Diaphragm shapes or color filters are used to vary the radiation.

A particularly simple solution arises when using a 7a-7c connected to the respective adjusting means Polarization filter 34, which is in the beam path of the derived from the light source 13 Radiation is laid. This radiation becomes like the figures described above described, deflected by the deflecting prism 18 in the lens 2.3 and to the camera housing 1 returned. A splitter prism 35 is mounted there, through which the radiation to photoelectric receivers equipped with crossed analyzers 36 resp. 37 reached.

The one between the light source 13 and the photoelectric receiver 26 or 37 placed polarization filter 34 does not change when the here is rotated Adjustment ring 8 shown by, for example, 900 the polarization state of the remitted Radiation in the polarization direction indicated by arrows in FIGS. 7a-7c. The ratio of the two components from the photoelectric receivers 36 and 37 generated electrical signals represents a measure for the relevant manipulated variable, z. B. the distance set on the lens.

By arranging several such devices, naturally multiple pieces of information independent of- are transmitted to each other.

As the embodiment in Fig. 8 shows, it is possible to to illuminate several transmission channels from just one light source. In addition is after the light source 13 a lighting strip 38 arranged from a staircase Prisms 39 - 41 are provided, which the light from the light source 13 to the individual Openings 42 - 44 of the diaphragm 17 directs the radiation the corresponding information imprint. The return of the radiation to the camera body 1 and the photoelectric Receivers 10 takes place, as described above, through the deflecting prisms 18.

However, it may be necessary for reasons of rationalization and space be that when transmitting by means of several information channels only one deflecting prism and a common photoelectric receiver can be used.

Such an exemplary embodiment is shown in FIG. 9. For each information channel separate light sources 45 - 47 are provided here, the radiation of which the openings 42 - 44 penetrated in the diaphragm 17. Is directed around and back to the camera housing 1 the radiation through a prism 48, the reflection surfaces of which are designed in such a way that the radiation is directed onto a common photoelectric receiver 49. It goes without saying that in this embodiment the radiation is offset in time is emitted from the light sources 45-47.

The feedback of information from the lens to that in the camera body 1 arranged photoelectric receivers can also be deflected by the radiation in different directions. An embodiment of this is shown in Fig. 10, in which, for the sake of clarity, only light source 13, deflecting prism 50 and photoelectric Receivers 51 and 52 are shown.

As can be seen from this figure, this is the radiation from the light source 13 to the camera housing reflecting surface in a first surface 53 and in a second Area 54 subdivided with different degrees of inclination against each other. When bringing in of the deflecting prism 50 into the radiation of the light source 13 (indicated by the double arrows) the latter is based on the photoelectric, for example, arranged one above the other Projected receivers 51 and 52.

The proposed principle also allows particularly simple Way the input of objective-specific, temporally unchangeable data. Usually Lenses are now attached to the camera body using bayonet mounts. While When the lens is attached, there is inevitably a relative movement of the lens mount and camera body to each other. This movement usually corresponds to one Renkwinkel from 45 - 60 degrees.

Will. e.g., as shown in Fig. 11, on the mount of the lens 3 a grid division 55 attached, so when attaching the lens, the number of Grid lines (which differ depending on the information to be transmitted is) "read" (e.g. the number of aperture steps of the lens in question), if care ge is carried that information channels according to Fig. 2 and 3 are arranged. It does not matter whether the division is on the face or the circumferential cylinder of the lens 3 is arranged. The lattice structure can can be scanned both as a reflective structure and in transmitted light.

This thought can be applied to the transfer of the current values, for example temporally variable setting variables are expanded. Is z. B. with the aperture or Entferungseinsteliring a lattice disk coupled, which in the beam flux intervenes, so can by "counting" the adjustment through the beam path light or dark bars running through the adjustment of the element concerned reported to the camera. Suitable methods are from industrial metrology known and do not require any further explanation here.

The examples listed make the very diverse possible variations of the new transmission principle. Completely independent of the special design What all variants have in common is that the lens is only passive and easy to manufacture and temporally stable components (slider, grille, filter), which by the covering transparent protection against external influences and completely protected at Attaching / removing the lens are not exposed to any mechanical wear. As already stated, it is a major advantage of the disclosed invention, that between the corresponding light passage openings on the camera and lens there is a larger, completely uncritical distance. This means that the irradiation of loading illuminating light not only (preferably) in the direction the optical axis, but also laterally or obliquely, even from a certain Removal can be done.

The increased inevitably associated with the proposed arrangement Power consumption (for the LEDs) can be drastically reduced if the Continuous lighting a pulse-like lighting is provided, which only in the moment a flash of light is generated in which the camera electronics determine the relevant status value "queries". This also provides an effective suppression of any extraneous light interference, the z. B. can be caused by stray light that occurs at the coupling point entry. This variant is also part of the new solution proposed here.

It is of course also within the scope of the invention that the Feeding the illuminating light to the location of the respective, influencing the beam path By means (aperture, etc.) and / or the derivation of the light influenced in the lens to the receiver or receivers via fiber optics instead of those shown by way of example Deflecting prisms takes place. Because of the limited space, have such Fibers (limited bending radius), however, have certain disadvantages compared to prismatic elements, which are advantageously and inexpensively molded from transparent plastic material can be.

Claims (24)

Claims 1. A method for the transmission of signal data between lens and camera in the case of system cameras, d u r c h e k e n n n z e i c h n e t S that (a) a defined radiation is generated, (b) this radiation at least accordingly a mechanical manipulated variable is varied in at least one of its properties, (c) this varied radiation is converted into an electrical signal, and that (d) this electrical signal for displaying the manipulated variable and / or for controlling Camera functions is used. 2. Device for the transmission of signal data between lens and Camera in the case of system cameras, that is not indicated (a) the camera housing (1) contains a defined radiation generating means (4,13,20,28), (b) the objective (2,3) optical means (6,9,15,18, 21,48,50) for recording and for Guiding this radiation and its return (25,31) to the Kameta.housing (1) has, (c) the objective (2,3) additionally with the said radiation accordingly at least one mechanical manipulated variable in at least one of its properties varying means (7, 17, 21, 33, 34, 42-44, 55) and that (d) in the camera body (1) Means (10,36,37,49) for evaluating these variation (s) in radiation in view on the display of the manipulated variable and / or the control of camera functions are. 3. Device according to claim 2, d a d u r c h g e -k e n n z e i c This means that the camera housing (1) is provided with at least one mirror element (4?) is which from the ambient light (daylight) a defined radiation to the lens (2,3) steers and has an opening (26> through which the lens (23> returned Radiation enters the camera housing (i). 4. Device 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 in the camera housing (1) a defined radiation from the ambient light (Daylight) dissipating inlet opening (6,14,20,28) and at least one radiation back to the lens (2,3) leading output (26,32) is provided. 5. Device 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 an artificial light source (13,45-47) is arranged in the camera housing (1) is, which emits a defined radiation, which through an opening (14,25,28) is guided in the camera housing (1) to the lens (2, 3). 6. Device according to claim 5, d a d u r c h g e k e n n z e i c n e t that in the camera housing (1) means for intermittently switching on the Light source (13) are provided. 7. Device 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 lens (2, 3) on its flange surface facing the camera housing (1) (12) at least one inlet and outlet opening (6,15,21,25,29,31) occupied. 8. Device 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 for the conduction md return of the radiation in the objective (e, 3) deflection systems (9,18,22,48,50) are arranged. 9. Device according to claim 17, d a d u r c h g e k e n n z e i c h n e t that the deflection systems are formed from mirrors (9). 10. Device according to claim 7, d a d u r c h g e k e n n z e i c n e t that the deflection systems consist of prisms (18,22,48,50). 11. Device according to claims 2 and 6, d a -d u r c h g e k It is noted that for the conduction and return of the radiation in the lens (2e3) light-conducting means are provided between the inlet and outlet openings (6,15,21,25,29,31) are. 12. Device according to one of claims 1 to 11, d a d u r c h g It is not noted that optically effective systems are present in the objective (2, 3) which are used to concentrate the radiation in the deflection systems (9,18,22,48,50) or the light-conducting means upstream and / or downstream. 13. Device according to claim 2, d a d u r c h g e k e n n z e i c n e t that the lens (2,3) means influencing the radiation (7,17,23,34,55) contains, which vary the radiation in at least one of their properties. 14. Device according to claim 13, d a d u r c h g e k e n n z e i c h n e t that the means influencing the radiation is a diaphragm (17). 15. Device according to claim 13, d a d u r c h g e k e n n z e i c h n e t that the agent influencing the radiation is a multiple diaphragm (42-44) is trained. 16. Device according to claim 13, d a d u r c h G It is evident that a shaped diaphragm (FIG. 5) influences the radiation Funds. 17. Device according to claim 13, d a d u r c h g e k e n n z e i c h n e t that the means influencing the radiation is designed as a gray filter (33) is. 18. Device according to claim 13, d a d u r c h g e k e n n z e i c h n e t that a pole filter (34) is provided as a radiation-influencing means is. 19. Device according to claim 13, d a d u r c h g e k e n n z e i c h n e t that the means influencing the radiation consists of a color filter. 20. Device according to claim 2, d a d u r c h g e k e n n z e i c n e t that optically effective scalings (55) are provided on the objective (2,3), which vary the radiation in at least one of their properties. 21. Device according to claim 2, d a d u r c h g e k e n n z e i c n e t that at least one photo receiver (10, 37) is mounted in the camera housing (1) is, which the radiation varied in at least one of its properties in converts an electrical signal. 22. Device according to claims 2 and 21, d a -d u r c h g e k It is noted that the photo receiver (10p37,51,52) has an evaluation circuit downstream is. 23. Device according to claim 22, d a d u r c h g e k e n n z e i c h n e t that the evaluation circuit contains a pulse counter. 24. Device according to claim 22, d a d u r c h g e k e n n z e i c h n e t that the evaluation circuit is equipped with a memory.