DE4317221A1 - Component camera (modular camera) for large format and medium format (large size and medium size) - Google Patents

Abstract

With the aid of a suitable component camera for large format and medium format, having an integrated, automatic light-measuring device and a line image converter, various measuring positions (23) can be determined on the basis of the groundglass image (8), which has been set, for the light-measuring device by means of a programming device (2) inside the camera in that an adjustable cross wire (cross hairs, cross lines, reticle) (5) is actuated via a dual twist grip (twist handle) (7). In addition, the groundglass image (focusing screen image, screen picture) (8) is transmitted by the line image converter to a coupled-on flat screen (14) and, by means of the twist grips (19, 20, 21) and an electronic cross wire (6), different measuring positions (22) can likewise be defined for the light-measuring device. <IMAGE>

Description

The invention relates to a camera for large and medium format integrated components, with the help of which it is possible to control the lighting proportions and the color temperature of the focusing screen image exactly to measure in the focused image plane. With the help of an integrated The measuring device can select the measuring positions selected on the focusing screen tions are determined. A suitable light and color measurement arrangement evaluates the predetermined measuring positions. To do this, the lightsens sensors of the light measuring arrangement automatically in the preprogrammed Measuring position placed. A light incidence angle connected in parallel knife sets the angle of incidence of the light rays in the measuring position to correct the measurement result accordingly. In general cause obliquely incident light rays with sensors a measured value adulteration. Different arrangements of automatic light covers gaps close the camera housing by the measured value before the measured value is recorded to prevent falsification by scattered light. Due to the large number of integrated components in the focusing screen frame the active areas of the light and color sensors, the line image converter and the film in the film cassette is not in the focused image area be spatially arranged. Different components are therefore in front of the focused image plane. However, for perfect film exposures and perform precise light measurements in the focused image plane To be able to, the focusing screen frame of the camera leads over suitable Guides and drives perform automatic movements, so the various device configurations as needed in the focused Image plane can be placed. The inserted film cassette will automatically by a pressure plate in the camera or in the focusing screen frame fixed. There is also an integrated cassette jack the possibility to transport the film cassette in the cassette slot. In addition, there is the possibility of the screen image on one Transfer flat screen or LCD projector by one in matt integrated frame image converter the matt screen image scanned in scanner mode. Via an on-screen programming device can also determine the measuring positions of the focusing screen image accordingly, there is again an automatic measurement recording due to the light and color measurement arrangement.  

Various embodiments of large and medium format are known cameras, some with image converter and data transmission a separate screen. Generally the light measurement is made with the help of a probe rod made parallel to the ground glass screen by the probe rod by hand vertical strokes and by a fixed arranged pivot bearing simultaneously perform swivel movements can. With the method mentioned, only an oval surface of the matt is disc image recorded by measurement. A measurement evaluation the color temperature of the screen image is not known.

Methods for transferring the screen image to a screen are known and are accomplished in that instead of An image converter plate is attached to the focusing screen frame becomes. The supposed screen image can be viewed on the screen to be viewed as. Device versions are also known in which Technical information parallel to the focusing screen in the camera in the form of graphical representations on a separate screen being represented.

The known methods of recording measured values, displaying images and However, the graphical display on the screen are significant Disadvantages. Exact placement of the probe rod the selected pixel of the focusing screen image is designed in practice as difficult, since often only after several attempts the goal is achieved. To avoid stray light when taking measured values a slide must be avoided beforehand for each individual measurement be inserted into the cassette frame. Furthermore, bean stood that the probe rod was not placed exactly in the image area can be due to the height of the probe rod. In addition a safety distance to the focusing screen must be maintained so that no damage occurs on the surface of the focusing screen. The parallel The measuring probe offset from the image area accordingly measures a larger one Amount of light available to the film layer during exposure.

Slanting light rays such as z. B. of wide-angle lenses cause incorrect measurement results because the probes stab measurement method offers no possibility of the directional characteristic of the light sensor used. This disadvantage  is particularly serious when using large film formats. Another The disadvantage of the probe rod measuring method is that the mechanical Guidance of the probe rod allows only a limited radius of action. It follows that the probe rod has only a limited oval area of the Screen image can capture metrologically. Smaller film formats cannot be measured using the probe rod measuring method become.

The use of image converters in the known version is prevented the use of a focusing screen, so that the viewer thinks of the union screen image with the resolution of the screen must be satisfied. As a rule, this means a significant amount Loss of detail of the focusing screen image. A graphic representation various recording data on the screen without on glare of the ground glass screen take away the possibility of the viewer to link the data directly with the recording situation.

The object of the invention is to propose a camera, with the help of which it is possible to determine the important ones on the screen Define pixels with a suitable programming device and then all of them automatically by a suitable light measuring arrangement Measure pixels together but individually. In addition, should it may be possible to refer to the specified pixels as needed the color temperature. The light measuring arrangement must be such be conceived so that there is no film format restriction further demands that even the edges and corners of the whole Screen image can be easily measured by measurement. A suitable light incidence protractor should be in the respective measuring position determine the angle of incidence of the light rays so that the light meter result according to the directional characteristic of the light sensor used can be corrected. This is to ensure that even at Use of extreme wide-angle lenses and large format films no incorrect measurements can occur. Furthermore, it is necessary to that before starting the light measurement, the camera with appropriate light covers are automatically sealed light-tight to prevent that stray light falsifies the measurement result and the time-consuming There is no need to insert sliders.  

The camera must be technically designed so that the active Areas of the light sensors placed exactly in the focused image area can be independent of the height of the sensors. The film cassette should be fixed automatically in the camera without pressing Clamp levers u. Like. A transport device could the film cassette in the cassette shaft. There is also the requirement the focusing screen image of the camera on a suitable screen transfer without covering the ground glass. Alternatively to It would be desirable to display the screen on a screen to project a reflection wall to enlarge it at the same time to achieve the screen image. At the same time, the measuring positions of the light measuring arrangement over the projected screen image can be determined. An extension of the task would consist of the image data of the optoelectronically registered Subsequently design screen image so that a suitable Printers out the focusing screen image in approximately the same image quality prints as if the starting position of the image were e.g. B. a slide template been the path from reproduction to general printing driving through.

This object is achieved in that before the matt an adjustable crosshair is arranged with its Help any coordinate point within the focusing screen can be adjusted using a rotary handle. A suitable position The arrangement registers the local position of the Crosshair bars. The saved positions of the crosshairs serve for controlling the sensors of the light measuring arrangements. Suitable elect romechanical drives place the sensors on the different ones Measuring positions that were set with the help of the crosshairs. The Sensors are suitable, the lighting conditions as well as the color temperature to determine the temperatures of the measuring positions. At the color temperature The entire screen image with the corresponding filter colors alternately applied, so that an electronic Matching between the different colors is made possible. In addition is at the same coordinate point for every light and color measurement the angle of incidence of the incident light rays with the help a suitable, optoelectronic light incidence protractor regi  striert so that the measurement result according to the directional characteristic of the sensor can be corrected. Before taking the measured value The light measuring assemblies will place the camera on the outside of the matt pane and the cassette shaft are lightproof with suitable roller blinds closed to keep stray light away. A suitable line picture converter rasterizes the entire focusing screen in the focused Image plane and stores the image data in an electronic data save. The focusing screen frame of the camera can linear motion Carry out runs with the help of suitable drives and mechanical Guides so that it is ensured that the active surfaces of the optoelectronic sensors of the various device arrangements for Measured value recording are always placed in the focused image plane. The content of this data storage can be displayed on one screen are transmitted or the image data are supplied to an image projector leads. In this way, the screen image on the screen or greatly enlarged, shown on a suitable reflection wall become. With the help of suitable programming devices, the measuring positions can the light sensors on the screen or on the projection image be determined. A separately functioning electronic module sets the image data of the data storage in printable reconstructable Image data around. A printer issues this image data in the form of a printed image available for evaluation.

The advantages that can be achieved with the invention are that the Operation of the camera is significantly simplified and at the same time thanks to the assessment of the image composition easier to handle the enlarged view of the screen image. Is special to emphasize that the focusing screen image technically precise lighting can be assessed with respect to the prevailing light and colors conditions through the versatility of the light measuring arrangements. A Another great advantage is the programming of the measuring positions especially since there are no restrictions on the film format size. Instead of of the probe dipstick are all lighting settings accomplished a conveniently operated twist grip. The annoying There is no need to insert sliders before each light measurement active light covers.

An embodiment of the invention is described below with reference to Drawings explained. In detail shows

Fig. 1 shows a schematic structure of a camera arrangement with integrated mech. Programming device and coupled flat screen, shown in the front view,

Fig. 2 shows a schematic construction of a mechanically adjustable reticle, illustrated in plan view,

Fig. 3 shows a schematic structure of the camera wherein the axial movement performed with axially adjustable Barem focusing screen frame by means of a guide prism shown in the side view,

Fig. 4 shows a schematic structure of the camera with axially adjustable Barem focusing screen frame in which the axial movement by means of a guide carriage is carried out, shown in the plan view,

Figure shows a schematic structure of the camera wherein the axial movement performed with axially adjustable Barem focusing screen frame using the image standard. 5, shown in the side view,

Figure 6 shows a schematic structure of a ground glass cover Lichtab., Shown in plan view,

Fig. 7 is an axial movement of the focusing screen frame with the positioning of the film and active light sensing area in the focal plane of the focusing screen of the image shown in the side view,

Fig. 8 shows a schematic structure of a light-incident-angle diameter, shown in side view,

Fig. 9 shows a schematic structure of a light-incident-angle diameter, shown in plan view,

Fig. 10 shows a schematic structure of the grid array surface light-sensitive elements of the light incident-angle diameter, shown in plan view,

Fig. 11 shows a schematic structure of the annularly arranged light-sensitive elements of the light incidence surface protractor, shown in plan view,

Fig. 12 shows a schematic structure of an inte grated in the lens frame filtering apparatus shown in the plan view,

Fig. 13 shows a schematic configuration of a filter band, shown in plan view,

Fig. 14 shows a schematic structure of a pressure plates-drive, shown in the front view,

Fig. 15 shows a schematic structure of a pressure plates-drive, shown in the plan view,

Fig. 16 shows a schematic structure of a film holder, shown in section in plan view,

Fig. 17 shows a schematic structure of a cassette lifter, shown by way presents in side view,

Fig. 18 shows a schematic configuration of the light sensors, light incident protractor and line image sensor in a common frame, shown in the front view

Fig. 19 is a schematic arrangement of various devices and their relationship to one another, partly shown in the front view or perspective,

Fig. 20 shows a schematic arrangement of a flat screen optionally be equipped with a mechanical or electronic programming device, shown in the front view,

Fig. 21 shows a schematic arrangement of a sheet having a symbolic representation of a Folienauswertegerätes, shown in the plan view.

Fig. 1 shows a schematic structure of a camera arrangement with an integrated, mechanical programming device and a coupled flat screen, shown in the front view. In this exemplary embodiment, a programming device ( 2 ) in the form of a mechanically adjustable crosshair ( 5 ) was installed in the focusing screen frame ( 1 ). The bars ( 28 ) of the cross hairs ( 5 ) can be moved in the entire area of the focusing screen ( 8 ) using a double rotary handle ( 7 ). The crossing point ( 9 ) of the bars ( 28 ) embodies the measuring position ( 23 ) of the light and color measuring device. Using the crosshairs ( 5 ), all measuring positions ( 23 ) of the focusing screen image ( 8 ) can be determined in advance. A rail ( 10 ) was placed on each of two outer sides of the focusing screen frame ( 1 ) so that the focusing screen image ( 8 ) can be adjusted in the longitudinal or landscape format. For this purpose, the focusing screen frame ( 1 ) is rotated by 90 degrees and placed again in the guide groove ( 11 ) of the turntable ( 12 ). So that the ease of use of the programming device ( 2 ) is maintained, the double rotary handle ( 7 ) can be repositioned on a matt disc frame ( 1 ) using a suitable coupling ( 13 ). In order to achieve that the mat can be laterally correct and upright standing judged target image (8) without the use of optical aids, the mat appears target image (8) on a flat screen (14). In the illustrated embodiment, the flat screen ( 14 ) is attached directly to the standard image ( 15 ) with the aid of a suitable plug-in base ( 16 ) and a rotary socket ( 17 ). The plug base ( 16 ) and the rotary socket ( 17 ) have electrical contacts ( 18 ) so that the flat screen ( 14 ) is not only mechanically anchored but at the same time electrical contacting takes place. The combination plug-in base ( 16 ) and rotary socket ( 17 ) is designed such that the flat screen ( 14 ) is held by snapping into the rotary socket ( 17 ). In addition, the flat screen ( 14 ) can be pivoted in the rotary mount ( 17 ). Two plug bases ( 16 ) arranged offset by 90 degrees allow the user to use the flat screen ( 14 ) both in landscape and in longitudinal format without any problems. In addition, the flat screen ( 14 ) has an electronic or mech. Crosshair ( 5 , 6 ). This specifies the possibility of determining the measuring positions ( 22 ) of the light and color measuring device via the flat screen ( 14 ). The crosshairs ( 5 , 6 ) are operated with the help of the rotary handles ( 19 , 20 , 21 ). On the flat screen ( 14 ) both the measuring positions ( 22 ) appear which have been determined inside the screen and the measuring positions ( 23 ) which have been determined within the screen.

Fig. 2 shows a schematic structure of a mechanically adjustable crosshair, shown in plan view. The programming device ( 2 ) shown in Fig. 2 was designed in this embodiment in the form of a mechanical crosshair ( 5 ). Two parallel threaded spindles ( 25 ) with threaded nuts ( 26 ) run synchronously with the help of a suitable combination of different drive elements and their placement. A thin rope ( 27 ) connects two opposing threaded nuts ( 26 ) to each other. A pair of threaded spindles ( 25 ) was offset by 90 degrees from the other pair so that the bars ( 27 , 28 ) of the cross hairs ( 5 ) can be adjusted in the axes xy. The threaded spindles ( 25 ) are driven using a double rotary handle ( 7 ). Using a suitable coupling ( 13 ), the double twist grip ( 7 ) can be attached to the focusing screen frame ( 1 ) if necessary offset by 90 degrees. When the bars ( 28 ) stand still, the respective positions ( 115 , 116 ) of the threaded nuts ( 26 ) are stored by a suitable electrical Registrieran arrangement ( 29 ) z. B. with the help of a magnetic wire. In Fig. 2 the registration arrangement has only been shown in the x-axis.

Fig. 3 shows a schematic structure of the camera with axially adjustable focusing screen frame wherein the axial movement is carried out with the aid of a guide prism, shown in the side view. In this exemplary embodiment shown, the image Stan dart ( 15 ) was attached to a guide prism ( 30 ), the guide prism is guided over a fixed guide bed ( 31 ). With the help of a suitable drive, the guide prism ( 30 ) in the guide bed ( 31 ) can be moved axially if necessary, so it is possible to place the matt disc frame ( 1 ) in the different positions, ie the sensors located in the matt disc frame ( 1 ) can be focused Image plane can be positioned. Furthermore, the guide bed ( 31 ) on the guide base ( 32 ) was arranged so that the picture standard ( 15 ) together with the focusing screen frame ( 1 ) on the profile rail ( 33 ) can be moved. After focusing the focusing screen image, the guide base ( 32 ) is locked on the profile rail ( 33 ) using the locking handle ( 34 ) and the focusing screen frame ( 1 ) can be moved axially over the guide bed ( 31 ) without the guide base ( 32 ) again to have to solve. The film evaluation device ( 111 ) was placed on the top surface of the lens standard ( 120 ).

Fig. 4 shows a schematic structure of the camera with axially adjustable focusing screen frame, wherein the axial movement is carried out with the aid of a guide carriage, shown in plan view. The focusing screen frame ( 1 ) is fastened in the guide groove ( 11 ) of a correspondingly designed guide carriage ( 35 ) with the aid of the rail ( 10 ). A suitable drive moves the carriage (35) in the guide bed (36) wherein the guide bed (36) was attached to the hub (12). The fixed bearing ( 37 ) of the turntable ( 12 ) was arranged on the image standard ( 15 ). As already shown in Fig. 3, the axial displacement of the focusing screen frame ( 1 ) also serves in this embodiment of the different, automatic placement of the sensors in the focused image plane.

Fig. 5 shows a schematic structure of the camera with axially adjustable focusing screen frame in which the axial movement by means of the standard image is performed, shown in the side view. The image standard ( 15 ) is moved with the help of the handwheel ( 38 ) on the guide base ( 32 ) on the profile rail ( 33 ) until the focusing screen image is focused. If necessary, the guide base ( 32 ) can be moved automatically on the profile rail ( 33 ) by means of a suitable drive, and there is therefore the possibility of placing the focusing screen frame ( 1 ) at various points, as described in FIGS . 3 and 4.

Fig. 6 shows a schematic structure of a matt-Lichtab cover, shown in plan view. The focusing screen ( 39 ) is automatically covered by a suitable light cover ( 40 ) if necessary in a light-tight manner by unwinding a roller blind ( 41 ) parallel to the focusing screen ( 39 ). The light cover ( 40 ) is placed on the back of the focusing screen ( 39 ) so that the overall length ( 42 ) of the focusing screen frame ( 1 ) can be made as short as possible.

Fig. 7 shows an axial movement of the focusing screen frame with the positioning of the film and active light sensor surface in the focal plane of the focusing screen image, shown in the side view. The upper drawing shows the focusing screen ( 39 ) after focusing the focusing screen image. The cassette slot ( 49 ) arranged in the focusing screen frame ( 1 ) and the light and color measuring device ( 44 ) are at this time in front of the focusing screen ( 39 ) or the focal plane ( 45 ). The middle drawing shows an axial movement of the focusing screen frame ( 1 ) by placing the film ( 46 ) in the film cassette ( 44 ) in the focal plane ( 45 ). The lower drawing shows the axial displacement of the focusing screen frame ( 1 ) by placing the active surface ( 48 ) of the light sensor ( 49 ) of the light and color measuring device ( 44 ) in the focal plane ( 45 ).

Fig. 8 shows a schematic structure of a light incidence angle, shown in section in the side view. The light beam bundle ( 50 ) falls at a certain angle on the pinhole ( 51 ) and parts of it penetrate the pinhole opening ( 52 ) and meet the underlying light-sensitive surface elements ( 53 ) or rings ( 54 ). The extreme distance ( 55 ) of the exposed surface elements ( 56 ) to the center axis ( 57 ) determines the size of the light incidence angle ( 58 ). A suitable optical lens can also be installed in the pinhole aperture ( 52 ) in order to increase the light scatter at the lens exit, thereby achieving a higher resolution.

Fig. 9 shows a schematic structure of a light incidence angle, shown in plan view. The pinhole ( 51 ) closes the light-sensitive surface elements light-tight on all outer sides. The pinhole opening ( 52 ) is located in the center of the pinhole ( 51 ). A suitable optical lens can optionally also be installed in the aperture ( 52 ).

Fig. 10 shows a schematic structure of the grid-like arranged light-sensitive surface elements of the light incidence protractor, shown in plan view. The light-sensitive surface elements ( 53 ) are arranged on a suitable base ( 59 ) in a grid-like manner and centrally to the center axis ( 57 ). With the help of a suitable electrical circuit, the individual surface elements ( 53 ) can be interconnected to form central rings, which considerably reduces the number of electrical supply lines.

Fig. 11 shows a schematic structure of the annularly arranged light-sensitive surface elements of the light incident-angle diameter, shown in the plan view. The centrally arranged rings ( 54 ) consist of a suitable light-sensitive substance. Each ring ( 54 ) emits an electrical signal when exposed.

Fig. 12 shows a schematic structure of a filter device integrated in the lens frame, shown in plan view. The filter device ( 60 ) consists of two driven rollers ( 61 ) which wind around a suitable filter belt ( 62 ). The roller drive was not shown in the drawing. The filter device ( 60 ) is arranged parallel to the lens frame ( 117 ) on the inside. With the help of the rotary movements of the rollers, different filter sections or filter cutouts ( 64 ) can be placed in the objective area ( 65 ). If there is a filter tape cutout ( 64 ) in the lens area ( 65 ), then there is no coloring of the screen image.

Fig. 13 shows a schematic structure of a filter belt, shown in plan view. The filter band ( 62 ) consists of several different colored filter sections ( 63 ) and filter band cutouts ( 64 ). The positioning of the cutouts ( 64 ) in front of the lens does not cause the focusing screen image to be colored.

Fig. 14 shows a schematic structure of a pressure plate drive, shown in the front view. The tension nuts ( 66 ) are driven by suitable pinions ( 67 ) and spindles ( 68 ) by an electric motor ( 69 ). The pressure plate was not shown in the drawing.

Fig. 15 shows a schematic structure of a pressure plate drive, shown in plan view. A tension nut (66) with an appropriate external gearing (70) and with an internal thread (71) is passed over a threaded stud (72) with the threaded studs (72) is attached to the support frame (73). The pinion ( 67 ) rotates the tension nut ( 66 ). The pull nut ( 66 ) moves in the axial direction via the internal thread ( 71 ). A suitable pressure plate ( 76 ) is also moved by the tension nut ( 66 ) via the pivot bearing ( 74 ) and thereby presses the film cassette ( 47 ) against the support frame ( 73 ). Spring elements ( 75 ) compensate for any unevenness between the film cassette ( 47 ) and the pressure plate ( 76 ). The pressure plate ( 76 ) was designed such that a cassette guide ( 77 ) is available at the same time.

Fig. 16 shows a schematic structure of a film holder, shown in section in plan view. A pre-punched film ( 78 ) is fixed over several guide pins ( 79 ) on the back of the matt disc ( 39 ) and pressed flat with the help of a frame ( 80 ). The buffer layer ( 82 ) compensates for unevenness between the frame ( 80 ) and the support ( 81 ). The frame ( 80 ) is fixed with the aid of a suitable locking device on the guide pins ( 79 ) of the film holder ( 119 ).

Fig. 17 shows a schematic structure of a cassette lifter, shown in side view. Driven spur gears ( 83 ) or friction wheels ( 84 ) convey the film cassette ( 47 ) on the narrow side wall into the cassette shaft ( 43 ) or in the opposite direction. The film cassette ( 47 ) has a suitable guide groove ( 85 ) on the side faces. The cassette lifter ( 118 ) is detachably attached to the cassette frame ( 1 ).

Fig. 18 shows a schematic structure of the light sensors, light incidence protractor and line image converter in a common frame, shown in the front view. A frame ( 88 ) is driven on two sides by two synchronously running threaded spindles ( 86 ) via an electric motor ( 87 ) and thereby executes movements parallel to the screen image in the y-axis. A suitable line image converter ( 89 ) was arranged in the area of the frame ( 88 ) at the top. The light sensor ( 90 ) and the light incidence protractor ( 91 ) are located in the lower region of the frame ( 88 ), together on a movably arranged guide runner ( 92 ). The guide skid ( 92 ) is moved in the x-axis with the aid of a threaded spindle ( 93 ), a sliding gear ( 94 ) and an electric motor ( 95 ).

Fig. 19 shows a schematic arrangement of various devices and their relationship to one another, partly shown in the front view or perspective. The screen image ( 8 ) is transmitted via the data line ( 96 ) to the LCD projector ( 97 ) and projected through the optics ( 98 ) onto a suitable reflection wall ( 99 ). In the upper part of the projection image ( 100 ) there is a data display field ( 101 ) for displaying various data such as. B. the exposure time, aperture values u. The crosshairs ( 2 , 5 ) of the focusing screen frame ( 1 ) are also smoothly faded in in the projection image ( 100 ), and the measuring positions ( 23 ) which have been set with the help of the focusing screen frame internal crosshairs ( 2 , 5 ) via the double rotary handle ( 7 ) . It is also possible to determine the measurement positions ( 24 ) via the projection image ( 100 ) and to display them in the projection image ( 100 ). For this purpose, a data line ( 114 ) connects the LCD projector ( 97 ) to a suitable control device ( 102 ). With the help of several rotary handles ( 19 , 20 , 21 ), an electronic crosshair ( 6 ) is moved within the projection image ( 100 ). The crossing point ( 9 ) of the bars ( 28 ) represents the measuring position ( 24 ) for the light and color measuring device ( 44 ) in the focusing screen frame ( 1 ). Furthermore, using the crosshairs ( 6 ) and the inserted vertical and horizontal calibration distances ( 103 , 104 ) the paths of the crosshairs ( 6 ) are calibrated by placing the bar ( 28 ) on the O mark of the calibration path ( 103 , 104 ). Then press the calibration button ( 105 ) and with the rotary handle ( 19 , 20 ) the bar ( 28 ) is guided to the 1 mark of the calibration section ( 103 , 104 ). Then the calibration key ( 105 ) must be pressed again. The calibration process must be carried out for both calibration sections ( 103 , 104 ) but only if the magnification scale of the projection image ( 100 ) changes or before the start of a series of recordings. This action ensures that the distances of the projection image ( 100 ) match the distances of the focusing screen image ( 8 ) in an assigned relationship. The two routes are automatically compared. The control unit ( 102 ) also has a display field ( 106 ) so that various data can be displayed directly on the control unit ( 106 ).

Fig. 20 shows a schematic arrangement of a flat screen can be optionally equipped with a mechanical or electronic programming device, shown in the front view. In this embodiment example, the programming device ( 3 , 4 ) consists either of a mechanical crosshair ( 5 ) or of an electronic crosshair ( 6 ). The electronic crosshair ( 6 ) can be pivoted by actuating the central rotary handle ( 21 ), both in a group, ie the two bars ( 107 , 108 ) of the crosshair ( 6 ) are perpendicular to each other and individually, ie the bars ( 107 , 108 ) can be separated are pivoted as shown in the drawing by a dashed bar ( 108 ). In the example shown, the task should be to reproduce the displayed rectangle without distortion. For this purpose, the crosshair ( 6 ) is pivoted with the help of the rotary handle ( 21 ) so that the vertical bar ( 107 ) runs parallel to the vertical object line ( 122 ). The left rotary handle ( 19 ) is used to move the bar ( 107 ) on the x-axis, ie the bar ( 107 ) is brought into line with the vertical object line ( 122 ). The angle of rotation ( 121 ) is visually displayed on the screen. The same applies if necessary for the horizontal bar ( 108 ) or for a horizontal object line ( 123 ). The setting is made using the rotary handle ( 20 ) on the right. In an extended version it is provided that the suitable camera positions are carried out automatically after the angle of rotation ( 121 ) has been determined. The operation of the mechanical crosshair ( 5 ) corresponds to that of the electronic crosshair ( 6 ), however the bars ( 28 ) cannot be swiveled.

Fig. 21 shows a schematic arrangement of a sheet having symbol ical illustration of a film evaluation device, shown in the plan view. The film ( 78 ) has several punched-out openings ( 109 ) in front of it which are used to fix the film ( 78 ) in the film holder. With the help of the start marker ( 110 ) in the foil evaluation unit ( 111 ) begins the foil evaluation and at the same time the length markings ( 112 ) are registered, so that the measuring positions marked with a pen ( 113 ) are classified or registered in a coordinate system can be. With the results, the film evaluation device controls the light and color measuring device in the focusing screen frame, ie the measuring positions ( 113 ) of the film are identical to the measuring positions in the image plane of the focusing screen.

Reference list

1 focusing screen frame
2 Programmer focusing screen
3 programming device mech. Flat screen
4 programming device el. Flat screen
5 crosshairs mech.
6 crosshairs el.
7 double rotary handle
8 focusing screen
9 crossing point
10 rails
11 Guide groove turntable
12 turntable
13 clutch
14 flat screen
15 image standards
16 sockets
17 rotary version
18 contacts el.
19 X-axis rotary handle
20 y-axis rotary handle
21 Swivel the rotary handle
22 Measuring position screen
23 Measuring position of the focusing screen
24 Measurement position projection image
25 threaded spindle
26 threaded nut
27 rope
28 bars
29 Registration arrangement el.
30 standard guide prism
31 Standard guide bed
32 standard guide base
33 profile rail
34 locking handle
35 turntable guide slide
36 Guide bed turntable
37 fixed bearings
38 handwheel
39 focusing screen
40 light cover
41 roller blind
42 overall length
43 cassette slot
44 Light and color measuring device
45 focal plane / image plane
46 film
47 film cassette
48 surface active (sensor)
49 sensor
50 light beams
51 pinhole
52 pinhole opening
53 surface element light-sensitive
54 ring light-sensitive
55 distance angle
56 surface element exposed
57 center axis
58 incidence of light
59 document
60 filter device
61 roller
62 filter belt
63 filter section
64 filter tape cutout
65 lens
66 pull nut
67 sprockets
68 spindle
69 electric motor
70 external teeth
71 internal thread
72 stud bolts
73 support frame
74 pivot bearings
75 spring element
76 pressure plate
77 cassette guide
78 slide
79 guide pin
80 frames of foil
81 edition
82 buffer coating
83 spur gear
84 friction wheel
85 Guide groove cassette
86 threaded spindle vertical
87 electric motor
88 frame sensor
89 line image converter
90 light sensor
91 light incidence protractor
92 guide runners
93 threaded spindle horizontal
94 sliding gear
95 electric motor
96 data line
97 LCD projector
98 optics
99 reflection wall / projection surface
100 projection image
101 Data display field
102 programming device / control unit
103 Vertical calibration line
104 calibration line horizontal
105 calibration button
106 Control unit display field
107 vertical bars
108 bars horizontal
109 die cut
110 start marker
111 Foil evaluation device
112 length marking
113 Measuring position foil
114 Data line control unit
115 position x-axis
116 y-axis position
117 lens frame
118 cassette jack
119 foil holder
120 lens standard
121 rotation angle
122 Object line vertical
123 Object line horizontal.

Claims (66)

1. Component camera for large and medium format, characterized in that a suitable focusing screen frame ( 1 ) with inte grated device arrangements ( 2 , 5 , 40 , 43 , 44 , 49 , 76 , 89 , 90 , 91 , 118 , 119 ) and fastening elements ( 10 ) with the help of a suitable linear drive ( 30 , 31 , 32 , 35 , 36 ) freely programmable movements in such a way that the active surfaces ( 48 ) of the optoelectronic sensors ( 49 , 89 , 90 , 91 ) of the various device arrangements ( 44 , 88 , 91 ) and the cassette film ( 46 , 47 ) are each automatically placed in the focused image plane ( 45 ) for the purpose of film exposure or measurement value acquisition, the measurement positions ( 22 , 23 , 24 , 113 ) of the sensors ( 48 , 49 , 90 , 91 ) are determined via suitable, camera-internal or external programming devices ( 2 , 3 , 4 , 102 ), via suitable electromechanical guide drives ( 86 , 87 , 88 , 92 , 93 , 94 , 95 ) of the various device arrangements ( 44 , 88 , 91 ) the sensors ( 44 , 49 , 90 , 91 ) automatically reach the preprogrammed measuring positions ( 22 , 23 , 24 , 113 ), with the help of the sensors ( 48 , 49 , 90 ) the light and color conditions can be adjusted taking into account the light incidence angle ( 58 ) of the individual measuring positions ( 22 , 23 , 24 , 113 ) are determined automatically, the color temperature determination of the measuring positions being carried out in such a way that the entire screen image ( 8 ) is alternately struck with the required filter colors Purposes of electronic comparison of the sensor data, the filter colors are created by an automatic filter device ( 60 ) integrated in the camera, a suitable line image converter ( 88 , 89 ) integrated in the focusing screen frame ( 1 ) rasterizes the focusing screen image ( 8 ) in scanner mode and stores it Image data in a suitable electronic data storage device, the content of the data storage device is expanded by additional camera-internal or External data is expanded and, if required, the entire data storage content or parts thereof can be fed to an internal or external modified flat screen ( 14 ), an LCD projector ( 97 ), a repro compensation module or other device arrangements for various further processing, with parts of the processed data being fed into the camera flow back and serve to control various control functions in the camera ( 1 , 12 , 15 , 120 ). 2. Component camera according to claim 1, characterized in that in the focusing screen frame ( 1 ) integrated device arrangements of a light and color measuring device ( 44 , 49 , 90 ), an electronic light incidence protractor ( 91 ), a line image converter ( 89 ), a programming device ( 2 ), a cassette shaft ( 43 ) with a driven pressure plate ( 66 , 67 , 68 , 69 , 72 , 76 ), a cassette lifter ( 118 ), various automatic light covers ( 40 ) and a film holder ( 119 ). 3. Component camera according to claim 1, characterized in that the light incidence angle ( 58 ) of the individual measuring positions ( 22 , 23 , 24 , 113 ) is determined automatically with the aid of an electronic light incidence protractor ( 91 ). 4. Component camera according to claim 3, characterized in that the light incidence protractor ( 91 ) from a thin pinhole ( 51 ) and from several optoelectronic light-sensitive surface elements ( 53 , 54 ), the surface elements being arranged in a grid around a center axis ( 57 ) and when each individual surface element ( 56 ) is exposed, a separate electrical signal is available, the cross-sectional area of the pinhole opening ( 52 ) corresponds to the cross-section of the active area of the light sensor ( 49 , 90 ), optionally the pinhole opening ( 52 ) can also be used be equipped with a suitable optical lens. 5. Component camera according to claim 4, characterized in that the pinhole ( 51 ) is arranged plane-parallel to the light-sensitive surface elements ( 53 , 54 ) at a certain distance and the electrical signals of the exposed surface elements ( 56 ) for determining the angle of incidence ( 58 ) serve by determining the number and the extreme distance ( 55 ) of the exposed surface elements ( 56 ) from the center axis ( 57 ), the pinhole ( 51 ) is placed in the focal plane ( 45 ), the center axis ( 57 ) of the pinhole opening ( 52 ) with the measuring position ( 22 , 23 , 24 , 113 ) of the light sensor ( 44 , 49 , 90 ). 6. Component camera according to claim 4 and 5, characterized in that the light-sensitive surface elements consist of centrally arranged, separately acting rings ( 53 , 54 ). 7. Component camera according to claim 4 and 5, characterized in that the light-sensitive surface elements ( 53 , 54 ) consist of individual, grid-shaped geometric surfaces ( 53 , 54 ) which are interconnected with the aid of a suitable electrical circuit to form centrally arranged ring segments so that it is possible to assign each ring segment ( 53 , 54 ) a certain angle of incidence of light ( 58 ). 8. component camera according to claim 1 and 3, characterized in that parallel to each light measurement by the light and color measuring device ( 44 , 49 , 90 ) in the same measuring position ( 22 , 23 , 24 , 113 ) a light incidence angle measurement ( 58 ) is carried out and the measured angle ( 58 ) is assigned to the respective light measurement value. 9. component camera according to claim 1, 2 and 8, characterized in that a suitable electronic correction circuit corrects the measured light value according to the light incidence angle ( 58 ), the correction factor corresponds to the directional characteristic of the light sensor used ( 44 , 49 , 90 ), thus the exact amount of light that actually strikes the film surface ( 46 ) is determined. 10. Component camera according to claim 1 and 2, characterized in that the integrated in the focusing screen frame ( 1 ) Programming Ge advises ( 2 ) consists of an adjustable crosshair ( 5 ) with the crossing point ( 9 ) of the two bars ( 28 ) the measuring position ( 22nd , 23 , 24 , 113 ) and the crosshair drive via a reversible double rotary handle ( 7 ). 11. Component camera according to claim 10, characterized in that the double rotary handle ( 7 ) via a suitable coupling ( 13 ) is connected to the focusing screen frame ( 1 ). 12. Component camera according to claim 10, characterized in that the crosshair ( 5 ) consists of two synchronously running pairs of threaded spindles ( 25 ) with threaded nuts ( 26 ) arranged offset by 90 degrees, the two spindles of each pair being arranged parallel to one another at a certain distance , A thin rope ( 27 ) connects two opposite, synchronously running threaded nut ( 26 ). 13. Component camera according to claim 10 and 12, characterized in that a suitable electrical registration arrangement ( 29 ) regi positions the positions ( 115 , 116 ) of the threaded nuts ( 26 ) at standstill and forwards the data to a suitable evaluation circuit. 14. Component camera according to claim 1, characterized in that the focusing screen frame ( 1 ) can carry out automatic, freely programmable linear movements by the image standard ( 15 ) is fastened to a driven guide prism ( 30 ) and the guide bed ( 31 ) belonging to the guide prism ( 30 ) ) is connected to the separately acting guide base ( 32 ), furthermore there is a rotatable connection between the cassette frame ( 1 ) and the image standard ( 15 ). 15. Component camera according to claim 1, characterized in that the focusing screen frame ( 1 ) can perform automatic, freely programmable linear movements by the focusing screen frame ( 1 ) is attached to a driven guide carriage ( 35 ) and the guide bed ( 36 ) on the turntable ( 12th ) the image standard ( 15 ) is arranged. 16. Component camera according to claim 1, characterized in that the focusing screen frame ( 1 ) carries out freely programmable movement sequences by the image standard ( 15 ) after focusing the focusing screen image with the aid of the guide base ( 32 ) and the handwheel ( 38 ) on the profile rail ( 33 ) is moved automatically. 17. Component camera according to claim 1 and 2, characterized in that the line image converter ( 86 , 87 , 88 , 89 ) in scanner mode records the focused focusing screen image ( 8 ) in the focus plane ( 45 ) and in any position in the y-axis can be placed using the programming devices ( 2 , 3 , 4 , 102 ). 18. Component camera according to claim 1 and 2, characterized in that the line image converter ( 89 ) is moved automatically via two synchronously running threaded spindles ( 86 ) parallel to the focusing screen image ( 8 ) in the focal plane ( 45 ). 19. Component camera according to claim 2, characterized in that the film cassette ( 47 ) is pressed plane-parallel against the support frame ( 73 ) with the aid of an automatic pressure plate ( 76 ). 20. Component camera according to claim 2 and 19, characterized in that the drive of the pressure plate ( 76 ) via suitable tension nuts ( 66 ) with a suitable external toothing ( 70 ) and with internal thread ( 71 ) and several tension nuts ( 66 ) with the pressure plate ( 76 ) are connected via a rotary bearing ( 74 ). 21. Components camera according to claim 20, characterized in that the tension nuts (66) are guided by means of threaded studs (72), the threaded studs (72) are fastened be (73) on the support frame. 22. Component camera according to claim 20 and 21, characterized in that the tension nuts ( 66 ) are driven by means of suitable pinions ( 67 ), the toothing ( 70 ) being designed such that the pinions ( 67 ) are stationary and the tension nuts ( 66 ) can follow an axial movement according to the thread pitch of the threaded stud bolts ( 72 ). 23. Component camera according to claim 22, characterized in that a suitable central drive ( 68 , 69 ) drives the pinion ( 67 ). 24. Component camera according to claim 2 and 19, characterized in that the pressure plate ( 76 ) in the region of the film cassette support is equipped with individual spring elements ( 75 ). 25. Component camera according to claim 2 and 19, characterized in that the pressure plate ( 76 ) is equipped with a cassette guide ( 77 ). 26. Component camera according to claim 2, characterized in that the focusing screen frame ( 1 ) is equipped with a foil holder ( 119 ) with the aid of which a perforated foil ( 78 ) can be attached to the outside of the focusing screen ( 39 ). 27. Component camera according to claim 2 and 26, characterized in that the film holder ( 119 ) consists of several guide pins ( 79 ) and a snap-in frame ( 80 ). 28. Component camera according to claim 2 and 26, characterized in that the desired measuring positions ( 113 ) are marked with the aid of a suitable pen on the film ( 78 ). 29. Component camera according to claim 26, characterized in that the film ( 78 ) with a start and length marking ( 110 , 112 ) is marked. 30. Component camera according to claim 2, 26 and 29, characterized in that the marked film ( 78 ) is fed to a film evaluation device ( 111 ) and with the evaluation result of the light and color sensor ( 44 , 49 , 90 ) in the corresponding measuring positions ( 113 ) is placed automatically. 31. Component camera according to claim 1 and 30, characterized in that the film evaluation device ( 111 ) is attached to the top surface of the lens standard ( 120 ). 32. Component camera according to claim 2, characterized in that a suitable cassette lifter ( 118 ) on the focusing screen frame ( 1 ) is placed with the help of which the film cassette ( 47 ) in the cassette shaft ( 43 ) can be conveyed automatically. 33. component camera according to claim 2 and 32, characterized in that the cassette lifter ( 118 ) with the help of driven, in pairs opposite spur gears ( 83 ) or friction wheels ( 84 ) the modified film cassette ( 47 ) on the narrow side surface in the guide groove ( 85 ) promoted. 34. Component camera according to claim 1, characterized in that the fastening elements of the focusing screen frame ( 1 ) consist of several rails ( 10 ) and circuit boards. 35. Component camera according to claim 34, characterized in that the focusing screen frame ( 1 ) is equipped on the outside on two side faces offset by 90 degrees, each with a rail ( 10 ). 36. Component camera according to claim 34 and 35, characterized in that the rail ( 10 ) in the guide groove ( 11 ) of the turntable ( 12 ) is mounted and suitable electrical contacts automatically make an electrical connection between the focusing screen frame ( 1 ) and Image standard ( 15 ). 37. Component camera according to claim 35 and 37, characterized in that by the implementation of the focusing screen frame ( 1 ) either longitudinal or landscape format is set. 38. Component camera according to claim 1 and 34, characterized in that suitable boards are attached in the ground glass frame ( 1 ), the boards serving as an assembly support for the various device arrangements ( 2 , 44 , 88 ). 39. Component camera according to claim 1 and 2, characterized in that the light and color measuring device ( 44 , 90 ), the electronic light incidence protractor ( 91 ) and the line image converter ( 89 ) are placed in a common, movable frame ( 88 ) . 40. component camera according to claim 39, characterized in that the line image converter ( 89 ), the light and color measuring device ( 44 , 90 ) and the light incidence protractor ( 91 ) with the help of two parallel, synchronously running threaded spindles ( 86 ) in the y-axis can be moved, another threaded spindle ( 93 ) which is connected to a sliding gear ( 94 ) moves the light and color measuring device ( 44 , 90 ) and the light incidence protractor ( 91 ) additionally in the x-axis. 41. Component camera according to claim 1, characterized in that the filter device ( 60 ) automatically places the required filter ( 62 ) in the beam path of the recording optics. 42. Component camera according to claim 1, characterized in that the filter device ( 60 ) is arranged in the lens frame ( 117 ). 43. Component camera according to claim 1, characterized in that the flat screen ( 14 ) is equipped with an electronic crosshair ( 6 ), the bars ( 28 ) of the crosshair ( 6 ) each connect two opposite sides of the screen. 44. Component camera according to claim 43, characterized in that the bars ( 28 ) of the electronic crosshair ( 6 ) can be moved in the entire screen area. 45. Component camera according to claim 43, characterized in that the bars ( 28 , 107 , 108 ) of the electronic crosshair ( 6 ) can be pivoted together or individually and the angle of rotation ( 121 ) on the flat screen ( 14 ) is optically displayed. 46. Component camera according to claim 1 and 43, characterized in that with the help of the electronic crosshair ( 6 ) the per spective course of the horizontal and vertical object lines ( 122 , 123 ) of the focusing screen image ( 8 ) are corrected by the crosshair ( 6 ) in each case Swiveling in the corresponding xy axis until coverage is possible with the object line ( 122 , 123 ) to be corrected. 47. Component camera according to claim 1, characterized in that the angle of rotation ( 121 ) of the electronic crosshair ( 6 ) serves to the standards ( 15 , 120 ), the focusing screen frame ( 1 ) or the lens frame ( 117 ) automatically in the corrected position swing. 48. Component camera according to claim 43, 44 and 45, characterized in that the electronic crosshair ( 6 ) is actuated via a plurality of rotary handles ( 19 , 20 , 21 ). 49. Component camera according to claim 1, characterized in that the flat screen ( 14 ) is equipped with a mechanical crosshair ( 5 ). 50. Component camera according to claim 1, 43 and 49, characterized in that the light and color measuring device ( 44 , 49 , 90 ) can be programmed using the crosshairs ( 5 , 6 ) ie the measuring positions ( 22 ) on the flat screen ( 14 ) can be determined. 51. component camera according to claim 1 and 27, characterized in that the flat screen ( 14 ) is equipped with a film holder ( 119 ). 52. Component camera according to claim 1, characterized in that the flat screen ( 14 ) via a suitable plug-in base ( 16 ) can be placed either on the image standard ( 15 ) or at another location. 53. Component camera according to claim 52, characterized in that the flat screen ( 14 ) is equipped on two sides offset by 90 degrees, each with a plug-in base ( 16 ). 54. Component camera according to claim 52, characterized in that the flat screen ( 14 ) on the socket ( 16 ) in the rotary socket ( 17 ) is pivotally mounted. 55. Component camera according to claim 52, characterized in that the plug-in base ( 16 ) engages in the rotary mount ( 17 ) and, as a result, the flat screen ( 14 ) is anchored in the rotary mount ( 17 ). 56. Component camera according to claim 52 and 53, characterized in that the plug-in base ( 16 ) and the rotary socket ( 17 ) are equipped with suitable electrical contacts ( 18 ) so that the flat screen ( 14 ) is automatically electrically contacted. 57. Component camera according to claim 1 and 2, characterized in that the positions ( 115 , 116 ) of the various crosshairs ( 5 , 6 ) and the specified measuring positions ( 23 , 24 ) of the external programming devices ( 2 , 102 ) on the flat screen ( 14 ) can be shown fluently. 58. Component camera according to claim 1, characterized in that with the aid of the repro compensation module, the image data of the line image converter ( 89 ) are corrected in such a way that a suitable printer reproduces the matt image ( 8 ) in print quality which reproduces an equivalent film template in general printing processes corresponds. 59. Component camera according to claim 1, characterized in that the repro compensation module at a suitable location in the Camera is placed. 60. Component camera according to claim 1 and 58, characterized records that the image data regarding contrast range, color rendering and image content for the various printing processes by appropriate, programmable corrections can be adjusted. 61. Component camera according to claim 1, characterized in that with the aid of an LCD projector ( 97 ) the focusing screen image ( 8 ) is displayed on a suitable projection surface ( 99 ). 62. Component camera according to claim 1 and 61, characterized in that the LCD projector ( 97 ) is operated via a suitable control device ( 102 ), with the help of the control device ( 102 ) an electronic, rotatable and adjustable crosshair ( 6 ) in parallel can be faded in to the projected focusing screen image ( 8 , 100 ). 63. Component camera according to claim 1 and 62, characterized in that the measuring positions ( 24 ) of the light and color measuring device ( 44 , 49 , 90 , 91 ) can be determined with the aid of the electronic crosshair ( 6 ). 64. Component camera according to claim 1, 61 and 62, characterized in that with the aid of the control device ( 102 ) on the projected screen image ( 8 , 100 ) each have a vertical and horizontal calibration path ( 103 , 104 ) so that with the help of electronic crosshairs ( 6 ) the calibration path can be traversed, the distance covered ( 103 , 104 ) is registered in the control unit ( 102 ) and compared with a camera-specific unit of length. 65. Component camera according to claim 1 and 64, characterized in that the magnification factor between the focusing screen image ( 8 ) and the projected focusing screen image ( 8 , 100 ) is determined by the comparison between the calibration distance ( 103 , 104 ) and the camera-specific length unit so that the larger aspect ratios of the projection image ( 100 ) can be transferred to the focusing screen image ( 8 ) in the correct ratio. 66. Component camera according to claim 1 and 63, characterized in that the flat screen ( 14 ) and the LCD projector ( 97 ) are additionally operated via suitable control devices so that further information in the form of symbols in the matte screen images ( 14 , 100 ) shown , Reference lines, markings u. Like. Can be faded in, if necessary, the fade-in must be identical to the position of the focusing screen ( 8 ) of the camera.