DE2552589A1 - DEVICE FOR AUTOMATIC EXPOSURE CONTROL IN MICROFILM CURRENT CAMERAS - Google Patents

Description

AGFA-GEVAERT AKTIENGESELLSCHAFT November 21

Leverkusen (λ 10-re-zi

PG 848 / MG 1131

Device for automatic exposure control in microfilm cameras

The invention relates to a device for automatic exposure control in microfilm cameras with a measuring station for measuring the reflectance value of the original to be filmed, with one in the transport direction As seen from the original behind the measuring station, the lighting station for the on a recording medium is arranged original to be scanned, and with means for controlling the amount of light incident on the recording medium by means of a control signal obtained from the reflectance measurement.

In a known device of this type according to DT-OS 1 2l4 52k , the template entering the microfilra continuous device is illuminated by means of a lamp of constant brightness and the light reflected from the template is measured by means of a photoelectric device of a known type, for example a photocell. That depends on the original brightness

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The photocell's varying output signal then controls a phase inclination control which reverses the brightness of the illumination lamps of the exposure station proportional to the output signal of the photocell. The different properties of the original are thus compensated for by changing the brightness of the lighting lamps.

The performance of such a throughput device is due to the relatively low control speed of yours Control loop limited. The phase control needs about 20 ms to adjust, plus the inertia of the lighting lamps, which only reach the set brightness after approx. 150 to 250 ms. From this it follows a relatively small maximum permissible throughput speed for the originals or a relatively large minimum required distance between two consecutive copies.

Another disadvantage of the brightness of the lighting

The flow camera regulating lamps is different in that the color temperature of the lighting lamps is different Brightness, which has a particularly unfavorable effect on the color film of the originals.

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The invention is therefore based on the object of an improved Device according to the preamble of the main claim to create, which has an increased control speed for the control circuit, for the color film suitable as well as reliable and cost-saving.

According to the invention, these objects are achieved by that the following devices are provided for exposure control:

a) a constant brightness lighting system for the exposure station,

b) an aperture system with a variable aperture for the Exposure station,

c) a device for generating one of the for the exposure beam path relevant aperture analog control signal,

d) a multiplier for multiplying the control signal obtained from the reflectance measurement with that of the Aperture opening analog control signal,

e) a device for comparing the resulting product with a predetermined, desired exposure of the Recording medium corresponding value as well as for generating a corresponding difference signal,

f) and a device for controlling the aperture by means of this difference signal.

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The amount of light Q incident on the recording medium should have a specific, constant value Q for optimal exposure of the recording medium. The amount of light Q depends on the reflectance value 2 ** he original as well as on the aperture b and is proportional to both, i.e. Q- ^ b · j. Since the amount of light is supposed to be constant, the product b «_J must also be constant. With increasing remission of the original, the diaphragm opening must be reduced to such an extent that the product of the diaphragm opening times the reflectance value remains constant.

The product formation b · / is addressed in the above Multiplier completed. In the differential amplifier connected downstream of this device, as a comparison value a nominal value corresponding to the optimal amount of light Q can be entered, with which the respective product £ «b is compared will. A difference signal is now generated from the difference between the setpoint and actual value Power amplification is used to readjust the aperture.

Advantageously, according to further features of the invention, there are means for storing the information obtained from the reflectance measurement Control signal provided, as well as means for input

-5-

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write this control signal into the memory, which is activated once for each original. This is a photoelectric barrier which can be actuated by the templates is preferably provided in the conveying path of the templates initiates the writing of the control signal in the memory.

The fact that the control signal is only stored once per original means that an original can be scanned a time-constant control signal is available, so that it is ensured that the aperture value during the filming of an original does not change constantly, depending on the original brightness, and thus the undesired banding is suppressed on the film. There continues to be the control signal obtained from the remission measurement of a specific original is still available until the reflectance value of the following template is saved and the aperture just as long as it is not changed, the aperture only changes from publisher to template, based on the previous value, readjusted and not, as is usual with other known devices with aperture control, of a certain, constant initial value adjusted with each submission. This is a particularly power-saving and fast control device created.

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According to the invention, a diaphragm which can be actuated by means of a rotary magnet is used as a diaphragm for the exposure device Rotary screen provided, which should be mounted with as little friction and inertia as possible and according to the principle a moving coil measuring instrument is pivoted.

To measure the aperture relevant to the exposure beam path, a lamp of constant brightness is attached in front of the aperture and a light-sensitive element is arranged behind the aperture, which measures the light passing through the aperture from this lamp and generates an output signal analogous to this amount of light . The lamp should be arranged relative to the diaphragm in such a way that, in every angular position of the rotary diaphragm, the proportion of light passing through the diaphragm from this lamp is proportional to the portion of the exposure beam path passing through the diaphragm.

According to a particularly advantageous feature of the invention is for the measuring station of the reflectance value and for the Exposure station provided a common lighting system. This ensures that the Color temperature of the lighting system dependent reflectance value of the original also actually in the measuring station for the Reflectance value and in the exposure station is the same.

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Furthermore, it is favorable if, according to the invention, in cost-effective and space-saving way for the lighting station, for the measuring station of the remission value and for the measurement the aperture a common lighting system is provided.

Further advantages of the invention emerge from the following description, in which an exemplary embodiment the invention is explained in more detail with reference to the drawing. In this drawing show:

Fig. 1 is a functional diagram of an inventive Device, and

FIG. 2 shows the electrical circuit diagram of a device according to FIG. 1.

In FIG. 1, 1 denotes the transport path for templates 2. A light source 3 supplied with constant direct voltage provides for the illumination of the original at k for reflectance measurement and for the illumination of the original at 5 in the exposure station. Between the exposure station 5 vend a camera unit 6, a rotary plate 7 is provided which can be pivoted by means of a rotary magnet 8, so vm the exposure control of the recording material.

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Part of the light from the light source 3 passes directly through the aperture of the rotary aperture 7 and is in the station registered photoelectrically. This portion that goes directly through the diaphragm is at a certain angular position the rotary diaphragm b-0_, where 0_ is the maximum through the Luminous flux reaching the aperture and b is a measure of represents the effective aperture. With a suitable geometric Arrangement of the lighting system is then the luminous flux 0 of the imaging beam path at a certain Angular position of the rotary shutter weakened by the same factor b as the luminous flux 0-, so that the output signal the registration station 9 of the effective aperture relevant for the imaging beam path is analogous.

In the Vbrlagentransportbahn 1 is in the transport direction seen in front of the exposure station 5 a light barrier is arranged. As soon as the leading edge of the If this light barrier is passed, the light barrier triggers a monostable flip-flop 11. The short The output pulse of this trigger stage causes the instantaneous remission value measured in the remission enjoyment station 12 to be written into the analog memory 13 will.

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This becomes the remission value in a multiplier 1A analog signal multiplied by the instantaneous effective aperture b analog signal that the Size £ * b analog output signal of the multiplier lA is fed to one input of a differential amplifier 15, the other input of which is an optimal one Exposure of the copy material corresponding target value Q is entered. The current actual value C * b is compared with the Setpoint Q compared. The output signal of the differential amplifier corresponding to the difference between the two values becomes amplified in a power amplifier. That amplified The signal feeds the rotary magnet 8, which is mounted on the axis of rotation of the balanced rotary shutter 8 is attached. As a result, the rotary shutter 8 is adjusted until the product C-b has reached the setpoint. The setting time is about 15 ms.

The angular position of the diaphragm set in this way remains the same retained until the following template passes the light barrier 10 and thus possibly a new reflectance value is written into the memory I3.

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In Figure 2, 10 again denotes the light barrier, consisting of a transmitter 50 and a phototransistor 51) whose emitter is connected to earth and whose collector is connected to +15 volts via a resistor 52. Between the phototransistor 51 and the resistor 52 is a monostable multivibrator 53 connected, the output of which via a Zener diode 54 and a resistor 55 once with the base of a Transistor 56 and also via a resistor 58 with 15 volts is connected. The emitter of this transistor lies to +15 volts, the collector via a resistor 57 on -30 volts. The collector of transistor 56 is across a Conductor piece 59 connected to the gate of a field effect transformer 6l with the interposition of a diode 60.

A photo element 62 is connected to the inverting input of an operational amplifier 63, the non-inverting input of which is connected to ground. The output of the operational amplifier 63 is connected to the inverting input via a resistor 6k. Furthermore, a potentiometer 65 is connected to the operational amplifier 63. The non-inverting input of a further operational amplifier 66, likewise provided with a potentiometer, is connected to the output of the operational amplifier 63. The output of the operational amplifier 66 is connected to the source electrode of the field effect transformer 6l via a resistor 167.

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The source and gate of this field effect transistor are connected to one another with a resistor 68 interposed. The drain electrode of the field effect transistor 6l leads to the gate of a further field effect transistor 69, whose drain is at +15 volts and whose source is at -15 volts with the interposition of a resistor 70. A Storage capacitor 71 has one connection to ground and with its other connection between the drain of the field effect transistor 6l and the gate of the field effect transistor 69. Source of field effect transistor 69 is through to the inverting input of operational amplifier 66 a conductor piece 72 connected.

Source -from field effect transistor 69 is connected via a resistor to the inverting input of a "] h operational amplifier. And via a resistor 75 to its output. The inverting input of this operational amplifier 74 is grounded via a resistor 76. The non-inverting input of this operational amplifier is connected through a resistance

77 in mass. A potentiometer 79 is across a resistor

78 also with the non-inverting input of the operational amplifier 74 connected.

A photo element 80 is connected to the inverting input of an operational amplifier 8l, whose non-inverting input

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connected to ground. The output of this operational amplifier is fed back with its inverting input with the interposition of a resistor 82. A potentiometer 83 is connected to two further inputs of the operational amplifier 8l; the output of the operational amplifier 8l is connected to the operational amplifier 74 via a conductor piece 84 with the interposition of a resistor 85 and a potentiometer.

The output of the operational amplifier 74 is via a Resistor 88 with "a potentiometer 89 as well as a Another conductor piece connected to the inverting input of an operational amplifier 87. The outcome of this Operational amplifier is using a resistor 90 fed back to the inverting input, the non-inverting input is connected to ground. Two more entrances of the operational amplifier 87 are connected to a potentiometer 91. The output of the operational amplifier 87 leads via a resistor 92 to the inverting input of a further operational amplifier 93 · the non-inverting The input of this operational amplifier is connected to ground via a resistor 94. In parallel with this resistor 94 are in A potentiometer 95 and a resistor 96 are connected in series. The output and the inverting input of the operational amplifier 93 are connected by a resistor 97.

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The output of the operational amplifier 93 leads to a power stage in which two transistors 99, 100 or 101, 102 are arranged in a Darlington circuit. One end of a resistor 104t is connected to +15 volts, the other end leads via the diodes 105 to 1θδ and via a resistor 109 to -15 volts. The collector of the transistor 100 or 102 is connected to the plus or minus pole of the voltage source. The base of the transistor 99 or 101 is connected to the conductor piece 103 connecting the two resistors 10 4 and 109 between resistor 10 k and diode 105 or between diode and resistor 109. The output of the operational amplifier 93 leads via resistor 98 to the conductor piece 103 between diode I06 and diode 107. A capacitor 111 connects the conductor piece between the diodes I06 and 107 to the two emitters of the transistors 100 and 102. A conductor piece 110 connects these two emitters to the Rotary solenoid coil 8.

The mode of operation of this circuit is now as follows:

The output of the monostable multivibrator 53 is normally on the Η signal (approx. 14.5 volts). This blocks the Reversing transistor 56, so that about -30 volts at its collector issue. The gate of the field effect transistor becomes via the diode 60 6l controlled, whereby this also locks. the

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voltage stored on the storage capacitor, which corresponds to the Remis si onsvrert corresponds to the original to be filmed is available at the source of the field effect transistor 69 .

If the leading edge of the following original runs into the light barrier 10, the phototransistor 51 is darkened and blocked. The collector voltage rises to +15 volts, as a result of which the monostable multivibrator 53 emits a negative pulse (approx. +0.5 volts) of approx. 0.8 ms duration at its output. During this time, the transistor 56 is durdigesterert so that the potential at its collector _{rises from -30 volts to about + 14 t} 5 volts.

This makes the field effect transistor 6l conductive. The remitted from the original and captured in the photo element 62 Light generates a current in this photo element, which the operational amplifier via the current-voltage converter 631 66, the resistor 67 and the - now conductive - field effect transistor 6l the storage capacitor 71 charges. This capacitor charges up to the point that until the voltage at the source electrode of the field effect transistor 69 has the same value as at non-inverting Input of the operational amplifier 66 reached. After the output pulse of the monostable multivibrator has decayed

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the transistor 61 blocks again, so that the voltage at the capacitor 71 remains stored and the output signal is still available at the source of the field effect transistor 69.

This output signal is in the multiplier ~ jh with that resulting from the aperture measurement, in the photo element; SO generated control signal multiplied. The potentiometers 79 »86 and 89 are used to adjust the output current of the multiplier 7 ^ if the multiplier is not activated.

The output current of the multiplier Jk. is in turn converted by the current-voltage converter 87 into a proportional voltage, which is compared in the operational amplifier 93 with the voltage set on the potentiometer 95 and corresponding to the exposure setpoint. If there is a discrepancy between the target value and the actual value, the operational amplifier 93 controls the subsequent power stage, which supplies the current for the rotary magnet.

In this power level flows through the resistor the diodes 105 to I08 and the resistor 109 a cross current, the transistors 99 to 102 arranged in a Darlington circuit via the voltage drop across the diodes so far

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controls that there is just no collector current flowing. If the operational amplifier 93 supplies, for example, one based on a corresponding setpoint / actual value difference positive output voltage, the potential shifts in the middle between the diodes also in the positive direction, the base of transistor 99 is activated. This also makes the transistor 100 conductive, so that a Control current can flow and the rotary magnet 8 rotates in the corresponding direction. This will make the coupled Adjusted rotary shutter, which in turn changes the illuminance of photo element 80 accordingly.

This closed control loop causes the rotary shutter to be adjusted until the reflectance value and The product signal resulting from the aperture value is the one on the potentiometer 95 corresponds to the setpoint set.

The potentiometers 65167 * 83 or 91 are used for offset adjustment the operational amplifiers 63, 66, 81 and 87, respectively.

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Claims (6)

AGFA-GEVAERT AKTIENGESELLSCHAFT November 21, 1975 Leverkusen 10-re-zi PG 8 * t8 / MG 1131 patent claims 1. Device for automatic exposure control
In the case of microfilm cameras with a measuring station for measuring the re-emission value of the original to be filmed, with an illumination station for the original to be scanned on a recording medium, seen in the transport direction of the original, and with means for controlling the
Amount of light impinging on the recording medium by means of one obtained from the reflectance measurement
Control signal, characterized by a) a lighting system of constant brightness (3) for the exposure station (5) » b) a diaphragm system (7) with a variable diaphragm opening for the exposure station, c) a device (3i9) for generating one of the for the aperture relevant to the exposure beam path, analog control signal, -Ic- 709821/0541 ι ' PG 848 / MG 1131 d) a multiplier (lk) for multiplying the control signal obtained from the reflectance measurement with the control signal analogous to the aperture, e) a device (15) for comparing the resulting product signal it with a predetermined one desired exposure of the copy medium corresponding value as well as for generating a corresponding difference signal, f) a device (16, 8) for controlling the aperture by means of this difference signal. 2. Apparatus according to claim I _1, characterized in that means for storing (l3) the control signal obtained from the remission measurement are provided and that means for writing (10,11) this control signal are present in the memory, which is in operation once for each original step. 3. Apparatus according to claim 2, characterized in that in the conveyor track (l) of the templates (2) one of the Templates actuatable light barrier (10) is provided, which enables the writing of the control signal in the memory (13) initiates. -19- 709821/0541 -Λ PG 848 / MG 1131 4. Device according to one of the preceding claims, characterized in that a rotary shutter (7) which can be actuated by means of a rotary magnet (8) is provided. 5 · Device according to one of the preceding claims, characterized in that a Constant brightness lamp (3) is attached and that behind the diaphragm a light-sensitive element (80) is arranged, which measures the light passing through the diaphragm from this lamp and one of these Amount of light generated analog output signal. 6. Device according to one of the preceding claims, characterized in that for the measuring station for the renission value and for the exposure station common lighting system (3) is provided. 7. Device according to claim 5 and claim 6, characterized characterized in that for the lighting station, for the measuring station for the reflectance value and for the Measurement of the aperture a common lighting system (3) is provided. For this purpose 2 sheets of drawings 709821/0541