DE1497923C3 - Color photographic copier - Google Patents

Description

P ₁ log Z ₁ ■ = N ₁ - log O ₁ + C + a [*., (N ₂ - N ₁ ) + * ₃ (N ₃ - W ₁ )] P ₂ log L ₂ = N, - log θ ₂ + C + a [a, (N ₁ - W ₂ ) + a ₃ (N ₃ - N ₂ )] P ₃ log t ₃ = N ₃ - log Θ ₃ + C + a [a, (N ₁ - N ₃ ) + _x . ₂ (N ₂ - N ₃ )] ,

where with ρ the Schwarzschild exponent, t the required exposure time, N. the original density, Θ the brightness of the copy light source in the respective color, C the total density of the copy, α the factor for the crosstalk of the other two color densities or degree of undercorrection, λ the Factor for the sensitivity of the eye to brightness is designated in the relevant color and the sum of the values «j + äo + äj =! and the index numbers each refer to one of the three basic colors red, green and blue.

3. Photographic color copier according to claim 1 or 2, characterized in that for storing the original density values measured during copying Memory (42) provided that the density values at least up to the end of the longest of the three exposures save in the individual colors.

4. Photographic color copier according to one of the preceding claims, characterized in that that to determine the impinging on the copy material in each of the three colors Light quantity (copy light quantity) a transmitter (24) of a time-dependent, starting with the start of exposure Signal and a transmitter (30, 31) for a logarithm of the copy intensity in the relevant Color proportional signal and encoder (18, 19) for each one of the logarithm of the co- ' pier light intensity in the other two colors signal reduced by the crosstalk factor are provided.

5. A photographic color copier according to claim 4, characterized in that for generation of the signal corresponding to the copy light intensity on in the relevant color sensitive SEV (7, 8, 9), a logarithmic amplifier (17) and one in a known manner Memory (42) built on semiconductor components lie in series, with two parallel-connected, Potentiometers (45, 46) connected to ground on one side, their sliders rotating in opposite directions are coupled and connected to an addition amplifier (36).

6. A photographic color copier according to claim 5, characterized in that the grinder the potentiometer arranged at the appropriate point in the various color channels (45, 46) are coupled to one another.

7. Photographic color copier according to one of the preceding claims, characterized in that that it contains an electronic analog computer.

The present invention relates to a color photographic copier having a photoelectric exposure control device including three each one Color channels, which are assigned to a color and made up of photo receivers and amplifiers a predetermined amount of light in the relevant color on the photoreceptor to end this exposure and with a device for achieving an undercorrection with respect to the so-called neutral gray compensation by taking into account the respective color densities of the original in the other colors when measuring the amount of copier light in one color.

In a device of this type that has become known, an undercorrection compared to the so-called Neutral gray principle in a color depending on the sum of the density in the two other colors applied.

It has now been found that better results, especially a higher number of salable First copies, are obtained when the undercorrection in one color is automatic depending on the Differences between the density of the original in that color and that in the other two Colors is done.

The object of the invention is to create a copier that this type of undercorrection with adjustable Allows to carry out degree of correction. This problem is solved by in the claim 1 described invention.

If the degree of dependence of the undercorrection while maintaining an approximately constant If the total density of the copy is set according to the original, the operation is simplified a corresponding copier quite considerably. It then needs to be used in assessing the Template only to be examined whether there is a color dominant in the template, i. H. larger areas one Color, are available. If this is the case, a corresponding degree of undercorrections becomes completely independent chosen by the color of the dominant. Instead of the previously usual three color correction options is now only one key that determines the degree of undercorrection or a corresponding one Rotary lever to operate.

According to the invention, the exposure time is timed in each of the three colors according to the following Equation determines:

P ₁ log t, = N ₁ - log O ₁ + C + α [a ₂ (N ₂ - N ₁ ) + * ₃ (N ₃ - N ₁ )] ,

where P _{1 is} the Schwarzschild _{exponent, Z 1 is} the required exposure time, N _{1 is} the original density and O _{1 is} the brightness of the copy lamp in the respective color, C is the desired overall density of the copy, α is the factor for the crosstalk of the other two color densities or the degree of Undercorrection and a _; is the factor for the brightness sensitivity of the eye in the relevant color and the index numbers 1 to 3 each relate to one of the three primary colors red, green and blue. A further normalization condition is that the sum of all factors α for the sensitivity to brightness of the eye is equal to 1 and that the individual color densities in the copy are linearly superimposed.

Further details and advantages of the invention emerge from the related subclaims with the description of an exemplary embodiment which is explained in detail with reference to figures is.

It shows

1 shows a basic illustration of a device according to the invention equipped copier,

FIG. 2 is a basic circuit diagram of the copier according to FIG. 1 and

F i g. 3 is a diagram for explaining the mode of operation, in which the degree of undercorrections is plotted on the abscissa and the amount of light J ₁ t _{t is} plotted on the ordinate.

In Fig. 1, 1 denotes a light source, the light in all three additive primary colors approximately in sends out the same dimensions. The light from this light source is via a double capacitor 2 on a Copy master 3 collected, which is imaged by an objective 4 on a copy carrier 5. Between Objective 4 and copy carrier 5 is a partially transparent mirror 6 is arranged, which is part of the copy template 3 outgoing light on measuring cells 7, 8, 9 throws. The measuring cells are in the present case designed as a secondary electron multiplier, the are sensitive to only one of the three colors due to upstream color filters. The order is made in such a way that for each of the SEV a portion of the Light falls. The three SEVs are connected to a control device 10, their structure and function will be explained in detail.

In the copy light beam path, subtractive color filters 11, 12, 13 are also arranged, which are made by electromagnets 14, 15, 16 can be moved into the beam path. The electromagnets 14, 15, 16 are connected to the control device 10, so that the exposure in each of the three Primary colors can be finished separately.

In Fig. 2 shows the circuit diagram of the control device 10. The control device is an analog computer formed, which is made up of similar components, so-called operational amplifiers.

The control circuit is essentially divided into three similar color channels 17, 18, 19. A voltage divider consisting of a fixed resistor 21 and an adjustable resistor 22 is located in each of the color channels between a DC voltage source 20 and the ground potential. Another resistor 23, to which an integrator 24 is connected, is connected to the slider of the adjustable resistor. This is constructed in the manner described from an operational amplifier 25, a capacitor 26 lying parallel to it, a resistor 27 and a normally open contact 28. The integrator 24 is connected via a resistor 29 to a logarithmic amplifier 30, the feedback of which is formed by a diode 31. The logarithmic amplifier 30 is connected to a negative voltage potential via resistors 32 and 33. At the tap between the resistors 32 and 33 is the connection for a potentiometer 34, which is used to adjust the Schwarzschild exponent ρ . A resistor 35, which is connected to an addition amplifier 36, is connected to the potentiometer 34.

The addition amplifier 36 is formed in the manner described by an operational amplifier 37 and a feedback resistor 38. The resistor 35 has half the resistance value as the feedback resistor 38. The output signal of the addition amplifier 36 is in a connected comparator 39 with a fixed reference potential, z. B. mass, compared, the comparator energizing the relay 14 as a function of the signal from the addition amplifier 36. A diode 40 is located parallel to this in a known manner. The relays 14, 15, 16 are all connected to a common voltage supply 41 and are controlled by the comparators of the corresponding color channels 39.
Parallel to this first part of a color channel, which represents a transmitter for a time-dependent signal, there is a second branch which supplies a signal that is dependent on the density of the original in the corresponding color. At the beginning of this sub-channel, which is also designed the same for all three colors, is the SEV 7, the z. B. is sensitive to red and does not react to light from the original in a different color. This SEV is connected to a logarithmic amplifier corresponding to the amplifier 30, 31. Behind this is a memory device 42 which can maintain the signal for a certain time, even if the SEV 7 is no longer illuminated. Such storage devices made up of semiconductor components are already

5 6

knows and is not the subject of the invention. You are bringing signal. In this position there is an above not described in detail. speak from channel to channel do not take place, and the

Between the output of the storage device copy is independent of the original on Neutral-42 and a negative voltage source is compensated for by off gray.

Resistors 43 and 44 of existing voltage 5 In the other extreme position, in which the loop divider, at its intermediate tap, the one connections fer 45 to the voltage of the voltage divider 43, 44 of two parallel to each other, on the other hand, and the wiper of the potentiometer 46 to ground Ground potentiometers 45 and 46 are located. is, the brightness of the original is in the color. The wipers of the potentiometers 45 are opposite to each other in this channel to the copy exposure. The wiper of potentiometer ¹⁰ is speaking color not more influence than the beat meter 45 with a resistor 35 to the parallel of the template in the other two colors th. Connected in lying resistor 47, to which parallel in this case there is the maximum undercorrection or, to put it another way, no Korder point at all in the other color channels 18, 19. The result is the same as if with are arranged. The resistance of this resistor ¹ S of a white lamp and a single photocell of the differs from the feedback the exposure is controlled, with the cell on resistance 38 by the factor <x _v ie by the factor of all three colors in approximately the same way responds, tor for the sensitivity of the eye to brightness for between these two extreme values can all this color. The corresponding resistances in the intermediate values strictly according to the theoretical glide, other color channels have the same value. «° chung can be set.

The wiper of the potentiometer 46 is with a The wiper of the potentiometer 45, 46 are with

connected to the resistors 35 and 47 parallel to the wipers of appropriately arranged Po resistor 48. This resistance has potentiometers, in the color channels 18 and 19 mechadenselben value as the Rückkoppelungswider- cally coupled so that grinders are adjusted by channel disposed in a paint booth 38. ² S potentiometer in the same way parallel to the resistors 35, 47 and 48 are like the the potentiometer 45 and resistors 49 and 50. The resistor 49 46. In this way, for all three color channels has a resistance value that differs from that of the over resistance 38 by adjusting a handle by a factor of 1: <x ₂ , speech factor α set.

that is, it takes into account the luminosity of the second 3 ° Das to end the exposure process in color, while the resistor 50 with its value of the color controlled by the color channel 17 determines the luminosity of the third color. The mende potential is further influenced by the resistor 49 is connected to the wiper of a potentiometer 49 and 50, to which an over meter in the second color channel is connected, which corresponds to the speaking factor α reduced potential of the brightness potentiometer 45 in the first color channel. 35 is in the other color channels. Depending on the resistances corresponding to the resistor 49, the sum signal that is provided in the amplifier 36 is formed by the addition at the appropriate point in the color channels 18, 19 of all these variables. The resistor 50 is in the same way comparator 39 with a fixed reference potential, a potentiometer in the third color channel is adjusted and which closes at a certain level, which leads to the potentiometer 45 in the first color 4 ° energization of the relay 14, whereby the Filter corresponds to channel. brought into the beam path and the exposure in

The operation of the described device of the corresponding color is terminated,
is as follows: By setting the potentio- The exposure control takes place in the channels

meters 22 the steepness of the voltage rise 18 and 19 in the same way. There must be the signal determined on the integrator 24, which starts when the 45 for the original brightness of all colors to the end switches 28, which are closed in the idle state, are open for the longest exposure time, will. This integrator therefore gives a time-dependent In the present circuit diagram is therefore the memory Signal introduced by the logarithmic amplifier 42. Such a memory can be omitted, ker 30 is logarithmized and that by the cons if z. B. by changes to the copier board 34 at the Schwarzschild exponent of the Emul- 50 care is taken that at the end of the exposure sion the photocell in the corresponding color of the light-sensitive copier material in one color borrowed material can be customized. At the pot still being exposed. That can be done with an oniometer 22 can therefore the basic sensitivity direction according to FIG. 1 z. B done in the way of the copying material in the respective color that the partially transparent mirror 6 for branching off will be presented. 55 of the measuring light already from the color filters 11, 12, 13

The second part of the color channel 17 gives a signal that is arranged in the copy light beam path,
that of the density of the original in the corresponding- In F i g. 3 is the mode of action of the invention

depends on the color. The output voltage of the appropriate circuit based on a diagram er-SEV 7 is a measure of the brightness of the original. Lautert, in which on the abscissa the degree of the sub-voltage is logarithmized and from the 60 correction α is plotted, and the memory 42 is recorded as the ordinates. The two potentiometers radiation doses in the individual colors. On the 45, 46, which are coupled in opposite directions, taking into account the ordinate axis, ie at a = 0, the measurements lie the influence of the crosstalk factor α of color dots for a negative with exposure control channel to color channel. In a a = 0 of the sander is the Neutral Gray principle. With increasing underside of the potentiometer 46 set so that the full 65 correction α the long switching times are shortened, while the voltage of the voltage divider 43, 44 on the opposite side is lengthened. This happens in the stand 48, while at the same time the grinder is in the way that the total density of the copy thereby kon-potentiometer 45 is practically at ground, so is not kept constant. With an undercorrection a =

Assuming that the basic calibrations across the timers were the same, there is a common switching time t _s , which would also result if a pure white exposure were carried out, the length of which only depends on the overall density.

If the calibration times are different, curves of the same character result, but these do not strive towards a common end point, but are split into three end points, the ordinates of which depend from the calibration time.

For this purpose 2 sheets of drawings

509 584/325

Claims (2)

Patent claims: 1. Color photographic copier with a photoelectric exposure control device; Contains three, each assigned to a color, of photo receivers and amplifiers built-up color channels, which when a predetermined amount of light hits the relevant Paint on the photoreceptor to finish this confection and with a device to achieve an undercorrection compared to the so-called neutral gray compensation through consideration the respective color densities of the original in the other colors when measuring the amount of copier light in the one color, characterized in that the undercorrection each depending on the differences between the original density in the relevant Color and the other two colors and that for setting the degree of undercorrection a potentiometer (46) for the associated density signal is provided in each color channel is, with the opposite potentiometer (45) to measure the influence of this Density signal is coupled to the other two color channels, so that an approximately constant one To achieve copy density. 2. Photographic color copier according to Anspaich 1, characterized in that the exposure control with time control in each of the three colors according to the following formula: