DE2135017A1 - Photographic process timers - Google Patents

Description

Chesley P. Carlson Company, 2230 Edgewood Avenue, Minneapolis,

Minnesota 55426 (U.S.A.)

"Timers for photographic processes"

The invention relates to a circuit arrangement for controlling the main, peak brightness and flash exposure times of Lamps commonly used in continuous tone and halftone photographic processes. In photography it becomes more and more important to produce quality work with high output. To this end, the industry is turning to electronic circuits over to the speed required for mass production to reach. Various circuits are known which use an RC timing cycle to keep the various, in continuous Lamps used to turn on and off tone and halftone photographic processes. However, these circuits are by use of alternating voltage and by monitoring the charge of the capacitor so complicated that additional circuitry is required to prevent random noise pulses from causing a false display of the maximum potential, which indicates the end of the control cycle. Also, some of these circuits are limited either to the change of time units (seconds) or the relative illumination (density of blackening). the

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Standard density values vary with the exposure time and those skilled in the art using ordinary non-electronic equipment consider both exposure time and exposure time Blackening density in the production of quality work. Due to the range of timing cycles desired and the non-linearity the effect of normal lighting on a film, most of the circuits used heretofore also have a large number of resistance and capacitance elements.

According to the invention, regulated DC voltages are used and by monitoring the discharge of a capacitor, a simple circuit is built that can be used in the reproduction of successive High quality work works very accurately. Due to improved electronic construction, especially in the The range of resolution of logarithmic and linear relationships of voltage and current sensitivities was the number of for the desired time sensitivities required capacitance and resistance elements significantly reduced.

Another object of the invention is the use of phototubes to monitor and compensate for fluctuations in the mains voltage and deterioration in the various lamps used. These phototubes change the timing cycle chosen.

Furthermore, normal photographic techniques can be used according to the invention because the invention enables both variable exposure times and variable blackness densities. To the To achieve these results, relays are assigned to each lamp,

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a change in the preselected exposure time and density values according to the halftone screen and density values of the original used. Choosing the one you want Lamp is done by briefly pressing a button, which switches on a relay that has a timing capacitor charges to a potential that depends on the desired exposure time and density. Both the size of the too charging capacitor and the required potential depend on the above-mentioned blackness and time unit values. the Circuit arrangement allows a linear change in the voltage, this being generated by a current that is logarithmic is changeable. This will reduce the number of resistor and capacitor elements normally used in a circuit of this type significantly reduced.

Pressing the start button switches off the charging circuit and energizes the selected lamp, thereby discharging the capacitor is initiated through a photosensitive phototube. Since the discharge takes place via the light-sensitive phototube, calls any change in the mains voltage or deterioration in user ^ th lamp a change in the phototube line and thus a compensation of the mains voltage changes or deterioration the lamp. The discharge of the timing capacitor is through a differential amplifier and differential comparator monitors to determine when the capacitor has discharged to a small predetermined value. If this little potential is reached, the output voltage of the differential compa-

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rators to a relatively high positive within nanoseconds Value. This output voltage is sent to the control electrode of a controllable silicon rectifier which, when it conducts, "de-energizes a relay that regulates the lighting circuit. When the relay is de-energized, its switch de-energizes the lamp used and thus terminates its time control: cycle.

Briefly pressing the switch assigned to the next lamp to be used de-energizes the switch connected to the first lamp Relay and begin to set the timing capacitor to a predetermined one Charge value for the second lamp. As already mentioned, pressing the start button disconnects the charging circuit again and measures the exposure time of the second lamp. This process is repeated until the photographic process is finished. It it should be emphasized that optionally instead of the one for black and white photo processes used lamps each of the individual lamps can be replaced by color lamps for color work; for this purpose a switch is provided.

A modification of the invention includes a mechanical computer, with the density readings introduced into the scales and further blackening values can be calculated and introduced automatically. Used to be these values by hand with the associated ones Errors and time delays calculated. This computer works on the principle of the slide rule; it calculates excess darkness values and automatically introduces these after entering the shadow blackening values ', the peak brightness blackening cur'

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and the halftone area in the computer dials. A cam plate and a cam follower and gears are used for this purpose provided to mechanically calculate the photo process timer in accordance with the conventional photographic formulas and to calibrate.

The invention will now be illustrated with reference to one in the drawing Embodiment explained in more detail. This shows in

Fig. 1 is a schematic circuit diagram of the timer according to the invention,

Fig. 2 is a schematic circuit diagram of the associated relays and circuits for the use of the timer according to the invention at different illuminations in photographic halftone processes,

Fig. 3 is a schematic diagram of the relationship between resistance and capacitive elements, whereby the current intensity and consequently the time cycle in a logarithmic Row can be changed,

4 is a schematic circuit diagram of the mechanical computer,

Fig. 5 shows the cam disk of the mechanical computer to achieve the desired values.

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Pig. 1 shows the photo-process timer according to the invention, which can be connected to a commercially available power source. A conventional controllable power source 12 converts alternating current to direct current of opposite polarity. For example, the current source 12 can be designed in such a way that a positive 2k V voltage is applied to one ungrounded output terminal 13 and a negative 20 V voltage is applied to the other ungrounded output terminal 14.

Circuit section 15 is a charging circuit for a variable capacitor 17. The discharge circuit for the capacitor contains the circuit sections 20, 21 and 22 as well as the outer phototube 24. Circuit section 20 is a commercially available differential amplifier3 which monitors the voltage potential of the capacitor 17 and the differential to the circuit section 21 passes on. Circuit section 21 is a conventional ³ differential comparator which generates a gradually increasing output power when its input power decreases to a small negative potential. This step-by-step output power is passed on to the circuit section 22, which indicates the end of the control cycle by igniting a controllable silicon rectifier 26 which de-energizes a relay 27 for extinguishing the lamps 30. Under the supervision of the above-mentioned circuit sections 20, 21 and 22, the actual discharge of the capacitor 17 takes place through the phototube 24, which only remains conductive as long as the lamps 30 are energized.

In Fig. 1, the charging circuit 15 uses a constant current

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source in the form of a field effect transistor 32. With the drainage current path this transistor 32 is a variable resistor 33 connected in series. The lower end of this resistor 33 is connected to the control electrode of the field effect transistor 32, so that the current through the field effect transistor 32 is adjusted by changing the resistance. With the transistor 32 and resistor 33, a variable resistor 36 is also connected in series, through which the charging capacitor 17 by the normally closed relay armature 39 is connected in parallel. It follows that the voltage level across the capacitor 17 i is determined by setting the variable resistor 36 and that the current through the field effect transistor 32 is dependent on the setting of the variable resistor 33. The variable Resistor 33 and variable capacitor 17 are used for logarithmic changes in illumination (blackening scale), while the variable resistor 36 for linear time change (Time unit scale) is used.

Fig. 2 shows how the timer according to the invention, bottom left in Fig. 2, is used for selective time setting different " those lamps used in continuous tone and halftone processes using photosensitive emulsions. The operational functions of the main, peak brightness and flash circuits are discussed below. Every circuit is used to produce a first-class, continuous tone or halftone reproduction of the original to be copied. In each Circuit is the variable resistor 36, which preferably consists of a series of standardized decade resistors,

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to allow linear changes in the units of time. Accordingly, a voltage that is directly proportional to the current flowing through the constant current source 32 is applied to the regulating capacitor 17 and this allows linear changes Changes in the exposure time due to the uniform settings of the resistance associated with the time unit scales

The adjustment of the charging circuit section 15 is used to achieve uniform changes in lighting due to uniform changes in the impedance elements 33 and IJ connected to the blackening scales. Since the illumination changes logarithmically with the exposure time, the variable resistor 33 and the variable capacitor 17 are used to generate logarithmic changes in the exposure time. There are two methods to achieve this result. The discharge time depends on the size of the capacitor and the corresponding charging voltage. Since the number of 0.1, 0.2 and 0.3 (the desired degrees of darkness) is equal to 1.259, 1.585 and 1.995, and since 1.995 is approximately two, the result is that the discharge time for each degree of darkness is 0.3 must double. It is known that the RC time constant for the discharge of a capacitor is directly proportional to the capacitance. Therefore a doubling of the discharge time, and consequently the exposure time, can be achieved by doubling the capacitor capacitance 17 for every increase in blackness of 0.3. In order to obtain uniform levels of blackening with uniform settings of the capacitor 17 in the capacitance range, the current must be logarithmic

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be reinforced. With the resistor network described below, indicated generally at 33 in FIG. 1, the current within each blackening interval of 0.3 is amplified in a logarithmic series. The capacitance value 17 is doubled after each blackening level of 0.3 and the resistance value 33 becomes returned the value calculated for 0.0 density. This gives a logarithmic gain to the lighting for reaches the desired range 0.0 to 2.0 in steps of 0.01 on the blackening scale.

Fig. 3 shows schematically how the logarithmic changes in the current through the variable resistor 33 and the variable Capacitor 17 can be achieved using as few impedance elements as possible. The changeable resistance 33 consists of a rotary switch 65 and associated resistors 42-44 and 48-50, as well as a rotary switch 64 with resistors 55-63. The parallel connection of resistors 42-44 or 48-50 enables blackening levels of 0.1. Blackening levels of 0.01 are achieved by the resistors 55-63, which are connected in series with the parallel branch of the resistors 42, 43 and 44. The number of resistors and the size of each resistor results from the following;

The desired maximum current can be selected from the characteristic curves of the field effect transistor 32, as can the Resistance value 33 necessary to generate this current 1.259, 1 »5Ö5 and 1.995) to the maximum current value are matched

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send current values achieved which, when applied to the characteristic Curve of the field effect transistor 32, the desired resistance values for blackening levels of 0.1 result. That I If you double the ratios for each density level of 0.3, instead of increasing the resistance, the capacitance value will be 17 doubles after each step of 0.3 and the circuit resistance 33 is brought back to its initial value. This method is a simple and economical circuit design for the desired logarithmic increases.

Density levels of 0.01 are achieved by using one of the resistors 42, 43 or 44 in series with the variable resistor 46, both being connected in parallel with a second resistor 48, 49, 50, as shown schematically in FIG. The total resistance of these networks connected in parallel is chosen so that the corresponding resistance (33 in FIG. 1) is the one calculated above in decadic blackening levels (eg 0.00, 0.10, 0.20 blackness density). For a given resistor (R 1) which can be varied from 0 to a positive value (46 in FIG. 3), the following formulas for R ₁ and R _{2 represent} the values for resistors 43 and 49, respectively, which are between Blackness densities of 0.1 and 0.2 are to be used.

" ^R 3 ⁺ W ₃ 2 + (4) (A)

where A = ( ^R _Ot2 ^{blackening) (R} 0 ^ blackening)

(Rq 2 blackening) - (R ₀ ^ blackening)

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(R ₁ ) (Rq λ blackening)
(R ₁₎ - (R _n .Schwärzung)

With the same formulas one can calculate values for the resistors 42, 44, 48 and 50 for the blackening levels between 0 and 0.1 and 0.2 and 0.3 obtained.

Therefore, in the corresponding circuit according to FIG. 3 every blackness level of 0.3 doubles the capacity and a return to the first contact positions of the rotary switch 65

A doubling of the capacity 17 for each density level of 0.3 is achieved using rotary switches 67 and 69 connected to one another. Capacitors 72-78 (common in Fig. 1 marked 17) are connected to the rotary switches for this purpose. It is emphasized that for the first four capacity levels individual larger capacitors 72 to 75 used * will. Thereafter, larger capacitors are continuously connected in parallel to achieve a total capacitance value for the last capacitance level twice the size of the last capacitor 78 to f achieve.

A principal density of 1.55 is used as an example of the operational position of this network. Fig. 2 shows that, when relay 240 is energized, current flows (conventional current flow is assumed) from earth through a relay switch 247, Conductor 284, time unit resistor 52, conductor 287, conductor 282, relay switch 291, blackening resistor 33, conductor 289, field

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Effect transistor 32, conductor 286, relay switch 248 for negative Voltage source. The regulating capacitor 17 is from point 280 Connected to earth via conductor 301, relay switch 39, conductor 300, relay switch 292, regulating capacitor 17. It is emphasized that the time unit resistance 52, as stated above, is connected to earth

52 is bound; therefore, the unit time resistance and the Regulating capacitor 17 in parallel.

The arrangement shown in Figure 3 is the detailed apparatus illustrated in Figure 2 by the variable blackening resistors 33 and 33a and variable variable capacitors 17 and 17a connected between relays 291 and 292 and point 80 and ground. In Fig. 3, for a blackening density of 1.55, a current would be from point SO via a conductor 82, contact 83, rotary switch 64, contact b5, conductor 87, resistors 58, 59, 60 and 61, conductor 89, conductor 92, resistor 42, contact 95, rotary switch 65, contact 97, conductor 99, conductor 101, flow to relay switch 291. A parallel current would flow from point 80, conductor 81, conductor 104, resistor 48, contact 117, rotary switch 65, contact 97, conductor 99, conductor 101 to relay switch 291. Similarly, the variable capacitor 17 would contain the capacitors 75, 76 and 77 connected in parallel, the connection from the relay switch 292, via a conductor IO6, conductor 107, contact 110, rotary switch 69, contact 112, capacitor 77 going to earth; A common connection 112 also leads to earth via rotary switch 67, contact 114 and capacitor 75 and from contact 115 via capacitor 7b. Similar circuits can be designed for any density from 0.00 to 2.0.

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Pig. 3 also shows the resistance and capacitance elements required for the flash lamp exposure time. It is known, that if flashlight is used this gives different characteristic results during the procedure than the rest of lighting technology. Design values for the lightning scale parameters result from the following formula:

Δ T = 100-100

where T is the flash exposure time for a given change the lightning density is required. Time values result for blackening changes of 0.05 and ratios between the subsequent fair value are created. In the same way as above, the ratio ahIeη to the desired maximum current of transistor 32 applied to corresponding ^ resistance values 33a and capacitor values 17a.

Fig. 3 shows that the density parameters (33a and 17a in Fig. 2) are arranged similarly to the blackening elements 17 and 33. However, it should be noted that the construction is made economical by using the same capacitors as are used can be used for the main and top light blackening circuits. The resistance elements included in the lightning blackening circuit include resistors 120-142. If the circuit were designed for a flash density of 1.50, the relay 290 would be energized and the relay switches 291 and 292 would be in the opposite position to that shown in FIG. Current would (in a conventional manner) from point ö0 via the conductors dl, 104, 144, 145, den

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Resistor 125, conductor 146, resistor 133, contact l48 _s rotary switch 149, common connection 150, rotary switch 152 ₅ contact 153, conductor 154 flow through relay switch 291. The variable capacitance 17a would contain the capacitor 74 and would be connected to earth in the circuit via the relay switch 292, conductor 155, rotary switch 156, common connection 157, rotary switch 158 _s contact 159j conductor 16O _{3 capacitor 74.}

As mentioned above, the unit time resistors are 52, 53 and (36 in Fig. 1) standardized decade resistors connected in series and are optionally connected in parallel with the timing capacitor to receive current from field effect transistor 32. Because of of the above-mentioned blackening density maintenance (Fig. 3), a current of constant magnitude flows through the time unit resistors 36 regardless of the total resistance. This means that the voltage drop across the resistor 36 is linearly proportional to the resistance value, since the current is kept constant for any given visual density. The timing capacitor 17 is therefore charged with a negative voltage that is proportional to the numerical value set on the time unit switch.

The rotary switch 173 is another object of the invention. It is shown in Fig. 2 in the normal position, with the normal time unit resistance groups 36 are connected in the circuit. But if, for example, there is a color separation or different If halftone screens have to be used, additional groups of time unit resistances can be created by using pawls 174

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provided, all of which can be set beforehand. With the help of this additional resistance group, the time units can be set for each color before reproduction starts. Therefore, only the rotary switch is required to change the color 173 to be rotated to bring the preset time unit values into the circuit.

In Fig. 1, the circuit section 20 is a differential amplifier, of the discharge of the capacitor 17 through the phototube supervised. Since every conventional differential amplifier uses j the construction shown is a device MEM 550 from General Instrument Corp. It contains two related, field effect transistors 16 and 162 connected in parallel, the both connected to the negative voltage source 14 with respect to earth are. The source electrode of the transistor 16l is connected to one side via a conductor 163 and a resistor 164 Potentiometer I65 connected. The pickup I66 of the potentiometer is connected to earth. The source electrode of transistor I62 is similarly connected through a conductor I67 and a Connect resistance I6ö with the other side of potentiometer I65 bound. Both field effect transistors Ιοί and 162 are forward prestressed; Transistor IbI from the source electrode via conductors 170, resistor 171, conductor 172 to the positive bus 175, and transistor 102 from the source electrode via conductor 176, Resistor 177, conductor 173 to positive bus 175.

The temperature stabilization of the two field effect transistors takes place through the resistors 164 and I6ö, each with the

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Source electrode of transistors 16l and 162 in series on the opposite one End of the zero adjustment potentiometer are connected. The Point selected where the field effect transistors I6I and Io2 one Have temperature coefficients of zero. Since the control electrode of transistor I6I is grounded through a conductor I80, that will Transistors pair balanced by setting the resistor 36 to zero, the resistor 36 to the control electrode of the second transistor 162 is connected. The resistors 171 and 177 are then chosen so that one obtains a current that is necessary to obtain a temperature coefficient of zero. The corresponding currents are then set using the potentiometer I65 balanced. After that, any increase or decrease the temperature of both field effect transistors 161 and 162 evenly influence and not disturb the differential between the two.

The circuit section 21 contains a conventional, very fast differential voltage comparator 182 of solid state design, e.g. a Fairchild u A 710 C. In parallel with the output terminals of the circuit section 20 is a capacitor switched to suppress the switch-on surge. Series resistors I86 and I87 are between the output terminals of the circuit and the input terminals of the circuit 21 are switched to match the input of the commercially available comparator 182. Farther Overvoltage protection is guaranteed by a Zener diode I89 connected to the input of the differential comparator 182 via conductor 190 and 191 and to earth via conductor 193, diode 194 and conductor 195 is connected.

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A positive is applied to terminal 202 of differential comparator 182 Voltage from the positive busbar 175 via conductor 197 j a series resistor 19 &, which meet the operating conditions must, as well as a ladder 200 created. A negative voltage is applied from negative bus 205 through conductor 206, Series resistor 207 and conductor 208 routed to negative terminal 209.

The voltage transfer characteristics of the differential comparator 182 are such that the output of comparator 182 remains slightly negative for large negative input voltages until the Input voltage decreases to a small negative millivolt value. After that, any further reduction in tension causes that the output reaches a relatively high positive voltage within nanoseconds. E.g. the output voltage goes to Pairchild u A 710 C from approximately 0.5 V to 3 V across.

The circuit section 22, which essentially consists of a series resistor 211, the controllable silicon rectifier 26 and the M relay 27, is used to indicate the end of the time cycle. The output of the differential comparator 182 is connected to the control electrode of the silicon rectifier 26 via the series resistor 211 and a conductor 212. A resistor 215, which is connected between the control electrode of the rectifier 26 and earth, is intended to ensure that the electrode voltage remains approximately at earth potential until the step input of circuit 21 takes place. The relay 27 is energized by the positive bus line 175 via a manual switch 213, a series pre-resistance

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stood 214, the relay coil 27 and a diode 217 to earth. By When the relay 27 is energized, a normally open relay switch 220 is closed which energizes a relay 221 which through its relay switch 222 holds the above-mentioned relay 27 in the energized state. A resistor 225 and a capacitor are connected in parallel to relay 221 for spark quenching. A Capacitor 230 for suppressing the inrush current is connected in parallel to rectifier 26 and relay 27. If the Input voltage of circuit 21 increases, the rectifier 26 is ignited and conductive. Current then flows through circuit section 22 from positive bus 175 through resistor 214 and rectifier 2b to earth. A quick de-energization of the relay 27 is achieved with a diode 217 that the counter electromotive force that has built up across the relay 27 when it is short-circuited by the rectifier 26 will.

Fig. 1 also shows schematically that the selected lighting is energized and de-energized by switches connected to relay 221.

In Fig. 2 the timing circuit is shown with various relays in order to achieve the photographic results sought after according to the invention to enable high quality. For black and white photographic processes, resistors 33, 33a, 52, 53 and 54 and the capacitors 17 and 17a individually preset and the relays 240, 241 and 242 actuated successively to the particular to get the composition you want. Each of the relays

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240, 241 and 242 operate four relay switches. The relay switches 245, 246, 247 and 248 for relay 240; Switch 250, 251, and 253 for relay 241; and switches 255, 256, 257 and 258 for Relay 242. Note that switches 247, 252 and 257 have two sets of contacts and are therefore used both in the normal position as shown and when each is associated Relays 240, 241 and 242 are energized.

The first switch on each relay 245, 250 or 255 causes the automatic latching of the relays after briefly closing the pull- '( belonging manual switch 260, 261 and 262. When the manual switch 260 is closed, the relay 240 is powered by the positive voltage source through the coil of the relay 240, conductor 265, switch 260 excited to earth. Energizing relay 240 closes switch 245 and thereafter relay 240 is de-energized from the positive voltage source via conductor 266, switch 245, conductor 267, switch 256, conductor 269, switch 252 in the normal position, as shown in FIG. 2, for Earth excited. Relay switch 246 de-energizes relay 24l. Assuming relay 241 energizes prior to pressing switch 26O, then J it from its positive voltage source across the coil of the relay 241, conductor 270, switch 250, conductor 272, switch 246, conductor 274, switch 257 energized in its normal position to earth. Energizing relay 240 opens switch 246 and thus de-energizes relay 241. Similarly, the switch de-energizes relay 242, normally from its positive voltage source, via coil of relay 242, conductor 275, switch 255. Conductor 277, switch 251, conductor 279, switch 247 is energized in its normal position to earth.

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Switch 247 in its energized position also connects the corresponding ones Time unit resistors 52 with the circuit, the connection of input terminal 280 via conductor 282, rotary switch 173, conductor 287, time unit resistor 52, conductor 284, switch 247 goes to ground. The fourth switch 248 of the relay 240 leads negative potential to the field effect transistor 32, from the negative voltage source via switch 248, conductor 286 to the drain electrode of transistor 32. Fig. 2 shows that each of the associated relay switches the corresponding relays Connects 241 and 242 in the same way. The names for the hand switches 260, 261 and 262 would be be main exposure, peak brightness exposure and flash exposure in one commercial unit.

As mentioned earlier, the flash lighting creates other characteristics Results during the procedure than the rest of the exposure techniques. Therefore there is another circuit available, essentially consisting of switch 288, relay 290 and relay switches 291, 292 and 293, which are the presetting of the desired density values derived above for flash purposes are permitted.

A manual switch 288 is used to easily switch the device for single exposures in color. For single exposure in color, switch 288 is set to position 295. Because this is a is free contact, the normal circuit is used and every Color is controlled by the individual circuits labeled Main, Peak Brightness, and Flash. If on black /

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.White-work flash lighting is used, switch 288 is set to position 291 and relay 290 is energized from the positive voltage source via conductor 296, switch 288, conductor 297 and 298, via push button 262 to earth. The energization of relay 29O causes relay switches 291, 292 and 291 to pass from their normal positions (FIG. 2) to positions which introduce the above-mentioned combination values for lightning blackening density into the circuit. In flash operation, an inner phototube 24a is used, which is operated by a small incandescent lamp (not shown) in the flash circuit. i

Another subject matter of the invention, the mechanical computer, is designated 340 and shown in FIGS.

The computer is used to calculate and input data for photographic processes. For example, becomes the value of the excess density (De) calculated by hand using the following equations:

Dc = Ds - (0.1 Dh + 0.01 Dh) {

De = Dc - Dsc

Where Ds = shadow blackening density Dh = peak brightness blackening density Dc = copy area

Dsc = grid area

De = excess density

In the schematic representation of FIG. 4, there are three scales. 341, 342 and 343 used; there is a rotating control knob on each

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j 346 and 347 attached. For ease of use, the scales 341 and 342 can be arranged coaxially, but are shown as separate scales for ease of understanding. 4 shows that each of the scales 341, 342 and 343 has identification numbers on the outer edge. The Kennleitzahl on the scale 341 is equivalent to 0.01 Schwärzungsdichtewerten that Kennleitzahl on scale 342 corresponding to O. ₉ l Schwärzungsdichtewerten and Kennleitzahl on scale 343 corresponding to Blitzschwärzungsdichtewerten.

A rotary switch 350 (64 in FIG. 3), which sets the resistor 46 (in FIG. 3) and a cam disk 352, is arranged on the control knob 341. The cam disk 352 (FIG. 5) is designed in such a way that the radial movement of a cam follower 354 is transmitted to a cant gear 360 and 361 through a lever 355 and a spindle unit 356. Tangential movement of the gear 36I relative to the gear 36O rotates a gear 366, and this rotation is transmitted to a pointer 370 through the spindle unit 368. 4 shows that the rotary movement of the scale 342 is transmitted via a spindle 372, a gear 374, gears 36O, 36I and 366, as well as the spindle unit 368 for moving the pointer 37O. In this way, the summation of Dh shown in the formula is obtained since the movement of scale 341, cam 352, cam follower 354, lever 355, spindle unit 356-, gears 36O and 361, gears 366 and 36I, gear 366 and spindle unit 368 only one tenth is as effective to move pointer 370 as rotating dial 342. Rotary switch 377 in FIG. 4 includes switches 65, 67 and 69 of FIG. 3 and is operative with resistors 42 and 48, 43 and 49 or 44 and 50 (Fig. 3) ■

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connected, selects them and sets the changeable capacitor 17 a. A switch 38O includes switches 149, 152, I56 and 158 and is operatively connected to and sets resistors 33a and capacitors 17'a.

To apply the invention, the corresponding time unit values are first derived. The correct values depend on the used Film, chemistry and halftone screen, as well as the lab technician's preferred point size along the gray scale. the Using only the main and flash circuit is sufficient sometimes off. The main exposure time depends on the point size that the photographer uses for the peak brightness area of the original, and the flash time units are set to be the shadow spot size preferred by the photographer result. The peak brightness circuit and thus the peak brightness time unit values are used to change the normal Procedure used. Both the peak brightness and shadow spot sizes remain the same while the peak brightness switching the setting (placement) of the 5055 halftone dot and regulates the midtones accordingly. This technique is called "no-screen bumpjf".

After the correct time unit values for a particular movie, Chemistry and halftone screen are determined, is no further time unit calibration necessary. After that, the same time unit settings are retained and only blackening density deviations, that of the corresponding density of the to be reproduced Depend on the workpiece are changed.

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The density changes are as follows: In the normal process the measured peak brightness blackening value is set on the main blackening scales. As a result, the variable resistor 33 and the variable capacitor in FIG. 2 set. A calculated fourth for excess blackening is then set on the flash blackening scale, whereby the counter was 33a and the capacitor 17a in Fig. 2 are set. Excess density is the difference between the copy density area and the halftone screen area. The copy redaction area is the difference between the main dot size (peak brightness blackening) and measured on the original used the shadow point size (shadow blackening). Another mechanism can be used by dividing the grid area by means of a Slipping clutch is taken as the zero point. If then, as above, the scale is set to the copy area, the rotates Scale and consequently the setting of resistor 33a and capacitor 17ä by an amount corresponding to the excess blackening.

If the "gridless butt" technique is used, the density settings are first determined by trial. As a starting point, it is recommended to subtract 0.3 density from the main exposure (and thereby halving the main exposure time) and adding 0.06 density before the peak brightness exposure time is initiated.

The electrical operation of the invention can be seen from FIG. Blackening and time unit settings are determined as above. The main exposure switch 260 is briefly pressed down by hand.

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pressed, whereby the relay 240 is energized, which by relay switches 245 is held in the energized state. Relay switch 246 and 247 de-energize relays 261 and 262. Switch 247 switches the preset time unit resistor 52 in parallel to timing capacitor 17, which connection via capacitor 17, switch 292, conductor 300, switch 39, conductor 301, conductor 282, Conductor 267, resistor 52, conductor 284, switch 247 to ground. A voltage source negative with respect to earth is connected to the DC source, the field effect transistor 32, applied, where = the current intensity is determined by setting the variable resistor 33. Since the lamps 30 are not yet switched on, the phototube 24 is non-conductive and therefore does not draw any current away. The timing control capacitor 17 is now charged to a predetermined value dependent on the values of the resistors 33 and 52 and ready to initiate the timing cycle.

Briefly pressing the "start switch" labeled switch 213 energizes relay 27 from the positive voltage source via switch 213, conductor 329, resistor 214, conductor 307, conductor 308, i the coil of relay 27, conductor 310, diode 217 to ground. This initiates the timing cycle by disconnecting the charging circuit by opening the normally closed relay armature 39 and energizing relay 221, which turns on the selected lamp (shown schematically at 30). Relay 221 is energized by the positive voltage source through the coil of relay 221, conductor 315, switch 320 to earth. When the lamp is turned on, the phototube 24 becomes conductive and timing begins. According to FIG. 1, the capacitor is discharged

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17 through the phototube 24 which is conventionally connected to a DC voltage source with a polarity which which is opposite for the charge of the capacitor 17. The phototube therefore works as a constant current source, the Current depends only on the high resistance of the phototube 24.

During the current flow through the phototube 24, the potential at point 318 less and less negative. This potential will is applied to the control electrode of transistor 162 via conductor 321. Since the current through the field effect transistor l6l and therefore through resistor 186 because of the forward bias and grounded control electrode of this transistor remains at a constant value, the voltage differential between decreases output terminals 324 and 325 proportional to the decrease the capacitor voltage. When the differential voltage reaches a small negative value (in the millivolt range), this shows the Discharge of the capacitor 17 and therefore the end of the timing cycle. This condition is made by the differential comparator 182, which is connected to the output terminals of the differential amplifier circuit 20 through series resistors 186 and 187 is. As noted, the differential comparator 132 responds to the small negative differential by providing a step voltage output within nanoseconds. This voltage is applied to the control electrode of the controllable silicon rectifier 26 applied across the series resistor 211. When the silicon equivalents 26 ignites, relay 27 is de-energized, while current from positive bus 175, through conductor 327, relay contact 222, Conductor 329, resistor 214, conductor 330, silicon rectifier 26

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flows to earth. When the relay 27 is de-energized, the switch opens 220, whereby the relay 221 is de-energized. This opens the relay switches 222 and 332, whereby the current flow through the Silicon rectifier 26 terminated and the selected lamp 30 switched off will.

Since separate time unit switches are provided for each lamp and all have been preset, it is only necessary to briefly press the switch associated with the lamp to expose the next lamp. For example, to initiate the Spitzenhelligkeits- i of the peak brightness switch 261 exposure pressed. Referring to Figure 2, relay switch 250 would then actuate the relay to ground through the aforementioned circuit, the relay switch

251 would de-energize relay 242; Relay switch 252 then ensures that relay 260 remains de-energized and switches the Peak brightness timing resistor 53 into the circuit; Relay switch 253 applies a negative potential across the field effect transistor 32 to the charging circuit 15. Then repeated a short press of the start switch 213 the above written timing cycle. The flash lamp is in the same Actuated way, the further relay 290 from the positive bus line via the coil of relay 290, switch 288, Conductor 297, switch 262 is energized to ground. By energizing this relay 290, relay switches 291, 292, and 293 are turned in is switched to the aforesaid flash blackening position and the inner phototube 24a is connected to the discharge circuit.

The timing cycle can be ended manually at any time.

209818/0939

This is done by an off switch 335 > which, when pressed, shorts the positive potential on conductor 308 to earth, whereby the relay 27 is de-energized, which leads to the de-energization of the relay 221 by the aforementioned circuit. When the relay 221 is de-energized, the relay switch 332 opens and thus extinguishes the lamp

The mechanical computer is operated as follows: According to FIG. 4, the value of Dsc between pointer 370 and pointer 382 is set on control button 347. For this purpose, a slip clutch (not shown) is provided between button 347 and scale 343. The control knob 346 is turned until the correct value of 0.1 Dh appears opposite the pointer 383 belonging to scale 342? this sets resistors 33 and capacitors I7 and transfers the value of 0.1 Dh to the pointer 370. Then the control knob 345 is turned until the value 0.01 Dh appears opposite the pointer 384 assigned to the scale 3 ^ 1; this sets the switch 350 and the resistor 46 and transfers the value of 0.01 Dh to the pointer 370. The addition of 0.1 Dh and 0.01 Dh has taken place because of the 1:10 ratio of the relative movements of the scales 341 and 3 ^ 2. Then the control knob 347 is turned, as is the associated scale 3 ^ 3 _} so that the value of Ds is opposite the pointer 370. When the control knob 347 was turned, the switch 38O was turned to set resistors 33a and capacitors 17a and the value of De entered into switch 3S0, this value being the difference between Ds and (Dsc + 0.1 Dh + 0.01 Dh) is. While the mechanical computer is shown to be integral with the timing circuitry of the photographic process timer of the invention, it is not intended to be used therewith

209818/0939

restrict. It is emphasized that the computer can also be built as a separate device, and the calculated values up by hand the scales attached to the described timing circuit can be transferred.

Claims

209818/0939

Claims (12)

Patent claims: 1. Photo process timer for continuous tone and halftone processes using light-sensitive emulsions, characterized in that a timing capacitor with a charging voltage source is connected in series *, which in Series with a controllable impedance, which is connected in parallel to the timing capacitor, to the charging voltage of the capacitor to determine, and that in series with the charging voltage source a source to achieve a constant Current is switched through the controllable impedance and that after switching the capacitor to discharge with the help a display device which contains an electrically sensitive element connected in series with the capacitor, an indication is made when the capacitor is discharged to a predetermined voltage. 2. Timer according to claim 1, characterized in that the display device a differential amplifier connected to the timing capacitor to monitor the discharge of the capacitor, a differential comparator connected to the differential amplifier to indicate when the capacitor im is substantially discharged, and has an electronic switching device connected to the differential comparator, which de-energizes a relay to indicate the end of the timing cycle. 209818/093 9 3. Timer according to claim 1, characterized in that the lying in series with the charging voltage source, for maintenance a constant current through the controllable impedance serving source contains a field effect transistor » H. Timer according to claim 1, characterized in that the controllable impedance can be changed linearly in order to change the potential across the capacitor in the same proportion to each setting made, and that a second controllable impedance | is connected to change this current in logarithmic steps, and that several additional timing capacitors are provided, which are connected individually or in parallel to several of the second controllable impedance, whereby the potential to which the capacitors are charged, together with the selected total capacitance, a timing cycle desired duration generated. 5. Timer according to claim 1, characterized in that several J lamps used in photographic processes and a plurality of relay switches associated with the lamps and the Time control capacitor to excite the lamps and to initiate the discharge of the control capacitor as well as with a manual switch for the optional actuation of the relays and thereby optional excitation of the lamps are connected, the electrically sensitive element de-energizes the relay switch when the capacitor discharges to a predetermined value is. 209818/0939 6. Timer according to claims 1 to 5, characterized in that that the controllable second impedance is connected in series with the first impedance and the charging voltage source to the Strom durch.die first impedance to adjust the voltage to which the timing capacitor is charged. 7. Timer according to claim 6, characterized in that the second controllable impedance comprises a resistor network, which is electrically connected to the source for maintaining a constant current is connected, wherein the setting of the second impedance has the consequence that the constant current through the first impedance changes logarithmically. 8. Timer according to claim 6, characterized in that the first the impedance connected in parallel to the timing capacitor is an adjustable resistor, which can be adjusted the voltage across the timing capacitor increases or decreases in direct proportion to the size of the setting. 9. Timer according to claim d, characterized by several additional adjustable resistors, which can optionally be added to or instead of the first adjustable capacitor Resistor can be connected in parallel. 10. Timer according to claim 6, with mechanical i-means for calculating of blackening density values and for setting the second adjustable impedance, characterized in that aese 209Ö18 / 0939 Means multiple input spindles, control buttons on each of the Input spindles, switches for setting the adjustable Impedance operatively connected to each of the input spindles and connection means included for translating from density information derived from the rotation of the control knobs, the connecting means at least Have a gear set on one of the input spindles and at least one cam follower assembly on another input spindle. 11. Apparatus for automatically calculating values used in continuous tone and halftone photo processes, marked by means of several control buttons and scales connected to them with identification codes in blackening units entered on them, several input spindles on the control buttons, one compared to one of the control buttons and associated scale adjustable pointer to display the excess blackening value, the results from the operation of the other control buttons and associated scales, and gears that control the input spindles to translate the blackening information entered in the control buttons connect rotatably with the pointer. 12. Apparatus according to claim 11, characterized by one of the Input spindles attached cam disk with which a cam follower for adjustment after the rotary movement of the cam disk is connected, and by a lever unit that is attached to the cam follower attached and interact with the gears to translate the rotary motion of the cam disk to the pointer. 209818/0939