DE1141532B - System for selecting characters for phototypesetting machines - Google Patents

Description

System for selecting characters for phototypesetting machines The invention relates to a photographic character composer, light typesetting machine and the like, in particular a system for selecting certain characters from a matrix that has a number of through parts of different light transmittance formed characters.

Known machines of this type have a controlled flash light source relatively high light intensity and short flash duration. The light source and the matrix are movable relative to one another in such a way that the light source with the individual characters are aligned in a predetermined order, with one character identifying this character on the matrix for each character Code number is attached, which serves to map the matrix to a specific character to adjust.

Except for these code numbers assigned to the individual characters in the known systems, a marker or start marker is provided on the matrix, from the counting process when setting each individual character must begin. These characters are localized by their during the Scanning process counted circumferential distance compared to this initial marking. It So the selection of each character must begin from this marking, what As a result, there is always only one single character per revolution of the matrix can be selected.

In other known devices, however, the individual code markings must be arranged in a predetermined manner to either a direct To be able to carry out a comparison or a so-called »complementary comparison <c. Otherwise there would be the possibility of an incorrect reading; for example would the code for the number 10 100 also matches the code 10 000, and consequently the latter code must be used in order to avoid misreading are scanned first. As a result, the matrix to set a specific character for each character one full turn return.

The object of the invention is to increase the working speed a phototypesetting machine by improving the selection of the characters accordingly from the matrix effecting system.

According to the invention, the code marking exists for each character from a number of in two rows in one of the recorded at this point Character associated with patterns arranged, pulse-generating characters; it are devices for scanning the two rows in every position for the purpose of determining in what sequence these impulse-generating characters for each character are arranged, provided, and these facilities are provided with separation facilities to distinguish between impulses generated by one or the other series of characters tied together. Furthermore, a selection device for the temporary storage of a one corresponding to the characters and a code between the dialing and the Separation device switched on comparison device to compare the code marking each character, digit by digit, with the one stored in the dialing device Code indication provided, which emits a pulse to the light source as soon as the code marking one of the characters with the code information stored in the dialing device matches.

As a result of this configuration, with the system according to the invention more than one character can be selected during one revolution of the matrix. As a result, this system has a much higher working speed achievable than with the known facilities, which for the reasons described only allow a single character to be selected during each matrix revolution. Since the speed of operation is one of the most important features of a light setting device represents, is by the system according to the invention for the selection of the individual characters the The practical value of the whole setting device increased considerably.

Further features of the invention are based on the in the drawing illustrated embodiment described. In the drawing, Fig. 1 is a schematic diagram of a dialing system according to the invention, Fig. 2 is a partial view the matrix shown in Fig. 1, bearing the individual characters in-enlarged. Scale, Fig. 3 is a schematic representation of a further embodiment of the Invention, FIG. 4 shows a single diagram of the provided in the device according to FIG Correspondence circles and FIG. 5 shows a schematic representation of a further embodiment the invention.

According to the drawing, which shows preferred embodiments of the invention, in particular according to FIG. 1, a matrix disk 10 is provided which is rotatably mounted about its axis 12 and carries symbols 15 which are at the same distance from the axis of rotation 12. These symbols are formed by suitable parts of different light transmittance, so that a light beam which emanates from the spark plug 17 and passes through an illuminating lens 18, when passing through such a symbol, is shaped in such a way that it passes through a focusing system 20, in the form of an image-bearing light beam, which also affects the image size, passes through and impinges on a photosensitive recording material which can be carried by the drum 22, for example.

A change in the light beam coming from the spark gap 17, the relatively high light intensity and short duration, can be done by twisting of the disc, which makes successive symbols in the possible path of the Light beam, and by precisely controlling the frequency of the light source, d. H. So the spark gap 17, certain, desired images of the symbols can projected onto the photosensitive material, these one after the other to hold onto the photosensitive material. It can be a suitable device provided to the successively projected images of the symbols in certain to arrange mutual distances, for example such a device, as described in detail in U.S. Patent 2,966,835.

The invention relates in particular to a device for determination the time at which a certain symbol, for example by a corresponding Binary code number is fixed with the optical system exactly aligned so that this Icon can be photographed. According to the invention, each symbol is followed by a Identified binary code number that is recorded on the matrix disc 10 as a character is, at a predetermined spatial distance from the symbol to which it assigned. A seven-digit binary code is only shown as an example.

Is shown in FIG. 2, for example, when the code number 1 000 000 corresponds to the letter A, the numeral "1" in the code number indicating mark are immediately following a certain radial distance from the center line of the disc 10. This marking 30, six other characters 32 are provided, all of which lie on the same radius from the center line of the disc 10, which is different from the radius on which the marking 30 is recorded. In other words, all markings that represent the number "1" are at a different distance from the axis of rotation than the markings that represent the value "0". The last of the seven marks, designated 32 ', is a certain distance from the letter A, and consequently the position of the mark 32' can serve as an indication of the exact alignment of the letter A with the optical system.

Similarly, the code for the letter B may be 0 100 000 and the code for the letter C will be 1100000, etc., as can be seen from the consideration the Fig.2 results. Each set of code marks is opposite the neighboring ones Sentences separated by an elongated marker 35, which extends through the two radial zones both the "1" marks 30 and the "0" marks 32 extend. All these Markings are preferably formed in such a way that they have a different light transmission own as the disk background. For example, the pane can be opaque and the markings can be made translucent or vice versa.

As FIG. 1 shows, those surfaces of the disk in which the two radial zones lie are illuminated by light sources 38, from which the light beams pass through suitable lenses 39, and these light beams are passed through the parts having a different light transmission in the Code zones interrupted to generate pulses. On the other side of the pane 10 is a first photocell PC. which is aligned with the zone of the disc in which the markings 30 appear, and in this way pulses emitted by the photocell PC are an indication that an "1" appears in a certain identification code. In the same way, a photocell PC is placed opposite the zone bearing the zero markings 32, and the pulses emitted by the photocell PC indicate that the code contains a "0". The output of the photocell PC is fed to a suitable trigger circuit 42 via a line 40 , and the output of this trigger circuit is connected via a line 43 to a separating pentode 45, in particular to the first or the control grid 45 G1 of the same, namely via a capacitor 46 This grid is normally biased to interrupt the voltage provided by resistor 47, which is connected to a suitable negative potential power source, while cathode 45C is grounded as shown.

In the same way, the output of the photocell PC is fed via the line 50 to a trigger circuit 52, and the output of this trigger circuit goes via the line 53 to the control grid 55 G1 of a pentode 55, namely via a capacitor 56. It is the same Grid 55G1 placed through resistor 57 under negative bias.

The anode circuits of the pentodes 45 and 55 are connected to a common output 60 which forms the input of a semi-stable flip-flop circuit 62. In this way, the delivery of a pulse from one of these pentodes due to their instantaneous conductivity causes the state of the flip-flop circuit 62 to be reversed. As the upper right-hand part of FIG suitable circle for temporarily storing a binary code number corresponding to the symbol to be selected by the disc 10. The selection circuit can be designed in such a way that it is fed with the output of a suitable encryption device and is thus controlled directly from a keyboard, as is described in German patent specification 1055 955; the dialing circuit can also be controlled from an encrypted recording, for example from a perforated or magnetic tape.

The output 66 of the selector circuit 65 is semi-stable with a number of Selector flip-flop circles 70 to 76 connected, which are independent of each other and individually under the control of the voter output. As a result, anyone can of the flip-flop circuits 70 to 76 independently of the other circuits by the dialing circuit can be set to »0« or »1«. The flip-flop circles 70 to 76 accordingly a series of double triodes 80 to 86 are provided, and the first anode each of these double triodes, labeled 80P1, 81P, etc., is common to one Output line 88 connected to a voltage sub-circuit with a load resistor 90, a partial resistor 92 and a negative bias resistor 93 leads. As As shown in the drawing, resistor 90 is on one side with the anode connection lead 88 and the partial resistor 92 and on its other side with a positive current source connected by about 225 volts. The negative bias resistor 93 is on one side Side with a negative power source, say -75 volts and on his other side connected to the partial resistor 92 and the output line 95, the The separation pentode 55 is connected to the grid 55 G2.

The other anodes of the double triodes, labeled 80P2, 81P2, etc. 80 to 86 are connected to a different voltage sub-circuit via a common anode line 98 which consists of resistors 100, 102 and 103, which are in the same Manner as the voltage sub-circuit 90, 92 and 93 are connected and connected. An output line 105 is between the resistors 102 and 103 on this voltage sub-circuit and connected to the second control grid 45G2 of the separation pentode 45.

Each of the flip-flop circuits 70 to 76 has two output lines, the conductive or non-conductive depending on the state of the associated flip-flop circuit are. For example, the semi-stable flip-flop circuit 70 has an output line 700, which is positively biased when the flip-flop circuit is in the "0" state, and a second output line 701 which is positively biased when the flip-flop circuit 70 is in its "1" state. The line 700 is with the first control grid 80 Gl, a tube 80 and the line 701 to the second control grid 80 G2 of the same Tube connected.

In the same way, the output lines 710, 711; 720, 721; 730, 731; 740, 741; 750, 751 and 760, 761 with the grids 81 Gl, 81 G2; 82 G1, 82 G2, etc. are connected, and consequently the grids of the double triodes are adjusted in accordance with the state of the individual semi-stable flip-flop circuits 70 to 76. In the lower right part of FIG. 1, a beam switching tube 110 is shown schematically. This tube corresponds to a construction as described, for example, in US Pat. No. 2,721,955. To clarify the representation, the devices for generating the magnetic field around this tube are not shown. However, these agents are well known in the specialist field and are also described in US Pat. No. 2,721,955.

The beam switching tube 110 has a common cathode 112, which can be connected to a negative voltage source of, for example -75 volts, and a number of collecting anodes 120 to 129. For each collecting anode, a corresponding beam deflecting element 130 to 139 is provided, as well as corresponding beam switching elements or grids 140 to 149. The switching grids 140, 142, 144, 146 and 148 are connected to one side of the semi-stable flip-flop circuit 62 via a common input line 142 and a capacitor 153. The odd-numbered switching grids 141, 143, 145, 147 and 149 are connected to a common control line 156 which is connected to the other side of the flip-flop circuit 62 via the capacitor 157. The remainder of circle 158 forms a conventional circuit or ladder for precisely biasing the odd and even control grids. All switching elements with the exception of the first element 130 are connected to a common load line 160 via the suitable resistors shown; the line 160 is in turn grounded via a load resistor 162. As a result, the switching tube works with the relatively small voltage difference of less than 75 volts. The first element 130 is connected to the load line 160 via an additional resistance-capacitance blocking circuit 163, to which a reset pulse is fed from a suitable reset circuit 165. A pulse emanating from this circle has the effect at any point in time that the electron beam is collected by the first collecting anode 120, disregarding the other collecting anodes, in that the potential of all anodes is reduced below the interruption voltage, after which all collecting anodes 131 to 139 before the Anode 130 come to earth potential, namely as a result of the trap circuit 163, whereby the beam on the first collecting anode 120 comes to stick. The last two collecting anodes 128 and 129 are not used in this circuit and are therefore directly earthed via suitable bias resistors 167.

The collecting electrode 137 is directly connected to an output lead 170 connected, which is connected to the spark control unit 172, the supply of electrodes 17 controls. The pulse appearing at the collecting electrode 137 increases on quickly and therefore ensures a practically instantaneous signal to the spark control unit 172 when the electron beam is on for the seventh time the collecting electrode 127 is switched. This collecting electrode is via an output lead 175 connected to an amplifier 176, which via a reset line 177 a Reset pulse for the purpose of resetting all flip-flop circuits 70 to 76 to the returns the same status, for example to "0". By doing that for the dialing flip-flop circuits such a separate reset output is provided, the reset circuits isolated from main output line 170 and can therefore use the main output pulse to the spark control unit neither amplify nor possibly weaken.

Each of the first seven collecting electrodes 120 to 126 is connected by respective output lines 180 to 186 to the cathodes of the double triodes 80 to 86, so that each of these output lines 180 to 186 of the beam switching tube 110 controls the operation of an associated double triode 80 to 86.

A suitable summing circuit 190 receives input pulses from both photocell triggering circuits 42 and 52 via the input lines 192 and 193. As is usual with such summing circuits, when the summing circuit 190 receives an output pulse from both triggering circuits, the summing circuit 190 gives an output pulse via the output line 195 for the purpose of resetting of the circle 165.

The operation of the system is as follows: Assuming, for example, that the letter A is to be selected and photographed and that the code character for A is the number 1000000, as described in connection with FIG Selection circuit 56 initiated, which in turn sets the flip-flop circuits 70 to 76 in such a way that the first circuit 70 is set to "1" and the other circuits to "0". As a result, the grid 80G is positively biased. If it is further assumed that the long reset mark 35 (FIG. 2) immediately preceding the code mark identifying the letter A has just passed the photocells PC and PC, the summing circuit 190 has a pulse to reset the circle 165 emitted, which in turn has caused a return of the electron beam in the beam switching tube 110 and the collection of the electron beam on the first collecting electrode 120, whereby the cathodes of the double triode 80 have been connected to the -75 volt power source.

Then the grid 80 G, has been positively biased, while the grid 80 G1 remains negative, as described above, and as a result the right part of the tube 80 becomes conductive and the voltage divider formed by the resistors 100, 102 and 103 becomes A signal is fed through the line 98, whereby the output line 105 is brought to a higher or more positive potential. At the same time, the relative movement between the disk 10 and the reading device (formed by the photocells PC and PCo) is continued. This relative movement is preferably continuous and is brought about by the fact that the matrix disc is moved in relation to the stationary photocells.

As FIG. 2 shows, in this way the first or "1" marking 30 causes the photocell PC to emit a pulse to its associated trigger circuit 42 , so that the grid 45 G ,, via the line 43 and the capacitor 46 is immediately biased positively. It should be remembered that an output signal is now generated in line 105, which is connected to grid 45 G, and as a result the separating pentode 45 becomes conductive and the semi-stable control flip-flop circuit 62 is via the Line 60 is supplied with a pulse. The impulse via the line 60 is only very brief, because the grid 45 G, as a result of the sharp impulse of the photocell PC conducted via the capacitor 46, is positively biased only for a very short time. With regard to the next selection flip-flop circuit 71, its associated comparison triode 81 and the associated collecting electrode 121, the pulse controlling the flip-flop circuit 62 causes the electron beam in the beam switch tube 110 to be directed onto the second collecting electrode 121 in accordance with the change in state of the flip-flop circuit 62, which switches the polarity of the switching grid via a conventional switching circuit 158. This biases the even grids negatively and biases the odd grids positively via line 156. The cathodes of the tube 81 are now connected to the negative voltage source via the beam switching tube, and since the flip-flop circuit 71 is set to "0" in the example shown here, the grid 81 G is positively biased so that a signal through the conduit 88 .dem the resistors 90,92 and 93 having voltage dividing circuit is supplied, and an output signal is the Trennpentode 55 supplied via line 95 to the grid 55G2. Since, as FIG. 2 shows, the next code marking in the code character corresponding to the letter A is the marking "0", the pulse emitted by the photocell PC through its trigger circuit 52, its output line 53 and the capacitor 56 causes the grid 55 G is positively biased for a period of time which is sufficient to supply another pulse to the control flip-flop circuit 62 via the output line 60. Accordingly, the electron beam travels in the beam switching tube to the next collecting anode 122, and the sequence of the individual processes described above is repeated.

In this way, the interrupter 110 in conjunction with the subsequent effect of the double triodes 80 to 86 a sampling of the in the flip-flop circuits 70 to 76 set code number, digit by digit, and the delivery of an output signal each of these flip-flop circuits via one of the lines 95 and 105, which indicates whether the number checked in the flip-flop circle is "0" or "1".

At the same time, the photocells PC and PC scan the code characters on the disk in order to determine the characteristic code number that passes these photocells between two successive reset markings 35 place by place. The reset markings 35 synchronize the beam switch tube 110 with the photocells or the reading devices, and as a result, if the first digit of the code number read and the first digit of the correspondence is determined by the dialing device in the flip-flop circles 70 to 76, over line 60 emits an output pulse which causes control flip-flop circuit 62 to switch the electron beam to the next collecting anode 121. If the second marking of the code character read corresponds to the setting of the second flip-flop circuit 71, the separating circuits (the pentodes 45 and 55) again emit a switching pulse by which the electron beam is switched to the third collecting anode 122, and this sequence repeated. If at any point during this comparison operation, which is continuously repeated for each code character on the matrix disc, there is a mismatch, the beam switch tube 110 is not indexed during this one step and falls out of phase with the scanned code. In order for an output signal to be generated on line 170 that triggers spark control circuit 172, the isolation circuits must find seven matches; In other words, they must find the code number set on the dialing device by comparing each digit of the same with each digit of the scanned code characters.

If a match is found, the electron beam will switched to the eighth position, namely on the collecting electrode 127 and the Above mentioned sharp, rapidly rising impulse runs from the deflector 137 via line 170 to spark control circuit 172. Accordingly, no coarse and fine control present as used previously, but in place the invention provides for a comparison of the desired code number with all of them Code characters on the matrix disc, each character independent of the other, and as soon as the code designation matches the one set on the dialing device Code is found on the disk, the light source or spark gap is instantaneous or ignited within a very short, predeterminable time interval that is independent is of some fine control, and now the corresponding selected icon photographed. At the same time, the generated at the collecting electrode 127, slower growing pulse through line 175 and amplifier 176 to in the flip-flop circles 70 to 76 to delete the code number just set and Bring these circles back to their original state to help them choose of the next desired symbol are ready to accept another code number. It should be noted that the device described above is independent is of any index or home position on the matrix disc; Consequently can with this system during each cycle of a relative movement between the matrix disc and the code reader and the optical system a number of symbols are selected, of course within the limits of the system, new selected ones Record code numbers and reset to its original state.

3 and 4, another embodiment of the device is shown in accordance with of the invention shown. Since the matrix disk, the optical and the recording system, the reading device and the symbol selection device completely identical to the corresponding devices shown in Fig.l, these parts were with the same reference numerals. The symbol selection circuit 65 is via its output 66 connected to the semi-stable flip-flop circuits 210 to 216 that this can be set to the binary code number that is set on the matrix target. Each of these flip-flop circles can have the usual Eccles-Jordan circle, details of which are shown for flip-flop circuit 210 in FIG.

This circle has a double triode 217, each of which has one or the other side can be conductive, depending on the state on which the circle is located is set. Accordingly, as is well known, the grid 217G1 will be positively biased when the left side of the tube conducts what the State) de corresponds to the flip-flop circle, and vice versa the grid 217 G2 positively biased when the flip-flop circuit is in its »0u state. Of the The flip-flop circuit can be set by a pulse emitted by the control tube 220 which in turn is controlled by the selector circuit 65 (for example on the in U.S. Patent 2,944,472).

The control output pulses of the flip-flop circuit 210 (and in a corresponding manner of the flip-flop circuits 211 to 216) run through the lines 222 and 224, which are directly connected to the two grids of the tube 217 and correspondingly biased. The comparison circles are designated in total by the reference numerals 230 to 236 in FIG. 3, and each of the comparison circles is connected to an associated flip-flop circuit 210 to 216 in the same way as is shown in FIG. The comparison or isolation circuit 230 has a pair of pentodes 240 and 242. To simplify the illustration, the screen grids of these tubes are not shown in the drawing because they are not part of the control of these tubes. A common anode output line 245 is connected to all of the anodes of these isolation pentodes in all of the isolation circuits 230-236, and this line leads to the semi-stable beam steering flip-flop circuit 250 (FIG. 3).

Line 222 is connected to one control grid 240 G1 of tube 240 and line 224 is connected to grid 242G1 of tube 242 . The other control grid 240G2 and 242G2 are biased in a similar manner via bias resistors 243 is negative, and the grid 240 G, is connected in such a way that a pulse is to him via the capacitor 252 from the photocell Kippkreisverstärker 42 supplied which is in turn pulses by the photocell PC , be forwarded. In a similar way, the grid 242 G2 is connected in such a way that the pulses supplied by the photocell PC are fed to it via the trigger circuit amplifier 52 and the capacitor 253.

A beam switching tube 260 is also provided, its beam switching circuit 262 is under the control of the flip-flop circuit 250, as shown in FIG is, so that each pulse on line 245 is a switching action of the flip-flop circuit 250 which in turn biases the grids 270 to 279 changes to the electron beam successively on the collecting electrodes 280 to 289. Each of the beam deflectors 290-299 is over an associated resistor grounded. The first seven collecting electrodes 280 to 286 are connected to the seven comparison outputs 300 to 306, which in turn lead to the corresponding comparison or separation circles 230 to 236, and the corresponding line from the beam switch tube 260 is at every moment the cathodes of both separation pentodes are connected within the relevant separation circuit, as shown in FIG.

According to FIG. 3, the outputs of the two trigger circuit amplifiers 42 and 52 are connected via lines 308 and 309 to a conventional summing circuit 310, the output of which is fed to a suitable phase inverter 312, and the output 313 of the phase inverter leads to a reset circuit 315 for the beam switch tube, and via the branch line 316 causes the output of the phase inverter to reset the flip-flop circuit 250 to the desired state. The output 318 of the reset circuit 315 is connected via the capacitor-resistor blocking circuit 319 to the deflecting elements of the beam switching tube in order to reset the electron beam to the first collecting element 280 by lowering the voltage of all deflecting elements below a predetermined separation potential. The reduction of the potential of the deflection element 280 to a positive voltage takes place more slowly as a result of the capacitance 319 ′ switched into its supply line, as a result of which the electrode beam remains stuck on the first collecting electrode 280 during this process.

The operation of this embodiment of the invention is substantially similar to that of the system described above. A desired code number is set by the selected symbol in the flip-flop circles 210 to 216, and the connections between these circles and the isolating circuits 230 to 236 cause the positive bias of one or the other of the control grids 240 Ga or 242 G1 in the corresponding separation circuit, whereby one or the other of the separation tubes 240 and 242 is prepared for the conductive state. While the beam switch tube is in its first setting, the cathodes of the separator tubes in circuit 230 are connected to a negative voltage, and when the first digit of a complete code character is scanned on the disk, a pulse from one of the photocells PC, or PC, arrives.

Based on the same example as in the first embodiment of the invention, in which the number 1000000 is assigned to the letter A, the pulse coming through the capacitor 252 causes an instantaneous positive bias of the grid 240G2, and as a result of the setting of the flip-flop circuit 210 in its "l" state, the grids 217G ,. and 240G1 are positively biased, and an output pulse occurs on line 245 and is fed to flip-flop circuit 250 through capacitor 320. This in turn causes the electron beam in the beam switch tube 260 to be passed on to the next collecting element 281, and the same comparison between the second digit of the code and the code digit in the flip-flop circuit 211 follows. As soon as a match is found, another pulse travels over the output line 245 to the Fhp-Flop circuit 250 and so on.

However, if there is a pulse in any of the isolation circuits 230 to 236 is initiated by the photocell reader from one of the photocells, while the opposite separating pentode by the corresponding dialing flip-flop circuit is set conductive, d. H. if, in other words, there is no agreement, so the beam switch tube 260 falls out of phase with the matrix, and the required seven output pulses on line 245 are not achieved. Accordingly the electron beam does not reach the eighth collecting element 287. However, if a complete agreement of all positions is determined, the remains Electron beam hang on this collecting element, and a pulse runs over the Output lead 325 to spark control circuit 172 so that between the electrodes 17 a spark is drawn which illuminates the desired selected letter. At the same time, a pulse is passed on via line 327 to the dial flip-flop circuits 210-216 to prepare for the inclusion of a new code number from the constituencies.

Another modified embodiment of the invention is shown in Fig. 5, the same reference numerals being used again for the common parts have been as in Fig. 1, namely for the matrix disk, the optical and the Recording system, the code reader and the symbol selector. The output of the selection device 65 controls the individual setting via the line 66 seven semi-stable flip-flop circles 410-416, and each of these circles is with connected to an associated isolating circuit 430 to 436, which is of the same construction is as shown in Fig. 4, and is with the associated flip-flop circuit also connected in the same way as with reference to FIG. 4 was described above.

Similarly, the outputs of the trigger circuit amplifiers 42 and 52 are connected via lines 437 and 438 to each of the isolation circuits. An “Odere isolating circuit 450 receives pulses from each of the trigger circuit amplifiers 42 or 52 and, as the name suggests, this circuit feeds a pulse from one of the photocells PC, or PC, to its output line 453 via a delay circuit 452, through which the pulses are passed to a semi-stable control flip-flop circuit 455 . The opposite sides of this control flip-flop circuit are connected to the odd-numbered and even-numbered switching grid elements 460 to 469 of a beam switching tube 458 via a conventional switching circuit 457. The collecting anodes 470 to 476 of the tube 458 are connected to the separating circuits 430 to 436 in order to effect a successive activation of these separating circuits for the purpose of comparing the code set in the dialing circuits with the code characters read from the matrix disc 10.

The pulses from both photocells PC,. and PCo, but a pulse continues through the output 486 of this circle only when the elongated reset markings 35 (Fig. 2) pass both photocells. Such an output pulse runs via a phase inverter 487 to the output line 490, which is connected to the reset circuit 492 for the beam switching tube 458, as well as to a reset line 493 for controlling the Fhp-Flop circuit 455. As a result, a pulse coming from the summing circuit 485 causes both the resetting of the control flip-flop circuit 455 to a predetermined state and the resetting of the beam switching tube 458 in such a way that the electrode beam is directed onto the first collecting anode 470.

The output of the isolating circuits 430 to 436 is a common anode line 500 which is connected in parallel to all anode circuits of all pentodes in the isolating circuits, in the same way as the line 245 in the embodiment according to FIGS second beam switching tube 505 is provided, which is connected to earth and a positive voltage, and the switching grid elements 510 to 519 of this tube are connected to a conventional circuit 520 which is controlled by a further control flip-flop circuit 525, which receives the output pulses of the Separator output line 500 are fed. The switching grid elements 510 to 519 are connected in the usual manner by lines 526 and 527 in such a way that the odd-numbered and even-numbered switching grids are connected to lines 526 and 527, respectively.

A reset circuit 530 is connected to the beam deflectors of tube 505 in the usual manner; An actuation pulse is fed to this circuit via line 532 from the phase reversal output 490 in order to reset the beam switching tube 505 and direct the electron beam in this tube onto the first collecting anode 540. All collecting anodes 540 to 549 are connected to a positive high voltage source via load resistors. The collecting anode 547 is also connected to the output line 550, which is connected to the spark control unit 172, so that after the switching tube 505 has been reset to its starting position, a total of seven pulses must have arrived in order to cause the flip-flop circuit 525 to that the electron beam in the tube 505 is directed to the collecting electrode 547, which results in the delivery of a pulse to the spark control unit 172 and thus a photograph of the selected symbol. In addition, a reset pulse runs from the output line 550 via the line 552, by means of which the flip-flop circuits 410 to 416 are returned to the desired initial state.

The mode of operation of the system shown in FIG. 5 results from the description of the exemplary embodiments described above, so that no detailed description appears necessary. It can be seen that the separating circuits 430 to 436 are actuated one after the other by the beam switching tube 458 and the binary code numbers set therein by the photocells PC, and PC, compare digit by digit with the code numbers in the selector flip-flop circuits 410 to 416 have been set by the selection circuit 65, If the read code character in every position matches the code set in the selection flip-flop circuit, the control flip-flop circuit 525 receives a total of seven output pulses, and the Beam switching tube 505 is switched step by step until the electron beam strikes the collecting anode 547, so that a pulse causing the generation of a spark is emitted via the output line 550. If at any time during the reading of the code characters a mismatch is found between successive reset marks 35, the beam switch tube 505 will fall out of phase with the system. Less than seven pulses are then fed to the control flip-flop circuit 525 before the next reset marker 35 causes a pulse to be passed on via the summing circuit 485, in this case both the beam switching tubes 458 and 505 and both control flip-flops are Flop circuits 455 and 525 reset to their original state without a pulse being supplied to the spark control circuits.

Thus, the operation of each of the systems described above is such that a code number set in a series of dial flip-flop circuits Place after place with each of the code marks on the disk, each of them one of the symbols carried by the disc is identified, compared, wherein the disc for the purpose of successive scanning of all code characters or numbers is moved past a photocell reader on the matrix disc. This Comparison can be made directly, especially in the case of binary code systems, d. H. "1" for "l", or also complementary, d. i.e. an output signal is given, when the reading device has the complementary number of those set in the dialing device Code number. As is well known, this can be achieved in that the separating circuits only emit signals that switch the electron beam when Complementary digits found in the dialing flip-flop circles and in the reading device will.

For the purposes of the foregoing, the term "agreement" means as it has been used throughout the description, either stating the same Digits and codes or complementary digits and codes. As soon as at If a mismatch is found at any point, the system falls out of phase with the disc because there is no match indicating impulse, and no output pulse is sent to the spark control unit for this character. Rather, the system is reset to scan the next character, etc., and as soon as a complete agreement of all places is determined, an output pulse goes directly to the spark control unit in order to actuate it and photograph the selected letter. These systems can therefore with work relatively high speed and can work during each Rotation of the disc in relation to the photocell reader more than one symbol taking photos.

The devices described above are preferred embodiments the invention. However, the invention is not limited to the details of these devices limited, but rather deviations from these details are possible, without leaving the inventive concept outlined in the claims will.

Claims (7)

PATENT CLAIMS: 1. System for selecting characters for photocomposing machines with a matrix that has a number of through parts of different light transmittance formed characters, and a controlled flash light source relatively high light intensity and short flash duration, which are so movable relative to each other are that the light source with the individual characters in a predetermined order comes to align, with one of these characters on the matrix for each character identifying code number is attached, characterized in that the code marking for each character from a number of in two rows in one of these Place recorded characters assigned patterns, impulses generating characters and means for scanning the two rows in each position to determine the sequence in which these pulses generate Characters arranged for each character are provided, these facilities with separators to distinguish between one or the other series of characters generated pulses are connected and a selection device for temporary storage a code specification corresponding to one of the characters as well as one between the Dialing device and the separating device switched on comparison device for comparison the code marking of each character, position for place, with the code information stored in the dialing device, which sends a pulse to the light source releases as soon as the code marking matches one of the characters in the dialing device stored code specification matches, are provided. 2. System according to claim 1, characterized in that a device for reading the code markings each character during the relative movement between the matrix and the light source it is provided that the comparison device via input lines with this Reading device and the selection device is connected and controls a device, each time there is a match between individual digits of the stored code and the read code mark emits an output pulse that furthermore a Step switching device is provided, which one of the number of digits of the code marking has at least the same number of stages and with the output of the comparison device is connected in such a way that a pulse in this output causes the Switching device by one step for each output pulse indicating a match causes, between the last stage of this tap changer and the Flash source is connected so that the flash source is turned on is switched over as soon as the tap changer is switched by one complete cycle has been, whereby a match between the stored code indication and the code mark of the selected character is displayed. 3. System according to Claim 2, characterized by one connected to the tap changer Resetting device for resetting the same to the first stage after reading every code mark of every character. 4. System according to claims 2 and 3, identified by binary number code characters on the matrix for each character, where each number of the code marking is represented by a series of pulse-generating characters is formed during the relative movement between the light source and the matrix are scanned in succession and each character generating a pulse in a of two rows, which indicates whether the relevant position is a "1" or a "0" is set up the selector to store binary code numbers and reading means for scanning each of the two possible positions of each Digit of each number on the matrix is provided. 5. System according to claims 1 to 4, characterized in that the stored binary code number digit by digit is compared with the read binary code numbers on the matrix disc and the Comparison means an output signal for each match between a Digit of the stored number and the corresponding digit of the number read off emits and that the tap changer emits an output pulse as soon as all Digits of the preselected number with the digits of the number read on the matrix to match. 6. System according to claim 4 or 5, characterized in that by the light source the individual selected characters one after the other on one common optical path are projected and that one of the number of locations The number of semi-stable flip-flop circles corresponding to the code characters is provided is, with which a selector for the individual setting of the flip-flop circles corresponding states are connected to the digits of a selected code number, and that normally ineffective circuits between each of the flip-flop circuits and the separating device for conveying the setting of the individual flip-flop circuits are provided with which switching devices are in operative connection for the purpose successive individual actuation of these circles to compare the setting of each flip-flop circle with a corresponding digit pulse, with between the Isolating device and the switching device there is an output pulse connection to switch the switching device from one of the normally ineffective ones Circle to the next upon finding a match between a digit pulse and the state of the corresponding flip-flop circuit and one on the consecutive Actuation of all normally ineffective circles responsive device is provided for putting the light source into operation. 7. Device according to one of claims 1 to 6 for determining the setting of certain code markings on a component on which different code markings are stored in different places. B. Apparatus according to claim 7, characterized in that the code markings are recorded in the form of binary numbers. 9. Device according to one of claims 1 to 8, characterized in that a device for resetting the comparison device after reading each number which does not match the number set in the selection device is provided. 10. Device according to one of claims 1 to 9, characterized by a device for resetting the selection device to a certain initial state upon receipt of an output signal. 11. Device according to one of claims 7 to 10, characterized by a reset device connected between the step switching device and the selection device for deleting the number stored in the selection device after this number has been found on the component carrying the series of such binary numbers. 12. The apparatus according to claim 11, characterized by a device for resetting the comparison device after scanning all digits of a number without determining a complete match. Contemplated publications:. USA. Patents No. 2,714,843, 2,775,172, the 2,790,362th contemplated prior patents German Patent No. 1 055 955th.