DE963118C - Process to bring the lines to be set with a light typesetting machine with types of different font sizes to the same length - Google Patents

Description

Method of using a phototypesetting machine with types different To bring the lines to be set to the same length. The invention bertri, fft a. Method of aligning the lines of a photographic. Typesetting machine, and in particular, in machines with an adjusting device and a counting and Spoke work to store the width. the types and to make the invoice for determining the additional spaces required for adjustment, which between. Words or types are arranged to make all lines the same To bring length.

It is clear that the guys. of each, alphabet as it is a different one Width, require different distances on the film. Man. can assume that the space required for a given type is given by the product of two factors is represented by which. the one of the for the type expressed in units required space, while the second is a coefficient which is the width or corresponds to the font size with which the redrative width of each Type of the alphabet. multiplied to get a number, whichever's width in units of length corresponds to the type in the desired font size.

Object. of the invention are methods and apparatus for in; to mix types of different font sizes on the same line without the adjustment to affect- The procedure consists essentially in that the length of a row with types of different font sizes is measured by giving each type a is given width expressed by a number, and leave that number with a through the thick or the. The font size of the type. Coefficients multiplied the product obtained for the purpose of its use in connection with the Adjusting mechanism 2o is stored in a counter and storage mechanism 24.

According to the invention, coding devices are used for this purpose with a keyboard for the numerical representation of the relative width of each type and a multiplier which is the product of the relative latitudes and the above coefficient of the font size in the storage unit.

Another characteristic of the invention relates to a registration device, which is controlled by a codification system, as well as means for sequential Adjustment of the types: on a photosensitive sheet or film accordingly the messages registered in the registry and a second codification system, its coefficient changed by the messages registered in the register can be and which is used to control the advancing device of the film.

The invention is as follows. by way of example with reference to the drawings explained. Figure z is a diagram of one of the features of the invention having photographic typesetting machines; Fig. 2 is a. Diagram for clarification certain mathematical relationships; Fig. 3 shows an application of the F ig. 2; Fig. 4 shows the circuit. an embodiment of a multiplier and storage unit; Fig. 5 and. 6 show a second embodiment of a multiplier; Fig. 7 shows an embodiment with eight relays; Fig. 8 shows an embodiment with a rotatable disc; Fig. 9 shows an example of an electronic tube circuit; Fig. Ro shows an embodiment of a generator. for generating groups of pulses; Fig. R r shows an example of the circuit of the multiplier.

Fig. R shows the overall arrangement of one of the features of the invention having photographic typesetting machine. However, the invention is not limited to that shown arrangement limited.

A keyboard 2 which is similar to that of an ordinary typewriter is, with a set of 4 permutation bars, is the one commonly used in telegraphy the type used. The permutation bars are with the. Keyboard keys coupled in such a way that they close electrical circuits which serve as the multiplier 6. and lead to a register 8 or 1o, which are used alternately .. The registries can, for. B. have rows of pins, e.g. B. eight for each Type in, the example described, which is optional, by hammers accordingly the width allocated to each type can be indented, as well as means, which determine which pins have been pressed in for transmission. The circuits comprise eight conductors to which a supply voltage according to one of the depressed: Key corresponding code character is created. One connected to the multiplier 6 Set of four ladders. r2 is connected to the permutation bars. and receives current pulses according to the values of the relative width of the type, which expediently in a binary system. In. the example chosen is the greatest relative Value limited to 15 while. the smallest value is o. If one of the wires z2 is excited, this corresponds to the emission of an r in the binary system and; one o when he's not aroused.

In the example described, a complete line is first registered in the registration unit 8, and then the following line is registered in the registration unit ro, while the registration unit 8 is connected to a reading unit 14. becomes., with the help of which the registered line. is photographed in the form of adjusted types. So while a line is being registered, the conductors 12 and one of the registration mechanisms 8 or ro receive successive groups of pulses: from , dien. Permutation bars, each group of impulses representing in a binary code the relative width of the selected type. In addition, the register is connected via four additional conductors 16, whose rides: Help the widths of the types are marked. A coded message representing a font size or a change in the number of points can be registered while a line is being recorded in order to be used later for changing the font size of the types in the course of a line.

The keyboard 2 is above the space key with a word counter 18 connected, via which the adjustment mechanism 2o the number of spaces in the line receives. The type counter 22 transmits to the adjustment mechanism in a corresponding manner the number of types of a line, if the line. by inserting the, spaces should be adjusted between the types.

Damfit the lines, can be adjusted, the register during the set that of the accumulation of the widths. messages corresponding to the types and the spaces. From the total value of the width, the line deficit can be derived, ie the additional space that has to be inserted between the words or types in order to. adjust the lines. This message is received by the storage unit 24. According to the invention, the storage unit 24 can e.g. B. be a binary counter with a certain number of stages, eight in the example described, each stage can have two positions. Set of conductors 12 a pulse set to the multiplier. Furthermore, voltages applied to the multiplier are given by a set of. Ladders 26 created by means of a font size selector 28, with whose H@i.lfe the operator. can choose a coefficient for font sizes between i and 15. A set of eight conductors Ei, E2, E 4, E 8, E 16, E 32, E 64 and E 128 connects the multiplier 6 with each of the eight stages of the storage system 24.

The memory unit 24 thus receives successive groups of voltages and pulses via the conductors E i to E 128 and stores the total value of the widths of the types forming the line, taking into account the change in font size made by the operator at any point in the line could be.

The line is transmitted in letters, where z. B. each type is projected onto a light-sensitive surface by means of a type carrier disk. A carriage 30 carrying the film moves accordingly. the width of the type. To the. Places at which the additional spaces are inserted for adjustment. must, an additional adjustment of the film carrier carriage.s.3o is effected by the adjusting mechanism. In the example shown in Fig. I it is assumed that the type of photography is carried out by a photographic unit 32 which works together with the type carrier disk and is controlled by a decoding device 34. The deciphering device receives coded pulses from the unit 14 for the transmission of the register which, for each type, scans the pens which have been pressed in during the writing.

The reading unit 14 is also connected to a multiplier 36, which can be designed like the multiplier 6 and. so in binary form indicates the relative width of each type. At the same time, a conductor 38 feeds the font size selector 48, which via a conductor 16 through in, your registry stored signals is controlled. Assuming that the multiplier 36 is designed so that it displays the results in binary counting. a set of Ladders 42 passes, these conductors are in two groups. divided, of which the group 44 to a variable switching mechanism 46 and, the group 48 to one another variable derailleur 5o leads. The variable derailleurs allow Adjustments to get what the binary count through the wires "44 and 48 sent values. correspond.

The variable switching mechanism 46, which is connected to a transmission 52 with the gear ratio i: 16, and the variable switching mechanism 50 work on an addition. Verk 54, which can be a differential gear, which adds the two movements . The film carrier carriage 30 moves. by a distance which corresponds to the sum of the two above adjustments. A clutch 56 allows the differential gear 54 to be separated from the film carrier carriage 3o to facilitate return. of the carriage if the line has been completely photographed, or to enable the use of a tab.

The adjustment mechanism 2o sends 58 voltages by means of a set of conductors, or impulses to serve changing. Rear derailleurs 46 and. 5o if an additional Distance to adjustment to; must be added to a word space if the corresponding signal read from the reading device 14 in the register will.

In the example of Fig. I it is assumed that the carriage by one any number of units between i and 225 can be adjusted. can, being this the latter number represents the product of 15 X 15. The making of a mutable Rear derailleur with 225 different positions is difficult. By the above, described Arrangement, however, will achieve this result by using only two variable, Reached rear derailleurs, each of which can occupy only fifteen positions, whereby the structure is simplified. According to this general: description of the parts of a the photographic typesetting machine exhibiting the characteristics of the invention Embodiments for the multiplier and the storage unit will now be described.

3 and 4 schematically show the design of a multiplier with sixteen relays R x to R 16. The mode of operation is explained in FIG. 2. The rectangles: i2 and: 26 represent the relative widths and the multiplication coefficients, respectively. The horizontal lines are connected to: conductors 26, while the diagonal lines are connected to conductors 12; are. Assuming that a given type has a width of five units and ß. a. Font size. or has coefficients of eleven, the circles, are, soft; occur at the intersection of the dashed lines, shown in black. The product, which should appear at the output conductors-Ei to E i28, is found by the binary addition of the rows. So, appears under Exit from. tension on the right end. each of the conductors E i, E 2 and E 4. The conductor E 8 remains primed and sends a restraint into the conductor E 16. The conductor E32 also receives a potential. It can be seen that the number indicated by the potentials on conductors E i to E 128 is "55", ie 32 + 4 + 16-1-2 + z.

In FIG. 3, the relays R i to. R. 16 by the permutation bars 4 and the. corresponding to the black circles of FIG Coefficient menu selector 28 energized. In the example described here, the relays R2, R 4, R 6, R 8, R 14 and R 16 addressed.

It can be seen in Figure 4 corresponding to an embodiment that each row: of relay contacts has a designation that corresponds to your relay, on which these contacts are located. So the two with r i2 belong Contact rows your relay R 12 on. In. Fig. 4 shows all relay contacts in the position in which they were in the rest position of the relay.

In Fig. 4 it can be seen that "the circuit of stage 2 of the multiplier comprises two sections, namely one which applies battery voltage to conductor E. 2 sets when a single one of the relays R 3 or R 8 is energized, and one. second Section, which a battery voltage for retention to the following stage 4 sets when relays R3 and R 8 are both actuated at the same time.

Instead of a single input terminal, the circuit of the following stage (relays R2, R 7 and R i2-) has two inputs. An input terminal receives the battery voltage if there is no retention coming from the previous stage 2, ie if: Relays R 3 and R 8 are both in the rest position, or if. a single @ is excited on them, while: the second input terminal receives battery voltage when R 3 and R 8 are operated simultaneously. One can. Notice in the figure. That the battery voltage is not applied to the two input terminals at the same time. can be created. In other words, the two circuits that transmit the battery voltage to the following stage close each other. The circuits of stage 4 are also designed in such a way that they relate to the number of actuators. Address relay. and not on their position. When the battery voltage is applied to the "no retention" level - on the right; the F'ig. 4 -, a battery voltage is applied to the output terminal E4 if one or three of the relays R2, R7 and R8 are actuated, and a potential is transferred to the zero level of the next stage, 8, if none or only one of the relays R 2 , R 7 or R 12 is activated.

It can be seen that when the battery voltage arrives at the other input terminal with a value of i , a potential is applied to the. Output wire E .I is applied when the, three relays are in the rest position or when only two of them are operated. At the same time there is a potential at the zero level. applied to the following stage if none of the three relays is actuated, and to the second level 8 if. one or two of the three relays are activated, etc.

To reduce the number of rectifiers working in series was the circuit is divided into two groups. The rectifiers should prevent and allow the potential to pass from the upper levels to the lower levels. a saving in contacts. It can be. check in the figure that the second Contact group works on the same principle and there, ß in. The Stromkr @ is in none If more than two rectifiers are in series, so: that the voltage drop occurs this is not a disadvantage.

From the above it can be seen that d: aß the multiplier -,% v Erk of FIG. 3 and q. directly at the output wires E i to E 128 results in the desired product in binary form. It should be noted that in no case are more than two rectifiers connected in series, so that the voltage drop in these rectifiers does not interfere with the operation of the multiplier. Each wire of the multiplier E i, E 2 bis. E 1 28 is connected to a relay, which. is denoted by the same reference number.

Let us first consider the work of the first stage, which is the input relay .E i and a binary selector with two stable ones. Positions SW i contains, which this from the stage of a process to. shows and maintains another registered number. When the first signal is received, the binary switch SW i must move from the "o" position to the "i" position. The switch SW i has the type generally used in telephony as a step switch mechanism with a spring drive. It is designed so that it does not change its position when the voltage is applied, but when it is interrupted. The switch SW i thus remains in its position "o" until. the input potential applied to E i disappears and then changes to the "i" position, whereby it shows the registration of a unit in the counter. At the second impulse the capacitance of the first, stage becomes. exceeded., and SW i must return to its "o" position, whereby it sends a restraint signal with the fiert 2 to the following: stage. The following stages all work in the same way, but can also work from. the previous stage obtained a retention potential. Below is the working of the following stages. described with reference to the fully extended step 8. The way it works depends on three factors: a,) The presence or absence of a potential. the input relay E 16, which is determined by the position of the contacts of this relay; b) the presence or absence of a retention coming from the previous stage, which is indicated by the presence of a battery voltage on wire B, which corresponds to a retention, or on the wire: t <4, corresponding to the absence, a retention; c) the position of the relevant stage: on "o" or on "i", which is indicated by the position in which the contacts of the binary switch are located :. These contacts are 'as. Tf shown as usual with switching circuits.

Under these conditions, are. the three operating conditions one Stage following: First case. The binary switch is in its position "O".

i. There is no holding back, ltepotentia, l von. the previous stage, that is, the battery voltage arrives on wire A. Then two cases have to be distinguished: There is no input signal, the binary switch SW 8 is not actuated, and the battery voltage is transferred to A 'through the contacts C, F, L, K, Q (no retention). If. If an input signal is present, the binary changeover switch is actuated by contacts A, E, I, D, h, and a battery voltage is applied to wire A ' via A, E, K, Q (no retention).

2. From the previous stage comes a reluctance. The battery voltage then arrives at B. Two cases are to be considered: None. Input signal, the binary switch SW 8 is operated by B, H, D, U and moves to its "i" position, and a battery voltage is applied to A ' via C, F, L, K, Q (no retention). In the event of an input signal, the binary switch SW S is not actuated and a battery voltage is applied to B ' via B, G, O, S (retention).

Second case. The binary toggle is originally in its position "i".

i. No holding back from. of the previous stage, ie the battery voltage is received at A. Two cases must then be considered: If there is no input signal, the binary switch is not actuated and a battery voltage is applied to A 'via A, E, 7, P (no retention). When appearing. In response to an input signal, the switch SW 8 is actuated via A, E, I, D, V and goes to its "o" position, and a battery voltage is applied to B ' via C, F, M, N, R (retention).

2. Restraint coming from the previous stage. So here a battery voltage is received at B. Two cases are possible: If there is no input signal, the binary switch SW 8 is activated via B; H, D, V actuated and goes into its "o" position, and a battery voltage is applied to B ' via B, G, N, R (retention). When there is an input signal, the binary toggle switch is not actuated and battery voltage is applied to B ' via C, FM, N, R.

You can see that there is no addition of the operating times in the storage facility occurs regardless of the number of simultaneous. Inputs in the counter im Moment. receiving a new number.

Another embodiment of the multiplier with eight relays, instead of sixteen, is shown in FIGS. 6 shown. In Fig. 5, the permutation bars 4 are connected to four relays A, A 2, A4 and A 8, and the coefficient selector 28 is connected to four relays Bi, B: 2, B 4 and B 8 . The contacts of these relays are in Feg. 6 shown. The contacts of FIG. 6 are designated with Arabic numerals which correspond to the numerals of the associated. Relays correspond, and - the lower case letters correspond. the: letter identifying the assigned relay. So refer z. B. the contacts marked a: i on the relay. A i.

In this embodiment, as in the previous case, it can be determined that if the relative width of a type is "5" and the font size is "ii", the relays A i, A4, B i, B 2 and B 8 are energized will. One sees immediately in the figure that the same conductors E i to. E 128 are excited as in Fig. 4.

It is clear that other types of. Multipliers and accumulators to be used. can. Without departing from the scope of the invention.

With the above. described. Multipliers will be at the same time Signals to one or more stages. of the storage facility. Db, the steps at the same time can be pressed, the time to accumulate a new one. Product in the storage facility extremely short, although the relay takes a few milliseconds to respond require,.

In the multiplier of Fig. 7, a number of pulses is over lines E i to E 64 are sent out one after the other instead of simultaneously. For this Basically, the whole can only be used to send a product to the warehouse sufficient. be made short that in the storage unit relatively quickly working steps. In this case it can be any binary electronic Counter are used, which only requires extremely short control pulses, so that the total time for the transfer of the complete product to the borders which can be reduced depending on the writing speed the typewriter or the transmission time are determined.

Like the. Embodiments of FIGS. 5 and 6, the embodiment of FIG. 7 requires eight input relays, namely A i 'to A 8' and; B i 'to B8'. The contacts of the relays are arranged in pairs in accordance with FIG. 6 in the positions which correspond to the non-excitation of their respective relays. The stages of the counting and storage @ system are with C i, C 2, C 4 to C 128 The connecting each stage pair: Rectifiers represent the circuits, over which transmission impulses from, each. Level to the next higher. The mode of operation of the device is explained using the previous example, which corresponds to a width of "5" and: a font size or coefficient of "i i". The relays A i ', A 4', B i ', B 2' and B 8 ' are energized. A manifold 62, e.g. B. a rotary switch for the successive application of a voltage to each of sixteen conductors, output from the upper part of the figure, finds circuits which serve via certain pairs of relay contacts; lead to different levels of this counter. The first pulse goes via the contacts a i ', bi' to the counter stage C i. The next pulse goes through the contacts di, b 2 '; the next via the contacts a4 ', b 4' etc. It should be noted that two pulses arrive at the counter stage C 8 one after the other, one of which via the contacts a q. ', b 2'and; another about the contacts a. i ', b8' goes.

It is easy to see that this causes the storage unit to be reduced to a Amount is brought, which is equal to the product "55" as with the previous ones Embodiments.

It is clear that the manifold 62 is a. any known structure may have, wherein it has no moving parts; needs. Numerous acquaintance such devices permit speeds of the order of io, ooo To achieve impulses per second and even more. At this speed are. only 1.6 milliseconds or less to transmit the full product the storage unit required.

The embodiment of Fig. 8 includes a continuously rotating opaque disk 64 having four groups of clear slots or cutouts 66 with sixteen slots in each group. A single slot 68 is opposite the other slots on a different radius, as shown in the drawing. A photoelectric device 7o is provided with means for generating pulses corresponding to the passage of each slit 68 in front of its light-sensitive part. It is assumed that disk 64 is rotating in the direction of the arrow. The arrangement of the photoelectric device is such that the slot 68 emits a pulse. is generated before any of the slots 66 generate a first: pulse.

A slip ring 74 made of insulating material and containing a single conductive segment 76 is attached to the disk and rotates with it. The segment 76 is electrically connected to the photoelectric device 70 such that it receives the pulses therefrom.

Four brushes 78 are distributed around the slip ring so that each of them, when, they come into contact with the segment 76, with him during the complete emission of the sixteen pulses generated by slots 66 in contact remain.

The disk 64 is expediently connected to cams or the like, which, to determine the times of the various: Operations: during the above transfer process to be used. Multiplying a relative width by a coefficient requires one revolution of disk 64 exiting from that shown in the drawing Position. After generating a pulse through: then reaches the slot 68 a group of sixteen pulses one of the brushes 78 across segment 76 and onto it a following group of sixteen pulses the next brush 78 in a similar manner etc.

Four conductors So and 8a are connected to switches which: in the embodiment shown in: are shown in the block containing the permutation bars 4 ... These switches should: be closed in accordance with the binary representation of the relative width of the selected type. (It is clear that when the multiplier is used in connection with the transmission, these four switches represent contacts which are closed according to the pin combination scanned by the reading unit 14 of the registration unit.) The ones via the closed. Pulsesi transmitted to the switch contacts are passed on in a corresponding manner to each of the stages C i, C2, C4 and C8 of the .Speicherwerk.24. With the aid of a conductor 84 coming from a flip-flop arrangement 86, however, such a voltage can be applied to the stages C r to C8 that they do not respond to any impulse arriving at their input conductors E i to E8. This "insensitivity" voltage appears on line 84 when assembly 86 is in one. its two stable positions, but not in. the other :.

A binary auxiliary counter 88 with binary levels D i to D 8 is with of the photoelectric device 70 by: a conductor 9o and a delay device 9i connected, which pulses with a delay of a few microseconds the lowest level of the counter transmits.

Pulses generated by the device 72 can be applied to one or more Stages of the counter are transmitted over a line 92, which with the stages is connected via contacts in the coefficient selector 28.

The following is a description of how a type works, the relative amount of which is "5" and. whose coefficient is "ii". First, a pulse coming from the control device 94 synchronized with the disk 64 is transmitted to the flip-flop arrangement 86 in order to. to bring this device into the state: in which the conductor 84 transmits a voltage to the memory stages C i to C 8 for "rendering insensitivity".

This is followed by a: from. Pulse generated in slot 68 via line 92 and a pair of contacts 96 and 98 to stages D i and " D 4" of counter 88. The counter then reads the: coefficient "ii".

The device 70 then sends a group of sixteen delayed pulses :. the Stu.feD i of the counter 88 and sixteen to delayed pulses via the segment 76, the conductor 8o and a contact ioo to the stage C i of the storage unit 24. It is assumed that the contact ioo and two other contacts io2 and 104 are closed to represent the relative British "5".

The first ten impulses going over the line 8ö have no Effect on level C i, since it is assumed that the storage units are going through the voltage to which conductor 84 is made insensitive. These ten impulses "Fill up the meter 88" by pressing it; from its original, setting Bring "5" to its maximum capacity of "15".

The eleventh pulse reaching the counter 88 causes the stage D 8 of the counter 88 to send a transmission pulse over a line io6 to the flip-flop arrangement 86, as a result of which the voltage for the "insensitivity" of! the conductor 84 is switched off. As a result of the delay device 9 1, the eleventh pulse coming from the photoelectric arrangement reaches the stage C i of the storage unit via the contact ioo before this change has been made, so that this pulse. also has no effect on the storage unit.

The next: five impulses, which. Advance of the storage plant 24 cause also leave the counter 88 up to its original one. value Advance "5", which is the position originally set by device 72 is equivalent to.

The device 94 then sends a pulse into the flip-flop arrangement 86 before the generation of the next pulse group in the device 70; to reapply the voltage to line 84 to de-energize.

The same processes are then repeated during the same group of five impulses reached stage C 2 of the storage unit via contacts i o2.

The next following group of fifteen inn pulses reaches the counter stage C4 not because it is assumed that the associated contacts are open.

Eventually, one: group of five pulses reaches level C B. This advances the storage unit 24 to a value which is 5 - 8 + 5 - 2 -I- 5-1 = 55.

Another method for generating the successive pulse groups is shown in Fig. 10. A disc io8 coated with an opaque material or coating has four groups of clear. Slots i io arranged so that only one slot passes in front of a fixed opening iiz at a time, each slot in the group being on a different radius. A is displayed an optionally about a fixed axis i 1 6 rotating stepped cam 114th Part of the opening i 12 from ,.

The cam 114 has a number of stages which e.g. B. the desired Font size or coefficients. B. the cam for a font size: from. »I I« is set, only five slots in each group generate light pulses, so that four successive groups of impulses arise "each of which has five successive ones Contains impulses.

A distribution arrangement of the reference! on Fig. 8 described Kind can be used, around. these impulses one after the other: the selected levels des Speicherwerk24.

Fig. 9 shows an embodiment in which electron tubes are used and a certain number of pulse trains are sent into the counting and storage system 24 will. This counter can be a sequence of flip-flop levels of the Eccles: Jordan type. Two further binary cells! R i i8 and i2o of the same type are assigned to the permutation bars 4 or the coefficient selector 28-. Mission from. Transmission contacts are connected to each stage of the counters 118 and i2o, and each set of contacts corresponds to one of the conductors i2 or 26 (Fig. i). It is believed that when the contacts are in the illustrated. Position, the corresponding conductors are dead; if: she is in the position »i «Should: the corresponding: conductors are live.

A. Pulse generator i22 sends pulses to counters i2o and. 24, z. B. with a frequency of 10000 pulses per second. Each level of the counter i2o has two idle conditions. If the level counts an "o" it becomes a high one Potential applied to its terminal "i"; if the level counts an "i", it becomes a high. Potential on their terminal "i" and a low potential on theirs. Clamp "O" created.

For the example of a type with a relative width of "5" and a font size. or coefficients of: "ii" are the contacts connected to the levels: "i", "2" and "8" of the counter i2o and the contacts connected to the levels "i" and "4" of the counter i 1 8 in, brought their position "i". If the pulse generator i22 generates positive pulses in the. Counters i2o are sent, take the potentials on the terminals. "O" and. "I" of its various. Graduate the corresponding binary combinations one after the other.

For the assumed: case you can see that the parts with unilateral Conductivity 12.4, which z. B. German; iumkristalle can be., Applied potentials for the eleventh impulse are all "high". In that moment the potential increases at one point a. In all other positions of the counter i2o there is at least one Rectifier 124 placed low, whereby. a corresponding one Voltage drop. arises at the resistor 126, so. that the signal to a lower Maintained level. will.

The eleventh pulse is transmitted in this way to the input of a flip-flop circuit, i28, -which switches the potential of its output conductor b from "high" to "low". This switchover blocks the input of the. Counting and; Storage, verks 24, since a rectifier 130 connected to its input terminal c is now connected to a low potential. Another with a flip-flop circuit. 134 connected rectifier 132 is at a raised potential, as explained below. The first eleven pulses thus reach the counter 24 before the circuit 128 reverses its potential.

The following pulses up. to the sixteenth press the counter 24 not, the sixteenth impulse, which sets the counter 120 back to "o", is transmitted, however, to the bromic circuit 128, which the. Potential at point b in. "High" changed.

The second, with the. seventeenth pulse beginning train of, eleven pulses can serve; Reach counter 24 in a similar manner.

The number of the pulse trains thus sent into the counter 24 becomes. controlled by your counter 118. For this purpose, the eleventh pulse sent to the flip-flop circuit 128 is also sent to the counter i i8. In the above example it is assumed that the contacts connected to stages "i" and "4" of this counter are in their "i" position. From this it follows that after the fifth such pulse received by the counter 118, all parts with one-sided conductivity 136 with high. Connected potentials. are; causing a high voltage on the flip-flop circuit. 134 is transmitted. This circuit changes the potential. its output terminal d from "high" to "low". It follows from this that no further pulse from the generator z22 can move the counter 24 forward. The multiplying process then ends after the counter 24 has received five trains of eleven pulses so that it counts "55".

In the above description it was assumed that the pulses a have positive polarity. In the case of negative impulses, the connections can be interchanged in a manner known per se: In the case of the illustrated in Fig. i i, Embodiment of the multiplier, the multiplication takes place without moving Parts. The product of the relative width of the type and the coefficient becomes obtained with the help of static, only one-way conductive parts, such as rectifiers, High vacuum tubes or the like.

A set of contacts 138 which, according to the: coefficient, is controlled in a manner similar to that associated with the counter i2o in FIG Contacts, applies a battery voltage to a set of wires 140 when the Contacts in the shown. Position (which corresponds to the position "o"), and to a set of wires, 142 when in the other stall (which corresponds to the position "i").

A contact set 144 is similarly made according to the relative width the type actuated.

For a type with a relative width of "5" and a coefficient of "7", a group of contacts, 146, 148, 150, 138 and 152 are actuated and the battery voltage is fed through a set of rectifiers to each of the lines E. i, E2 and E32 applied what. the product "35" represents.

Each of the wires E i through E 128 is connected through a resistor 154 to the Battery connected. The one assigned to the contacts. Resistors 156 have one. relatively small value compared to yours of the resistors 154. As a result becomes: the voltage on a line, e.g. E 32, due to a voltage drop the resistor 154 is reduced if there is a circuit which is different from the Line E32 via one; Rectifier and, one. Resistance 156 leads to earth. In other words, all contacts do not correspond to the one assumed in the example Position would be, would be one or more resistors 156 to Earth-carrying circuit exist, and the Pobenhial of the line E 32 would stay in, near the earth potential, even if one or more of the others connected to the line E 32; Rectifier through a switch to the battery would be connected :. It. eats natural.ch accepted, then the one with the lines: E i to E 128 connected external load a relatively high impedance in comparison to resistors 154 has.

The case of the conductor E i is a: special case, since this conductor always must be excited when the multiplier and the multiplicand are both odd numbers, are. For this purpose, as shown, a. Circuit with only two rectifiers sufficient.

Similar circuits must be provided for ° all possible products .. This results in a circuit with a relatively large number of Rectifiers, however, these can be very small in size, and the circuit can be designed for very small currents. In this embodiment you can appropriately printed circuits are used ..

Claims (5)

PATENT CLAIMS: i. Method to bring the lines to be set to the same length with a photocomposing machine with types of different font sizes, characterized in that the length by means of. a Muttiplizierorgan.s (6) is measured, which multiplies the width of the types with a certain coefficient corresponding to the selected font size, the products being stored one after the other in a counter storage unit (24), so that the sum of these products is the Expresses the length of the line in units of length which are suitable for actuating the devices (46, 50, 52, 54) for producing the spacing between the words via a compensating device (2o). 2. The method according to claim x, characterized in that, ß the multiplication, and the accumulation take place in that a binary code is used: and that the MulBiplierwerk relays, which keep the, different. possible partial products. correspond. and under the control of the number indicating the width given by the keyboard (2) and: the font size given by a button, and that the partial products of the same order are added by contact circles which are dependent on the number of actuated relays regardless of the order .ungs: address the same number or sequence, with a signal being transmitted in the relevant stage if the number of actuated relays is odd, with a restraint signal being sent to the following stage at a level corresponding to the number of actuated relay pairs. . 3. The method nasch claim i, characterized. characterized in that a multiplier and storage unit (24) is used which a. Receiving relay for each stage contains the value the new number arriving in the counter, with one switch per step when falling works and in his contacts the previous: total amount kept, the coil of this switch. gets excited when he is out of the position "O" should change to a position "i" so that the switch when it is energized was, passes from one position to the other when the power is interrupted and the retention of the previous total amount gives up to get on the: to set the new total amount .. 4. Apparatus for carrying out the method after the. Claims. i and 3, characterized by firstly an opaque, with cams od. The like. Provided, rotatably arranged disc (64), which preferably with slots (66) ad arranged in groups on a circle. Like. Is provided and. has a special slot (68), secondly one. with the spinning disk (64) firmly connected slip ring (74) made of insulating material, which is a having conductive segment (76) and, corresponding to the slot groups (66) working Brushes, thirdly a phot0-electrical device (70), which on the one hand with the Segment (76) of the slip ring (74) and on the other hand. via a delay device device (9i) is electrically connected to an auxiliary counter (88): fourthly, a Speichenverk (24), on the one hand with the brushes (78) via switches (ioo, pulled and, io4) od_ like. connected. and on the other hand with a flip-flop arrangement (86) electrical is connected, fifth, a controller, and sixth, a coefficient selector (28), the one with a pre-pulse generating. Device (72) and the counter (88) is electrically connected. 5. Apparatus for carrying out the method according to claim i and 4, characterized in that, ß the slots of the opaque disc (64 and io8) are arranged in groups in such a way that only one slot at a time (iio) can appear in front of a fixed opening (1i2), and dafi between the light source and the photoelectric assembly is a rotatably disposed stepped cam (114) is arranged, each of which is an arbitrarily adjustable part of the openings. (i i o) covers. Considered publications: German patent specification No. 867 65 i.