DE1040828B - Arrangement for calculating with number fractions - Google Patents

Description

In order to be able to count fractions of numbers with the usual calculating machines, essential interventions are necessary required in the machine. It was proposed that the counter of an arithmetic unit be used to record of number fractions is provided to be equipped with a counting wheel instead of the usual division of ten has a division corresponding to the denominator of the fractions. Should z. B. fifths are added, the counter wheel provided for this purpose has five positions, and the transfer to the next higher counter position, in this case, the units digit, occurs after five fifths have been introduced.

The invention relates to an arrangement for calculating with number fractions by means of a for a specific Number system, preferably for the decimal system, provided counter. According to the invention are the counter provided for recording fractions of numbers according to the nine value of the Numerical fractions adjustable switching elements, preferably relays representing the values 1, 2, 4, 8, assigned, the input of the complement of the nine value formed as the basis of the number system used effect in this counter station after the counter value of a first fraction is introduced and after the capacity of this counter has been exceeded by the counter values of further number fractions became. According to a further feature of the invention, they cause the number fractions to correspond to the nines adjustable switching elements when taking the value the representation of the in the for inclusion value contained in the counter provided by number fractions minus the introduced complementary value.

The invention is explained in more detail below using an exemplary embodiment. It shows

Fig. 1 a to Id the circuit diagram of the machine,

Fig. 2 is a timing diagram,

3 shows a side view of a point in the arithmetic logic unit used,

4 and 5 a schematic circuit arrangement for the optional control of arithmetic units for handling fractions with unequal denominators.

First, the counter used in the embodiment will be described. Fig. 3 shows one such This is the counter that is used in common punch card machines Counter provided for each decimal place. The control is carried out by punch cards in which the information are punched according to the well-known ^ -loch key.

Between the cores of the switching magnet AM and the stop magnet SM (Fig. 3) is rotatably the armature 45, which is connected to a clutch lever 21

arrangement
for calculating with number fractions

Applicant:

IBM Germany International Office Machine Company mb H.,
Sindelfingen (Württ), Tübinger Allee 49

Claimed priority:
V. St. v. America March 15, 1955

Joseph Oliver Hannibal jun. _r

Vestal, NY (V. St. Α.),
has been named as the inventor

commitment. In the disengaged position of the coupling lever 21, the armature 45 rests against the core of the magnet SM. When the magnet AM is excited, the armature 45 is attracted by the core of this magnet, and the clutch lever 21 engages. The clutch lever 21 is locked in its two positions by a pawl 35.

When the clutch lever 21 is moved into its second position when the magnet AM is excited from the disengaged position shown in FIG. 3, it releases a disc 20 for counterclockwise rotation, and a spring 31 can now engage a clutch pawl 30 pull the switching gear 16. The ratchet wheel 16 is attached to the continuously rotating gear 17. When the clutch pawl 30 is engaged as a result of the excitation of the magnet AM , the rotation of the counter wheel 24 is initiated. The termination of the rotation of the counter wheel 24 is brought about in a known manner by the switch-off lever 50 or, in the case of subtraction processes, by the excitation of the stop magnet SM . The release lever 50 carries two in particular spaced pins 52 and 53 (the latter not shown) which with the surface 21 b of the off lever 21 cooperate to the counter introductions at 150 ° and the decimal carry at 336 ° of the machine game (= 360 °), as can be seen from FIG. 2.

In order to trigger special expensive processes when the counter wheel reaches its "9 position", a follower lever 24 α cooperates with the counter wheel 24 in such a way that a nose of the lever 24 α falls into a notch on the circumference of the counter wheel when this is the

8M 657/233

Item 9 reached corresponding position. As a result, the contact spring 239 comes into contact with the Nine contact segment 241. When the counter wheel runs from "9" to "0", the contact spring 239 brought into contact with the tens contact segment 240. These segments 240 and 241 and the contact spring 239 form a changeover contact (Fig. Ib), which carries the tens from a counter digit into the causes the next higher counter digit in a known manner.

The counter is provided with an electrical totalizing device which is known per se and is therefore only shown schematically in the circuit diagram (FIGS. 1 b and 1 c). It can be seen from this illustration that a removal brush 1044 is assigned to each counter element, which brush is in contact with a common contact rail 1045 and, depending on the setting of the counter wheel, with one or the other of the contact segments 1046 representing the digits. Contact segments 1046 corresponding to the same digits are connected to one another by lines and receive pulses from the sum pressure pulse transmitter E 1, which pulses are transmitted to the pressure control magnets depending on the position of the removal brush of the counter positions.

The machine's transport device guides the punched cards individually and one after the other through the Sensing stations in which the perforations of the cards are sensed. As this transport facility is known, it is not shown in the drawings. In Fig. 1 a only the electrical Connections to and from the sensing brushes are shown. This figure also shows the initiation of the machine work required circuits and sockets, which by means of cables with the various Control elements of the machine and the sockets of the meter are connected to the Cards to introduce punched information into the counter.

The machine contains two sensing stations through which the cards are successively passed will. The first sensing station can be used for various control purposes in a known manner and is used in the present invention to control the additive or subtractive Introduction of the values in the counter. According to the invention, the counter can optionally be used to receive Fractions are controlled. The second sensing station is used to use appropriate plug connections to transfer the values sensed from the cards to the meter.

The card transport is initiated by pressing the start button (FIG. 1 a), the contact 274 of which closes a circuit from conductor 920 via line 272 and start relay # 1636 to conductor 921. The relay # 1636 is held by the holding winding # 1636 - //, the assigned contact b and the cam contact CR 6 and energizes the relay # 1638 via its contact a , which in turn causes the excitation of the relay # 1639. Relay # 1639 closes its contact b , thereby energizing the card knife clutch magnet 64 to remove the punched cards from the magazine (not shown) in the usual manner.

The machine is driven by the motor M after the main switch 5 ^{1 is closed.} The excitation circuit of the coupling magnet 64 runs from the main conductor 29 via the fr contact of relay # 1639, cam contact CR 87 and the winding of the coupling magnet 64 to the main conductor 921.

The cards removed from the magazine close the card lever contact 276 as they travel to the first sensing station, so that the relay R 1628 is energized and relay # 1630 is energized via the associated contact α and the cam contact CF 22. The relay # 1630 closes its contact # 1630r, so that when the cam contact CR 88 closes, the excitation circuit from the main conductor 920 via the contacts R 1639 b, R 1630 c and the cam contact Ci? 88 to the coupling magnet 280 or to the main conductor 921. Excitation of the clutch magnet 280 causes a one-turn clutch to be engaged to initiate rotation of a shaft to control various cam contacts. These cam contacts are labeled CF and are only effective during the card transport processes. The cam contacts labeled CR in the circuit diagram, on the other hand, are actuated with every machine cycle.

As mentioned, the cam contact CR 8 closes the excitation circuit for the relay R 1628 via the card lever contact 276, which is held via its contact # 1628 'and the cam contact CF 5 . The cam contact CFS maintains the excitation of relay # 1628 until the following machine cycle, so that when the cam contact CF 2 closes during this and the following machine cycles, the excitation circuit for the clutch magnet 280 is closed via relay contact # 1628 c and cam contact C # 88 will.

Relay # 1628 closes its contact # 1628 t? When energized, thereby producing a circuit from main conductor 920 via cam contact C # 3 and a coupling magnet 153 to main conductor 921. The excitation of the coupling magnet causes the grippers of the transport device to guide the cards through the successively arranged sensing stations and to the depositing station. The relay # 1630 is energized at the end of the first card transport machine game via the cam contact CF 22 and the contact # 1628 α , and the contacts # 1630 c and # 1628 c alternately close the excitation circuit for the clutch magnet 280 to keep the machine in operation hold until the stop button is pressed or the card lever contact 276 opens because no more cards are fed.

The circuits through which the perforated cards are evaluated in the first and second sensing stations are shown in FIG. 1a, but this figure only shows the sensing commutators assigned to columns 1, 2 and 80 in a schematic representation. These sensing commutators are known to be used when all columns and counting point positions on a card, that is to say the entire card, is sensed by the sensing brushes at the same time. This facility is present for every eighty columns in both sensing stations. The sensing circuit runs for the first sensing station from the main conductor 920 via the breaker contacts CBl to Cß4, the cam contact CF 28, the contact # 1630 b, which is closed during the entire sensing time, to the line 990. The line 990 is via the line 991 with the Contact arm K165 of the sensing commutator assigned to the first card column is connected. The contact arm 165 successively comes into contact with the contact segments 164 and closes

6g a circuit over the one passed through a card hole Brush 162. The sensing brushes 162 are attached to a common contact rail 161, those with a socket, for the first card column, for example with the socket 923, connected is. The first sensing station therefore contains

eighty such sockets 923, 942, etc., of which can be made from connecting cables for the various control tasks.

The sensing circuits of the second sensing station run from the cam contact CF28 via the relay contact R 1632 g to the line 992, to which the contact arms 165 of the sensing commutators assigned to this sensing station are connected via corresponding lines, such as 993 for the first card column. The contact bars 161 connected to the sensing brushes 162 are connected to corresponding sockets 926, 944 and 975, respectively, of which there are also eighty. Contact R 1632g is activated when relay 2? 1632 closed at the time the cam contact CF 23 closes for the duration of the sensing time in the second sensing station.

To prepare the counter to receive the information, a connecting line 977a between the socket 977 (Fig. La) and the input control socket 978 (Fig. 1 b) and also a connecting line 977 b between the socket 977 '(Fig. 1 a) to Socket 979 (Fig. Ib) can be inserted to transmit the card machine game pulses to energize a relay R149 B , the energization of which is appropriately maintained (not shown). The sockets 977 and 977 'are connected to the contacts f? 164a, which are closed by the relay i? 1641 (Fig. La) when it is energized at the time of the closing of the cam contact CR 88 during the introductory and the sensing machine games.

When the numbers "1" to "9" are introduced, the addition control circuit runs from the main conductor 920 (Fig. 1 a) via the line 1038, the cam contacts CF29 and CF30, the relay contact R 1641 α and via the connecting line 977 a from the socket 977 to the socket

978 (Fig. 1 b) and via the excitation winding of the relay R 371 and the line 1029 to the main conductor 921. In parallel, a circuit runs from the socket 977 'via the connecting line 977 & to the socket

979 (Fig. Ib) and via the control relay R 149. The two relays R 149 and R 371 close the circuits for the additive amount introduction into the counter.

Since the circuits required to carry out the purpose according to the present invention are shown in the circuit diagram in connection with the units digit of the counter, the circuit for normal amount introduction is explained in connection with the tens digit of the counter for better clarity. The relay i? 371 has the associated contact R switch 149 e when energized the associated contact 371c (Fig. Ib, bottom right) and the relay R 149. At the same time, the contact R 371 α was switched over in order to prevent the excitation of the write control relay R 223 (Fig. Ib) while the card counting point positions 1 to 9 are being sensed. As a result, the excitation circuit for the relay R 223 through the cam contact Ci? 71 controlled and runs from the main conductor 920 via the cam contact CR 71 (which is open during the card sensing time 1 to 9), the toggled contact 72149-1, the normally open, now closed lower contact R 371a, the rest side of contact R 445a and over write control relay R 223 and line 1029 to main conductor 921.

The circuit for the additive introduction of a digit value into the tens of the counter thus runs from the main conductor 920 (FIG. 1 a) via the cam contacts CB1 to Cß4, the contact i? 1632 g, the line 992 and, for example, via the contact arm 165 of the sensing commutator assigned to the 80th card column, a contact segment 164 and the brush 162 that has passed through a card hole to the socket 975 and from here via the connecting line 975 α to the socket 976 (Fig. 1 b) and via the contacts /? 445ί ?, i? 223c (in rest position), the switched contacts R 149 e, R371c and via the adding magnet AM of the tens to the main conductor 921. The

ίο breaker contacts CB (Fig. 1 a) send when sensing any card holes pulses that couple the counter wheels so that their rotation begins; In the case of additive introductions, the rotary movement is terminated in the 155th ° of machine play by the switch-off lever 50. In this way, the digit value corresponding to the scanned card hole is added to the counter.

All counter digits are set to the number "9" in their basic or normal position. Therefore, W ^T hen the Addiermagnet AM a pulse receives, and by the engagement of the clutch pawl 30 (Fig. 3) in the indexing wheel 16 is a counter wheel starts its rotation, the contact spring 239 contacts the contact segment 240 contacts and is locked in a known manner. Assuming that the value 5 is to be added, the contact 239/240 is locked when the counter wheel passes from "9" to "0" and the counter wheel continues its rotation through the positions 0,1, 2, 3, until it is stopped in the position corresponding to number "4". At a certain point in time during the machine game, the tens transmission pulse is sent via the tens contact and the counter wheel is advanced by one switching step so that the counter wheel set to the number "4" is rotated to the correct setting 5 and all other counting wheels are rotated from their basic position 9 to position 0 will.

The tens transfer control relay i? 638 (Fig. Ib) is energized by the cam contact CR 61 for the time from the 295th to 315th degree of machine play in order to prepare the usual circuits of the nine and tens contacts 241 and 240 in the counter positions which the transmission pulses are sent to the adding magnets AM of the counter stations. The contacts R 638 d (Fig. Ic), R638c and R 638 α are connected in series with the adding magnet AM of the units, tens and hundreds of the counter. The transmission pulse from the nine contact of the highest digit of the counter is transmitted via the connecting line 980 'between the socket 980 and the socket 981 to the adding magnet of the lowest counter digit.

Since the control circuits for the tens transmission are known, they are not described in detail.

The value stored in the counter is removed by energizing the removal relay i? 445 (FIG. 1 b) by a program signal. The energized relay i? 445 switches over its contacts, and the extraction circuit, e.g. B. for the tens, runs from the main conductor 920 via the contact arm 1039 of the sum pressure pulse transmitter El (Fig. Ib), the normally closed contact R75j (if this tens digit contains a positive "9"), the line to the removal contact segment 1046 in the tens, which in the new position removal brush 1044 ', the contact bar 1045', the now switched contact R4A5e and via the idle sides of the contacts i? 223c and i? 145t? to the EXIT output socket of this counter. Would the im

If the numerator “9” was a negative value, then this counter value would be taken as its nine's complement, i.e. as XuIl. In this case the relay R 75 must be energized. The extraction circuit has in this case essentially the same course with the exception that it now runs from the contact arm 1039 of the pulse transmitter El via its zero contact segment and the switched contact R75i to the nine contact segment 1046 of the tens. The excitation of the relay R 75 occurs when the highest count is "9", and the circuit to excite the relay runs from the conductor 920 via the cam contact Ci? 62, the contact Ria (quiescent side '), the nine contact 239/241 the highest meter position, the rest side of the contact R 638 α and via a connecting cable NB ' between the sockets NB and XBC and via the excitation winding P of the relay R75 to the main conductor 921.

In the foregoing, the method of operation of the calculating machine, which is known per se, was introduced during the introduction the numbers "1" to "9", the transfer of tens and the withdrawal of value are briefly described. Hereinafter the use and control of the counter in performing fractions will now be discussed. Although fractions with any denominator can be used, the description below has a fraction with the denominator 6 was chosen to carry out the fraction calculation. For the introduction of Fractional values in the counter are used by the circuits shown in FIGS. 1 c and 1 d.

The relays RE, RF, RG and RH (Fig. 1 c, top left) are connected on the one hand to the main conductor 921 and on the other hand each with a socket, which are labeled 1, 2, 4 and 8 and correspond to the binary representation system. An equal number of sockets FC , which are connected together to the main conductor 920, are provided above these sockets. Sockets 1, 2, 4 and 8 can be connected by connecting cables corresponding to the denominators of the fraction to be treated with the letters FC . With the assumed denominator value 6 z. B. to connect the sockets 2 and 4 with the sockets FC , with fifths the sockets 1 and 4 would have to be connected to the sockets FC by connecting cables. The relays RA, RB, RC and RD also connected to the main conductor 921 are connected to the contacts α of the relays RE, RF, RG and RH , respectively. The movable contact springs of these contacts are connected to one another and to the rest side of the contact R75a (Fig. Ib). The other contacts assigned to the relays RE, RF, RG and RH are arranged in the form of a pyramid and establish connections with the sum pressure pulse transmitter Til (Fig. Ib), a second pulse transmitter E2 and the adding magnet AM or subtracting magnet SM of the units digit of the counter.

The contacts of the relays RA, RB, RC and RD shown in Fig. 1d control the extraction of value from the units position according to the position of the brushes 1045 ", which are connected via the line 1045 α to the normally open side of the contact i? 445t: ( Fig. 1 c). This contact enables the value to be taken from the units position of the meter when it is switched and closes the extraction circuit via the normally closed contacts R223d and R 149 c to the output socket EXIT of this meter position the pressure of the taken out, respectively. the ten contact segments 0 1045 "of the ones digit, up to 9 of the sampling device depicted d as shown in Fig. 1 connected to the contacts of the relays RA, RB, RC and RD, in turn connected via a cable the contact segments of the sum pressure pulse transmitter £ 1 (Fig. Ib) are connected. If the units digit of the counter is used for the normal introduction of decadic values, the contacts (Fig. Ib) of the relays RA, RB, RC and RD remain in their rest position.

ίο Setting the relay to the denominator a certain fraction fulfills two tasks, namely the adjustment of the counter to one of the the corresponding value (default value) to be treated, which is explained in more detail below, and secondly, the switching of suitable contacts in the extraction circuit in order to extract the correct one To bring about value. These two requirements are made easier with the help of the table below understandable.

Denominator values

Ninth.

Eighth note ..
Seventh

Sixth.

Fifth.

Quarter ..

One-third ..
Half ...

Possible counter values

0 12 3 4 5 6 7
0 1 2

2 3 4th 5 6th 7th 1 2 3 4th 5 6th 0 1 2 3 4th 5 0 1 2 3 4th 0 1 2 3 0 1 2 0 1

The default value for a fraction, e.g. B. the sixth, corresponds to the tens complement of the Denominator value, ie the number "4". Presetting value or setting of the counter to this value is necessary, so that the counter when entering z. B. six sixths a carry over to the next higher Decimal causes. The number "2" is z. B. the preset value for the eighth etc.

When removing a counter that is used to deal with certain fractions, it must be taken into account that the value in the counter is taken too high by the preset value. In the case of sixths of a fraction, the counter values 1, 2, 3, 4, 5 correspond to the setting values 5, 6, 7, 8 or 9 in the decadic system. Similarly, the numerators 1 and 2 of the fractions with the denominator 3 correspond to the setting values 8 and 9, respectively, in the decadic system. The contacts of the extraction circuits must therefore use the relays RA, RB, RC and RD to extract the correct extraction values from the counter value of the break in the counter.

Assuming that the arithmetic unit of the machine is set for normal addition processes, the addition control relay i? 371 (Fig. Ib) is energized in the manner already described. With the further assumption that the value 5 (the numerator of the fraction ⁵ As) is to be entered additively into the counter, the counter wheel is first turned by five units.As the counter wheel is normally set to the value 9, the value 5 is added turning the counting wheel from "9" to "4". During this rotation the tens contact 2397240 '(Fig. Ic) is closed in order to bring about a tens transfer in the usual way to the tens digit of the counter. According to the invention, this tens contact is also used to initiate the introduction of the preset value into the counter.

The normal tens transfer process takes place at the end of the machine game (308th ° to 315th °), and during this time the tens carryover causes the counting wheel of the ones digit of the counter to advance by one switching step. At the same time, a presetting relay RJ (Fig. Ic) is excited via a circuit that starts from the main conductor 921 via the winding LP of the relay RI, one of the parallel-connected contacts RF b, RG b and RH b, the contact 7? 638 fr, the closed tens contact 2397240 ', via the line 1051 and the cam contact Ci? 76 (Fig. Ib) to the main conductor 920 runs. When the cam contact Ci? 210 is closed in the 337th to 345th degree of machine play, the excitation circuit for the addition magnet AM (Fig. 1c) is closed in order to initiate the presetting of the counting wheel in the ones place. This excitation circuit runs from the main conductor 921 via the adding magnet AM of the units position (Fig. 1 c), the contact R 638 d (rest side), the now switched contact RI b, the line 209, the cam contact CR 210 and via the line 1043 ' and the breaker contacts CB 1 to CB 4 (Fig. La) to the main conductor 920. The counting wheel is then rotated until the subtraction or stop magnet SM is excited by a pulse. This stop pulse interrupts the rotation of the counting wheel after it has added the value 4 (tens complement of the denominator value six). The stop pulse runs from the main conductor 921 (Fig. 1c) via the subtraction magnet SM, the switched contact RIa, the rest side of the contact RHc, the switched contacts RGc and RFd, the rest side of the contact REd, the extraction line 7 (Fig. Ib), the rest side of the contact R75-1, the seven-contact segment 1040 and the contact arm 1039 of the pulse transmitter E 1 to the main conductor 920.

In a later section of the machine game, the contacts of the relay RI must be reset to their basic position. Since this relay is a locking relay of known type, its unlocking coil LT must be energized. The pulse for exciting the relay RI-LT (Fig. 1 c, above; runs from the main conductor 921 via this relay, the rest side of the contact RHe, the switched contacts RGg and RFj, the rest side of the contact REm, the extraction line 6, the rest side of the contact i? 75c (Fig. Ib), the six-contact segment of the pulse transmitter E 1 and via its contact arm 1039 to the main conductor 920. The trip relay RI-Lt is excited via the contacts of the relays RE, RF, RG and RH , so that the time the excitation depends on the combination in which the relays RE, RF, RG and RH are excited FC sockets manufactured.

In the case of subtraction processes, the numerator of the fraction must be introduced subtractively, whereupon the counter is preset in the manner described. The subtractive introduction of the numerator of the fraction occurs in that the adding magnet AM (Fig. 1 c) is excited by a pulse, the time of which corresponds to the digit which is one less than the denominator value of the fraction. For example, the point in time (ie the machine play segment time) is 5 for sixths, 8 for ninths, 2 for thirds, and so on. Subtraction magnet SM is subsequently energized when the counter value of the fraction is sensed. Towards the end of this machine game, the presetting takes place in the manner already described in order to set the units digit of the counter to the correct value, ie to the preset value 4 in the case of sixths fractions.

Suppose the fraction _^3/6 is subtracted in the units digit of the counter, the counter wheel is set in the basic position of "9". The counter of the ίο fraction is represented on the punch card by the number hole 3; the denominator 6, the relay RF and RG in the in the Fig. 1 c excited manner shown accordingly, and the addition AM magnet unit's place is in the energized time the index item 5 corresponding portion of the machine game. The adding magnets AM of the other counters, ie the tens and hundreds, are excited in the usual way at index time 9; provided that these positions are set up to handle the numerical values of the ao decadic system. After the excitation of the adding magnet AM at index time 5, the counter wheel of the units digit is turned further until the impulse triggered by the sensing of the perforation 3 in the card excites the subtraction magnet SM , after which the counter wheel of the units digit has moved two switching steps. Since the counter wheel for the units digit was originally set to "9", after two switching steps it will then be in position 1. During this rotation, the tens contact of the units digit was closed and a one in the units digit was added through the normal tens transfer process to make the counter wheel for the units digit in to advance position 2 (in the tens digit the tens were carried over in the usual way). In the machine play section following the tens transfer, the presetting is effected in the manner described in order to add the preset value 4. This addition process sets the counter wheel of the units digit to the digit value 6. Since this value is negative, it is converted into the nine's complement in the usual way and taken as value 3 (in reality Ve).

The circuit for the excitation of the adding magnet AM at index time 5 runs from the main conductor 921 via the adding magnet AM (Fig. Ic), the rest side of the contacts R 638 d and RJb, the now closed contact R 297 d, the rest side of the contact RHd, the Switched contacts RGe and RFg, the rest side of the contact REi and via the five-contact segment and the contact arm 1039 of the pulse transmitter E2, the line 1043 'and the breaker contacts CB 1 to CB 4 (Fig. la) to the main conductor 920 corresponding card hole, the subtraction magnet SM (Fig. 1 c) is excited by a pulse that is sent from the main conductor 921 via the magnet SM, the rest sides of the contacts RJα and i? 371i ^ the now switched contact .R 149 c and the rest sides of the contacts R. 223 d and 22445 c to the output socket of the ones place and from this via a connecting cable (not shown) to the corresponding sensing brush socket (Fig. 1 a) and via the white already described direct current path to the main conductor 920 runs.

The counter is reset to "9" or to the basic position in the known manner. In the The above explanation of the processes involved in fractional calculations, the fractional values were from half to Ninths assumed. Fractions with denominators greater than 10 but not prime numbers can be replaced by the Connection of various partial counters and the

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Laying the fraction into partial fractions are dealt with, the denominators of which are the factor values 2 to 9 of the original Denominator are. For example, if a fraction is to be treated with the denominator 12, then this denominator must be used can be broken down into factors, each of which has a value less than 10. In the example chosen therefore the factors can have the value 2 and 6 or 3 and 4. In both cases the product is the Factors 12. The twelfths are thus represented in the form of thirds and quarters or half and sixths. If the first combination is selected, then the tens and units of the partial counter are used set to deal with thirds or quarters. On the other hand, the combination of halves and Sixths selected, then of course the tens and units of the sub-arithmetic unit must be accordingly can be set.

It is also necessary that the numerators of the fractions are converted into other values, such as this for example in Table 1 below for a fraction with the denominator 12 using the denominator factors 4 and 3 is shown.

Table 1

Tens digit Ones place Twelfth counter takes on takes on one-third quarter 1 0 1 2 0 2 3 0 3 4th 1 0 5 1 1 6th 1 2 7th 1 3 8th 2 0 9 2 1 10 2 2 11 2 3

The table shows the possible numerators from 1 to 11 of the fraction with the denominator 12 in the right column and the, as it were, encrypted values corresponding to each counter position in the two left Columns. The encrypted value e.g. B. of the counter 7 is 13, that of the counter 10 is 22, etc. Will be halves and sixths are intended to represent twelfths, the following table applies:

Table 2

Tens
half One
sixth Twelfth counter 0 1 1 0 2 2 0 3 3 0 4th 4th 0 5 5 1 0 6th 1 1 7th 1 2 8th 1 3 9 1 4th 10 1 5 11

For example, the key value 10 applies to the counter 6, the key value 15 applies to the counter 11, etc. The key values for the counters and fractions can be punched directly in the cards or formed from the perforations representing the original shape of the fractions by means of a converter.
An example of how a fraction in one counter group and another fraction in another counter group can be treated in the same operation by controlling punch cards is shown in FIG. 4. In this example, the denominators of the fractions in certain columns of the card and the numerator values are of the breaks punched in other columns of the cards. Of FIG. 4 it can be seen that the punched card A fraction _^3/5 and the map B contains the fraction _^3/6. Both counter groups Acc.l and Acc.2 are provided with sockets FC, 1, 2, 4 and 8 below the assigned counters. The counter values of the fifth fractions are transferred to the register group Acc. 1 and the counter values of the sixths fractions via connecting cable 944 f into the counter group

ao Acc.2 introduced. The preset value for the counter Acc.l is set by means of the contacts PS la and PSIb , which establish connections between the sockets FC and sockets 1 and 4 via the connecting cables PWl, PW2, PW3 and PWi. When this connection is established, the relays RF and RG connected to sockets 1 and 4 are energized and the preset value 5 is entered in the counter Acc. 1 introduced. The contacts psia and PSl b are controlled by a selector relay PSl, which is energized by a "5" pulse of a digit selector DS L, which is connected by means of the connecting cable PWlO with the brush sleeve 942 'in the first sensing station. Therefore, every time the denominator value 5 is sensed in the first sensing station, the numerator Acc. 1 effective to record the counter values of the fifth fraction.

Similarly, the counter takes Acc. 2 shows the numerator values of the fractions with the denominator 6. In this case, the connecting cable PWIl a connection between the brush sleeve 942 of the first sensing station and the input jack of the digit selector DS 2 ago from which of the value 6 corresponding pulse is selected and energized via a connecting cable, the selector relay PS2. The contacts PS 2 α and PS 2 b of the selector relay PS 2 in connection with the connecting cables PWS, PW6 _r PW7 and PW 8 establish connections between the sockets FC and the sockets 2 and 4. As soon as this occurs and pulses are received at sockets 2 and 4, the counter Acc.2 records counter values of the sixths of a fraction.

Fig. 5 shows another arrangement in which

a single counter is used, which can accommodate either fifth or sixth. It should be noted, however, that the cards in which the fractions are punched, in contrast to the arrangement previously described in connection with FIG. 4, are sorted into special groups each containing fractions with the same denominator. Of Fig. 5 it can be seen that the introduction of the sensed in said second sensing station counter c by means of the fractures in the cables, PW15, PW16 and PW17 in connection with the control contact of a selector relay PS3 PS 3 takes place. The movable contact spring of the contact PS3c is through the connecting cable 15 to the PW counter Acc. 3 and the other two contact springs of the changeover contact PS 3 c are connected to the sensing sockets 936 and 930 by the line PW 16 and PW 17, respectively. The numerator values of the fractions with the denominator 5 are introduced via the socket 930 and via the sensing socket 936 the

Introduction of the numerator values of the fractions with the denominator 6. In this case, the sockets FC, 1, 2 4 and 8 in connection with the connecting cables PW21, PJV22, PW2 \ and PW26 represent the numerator Acc. 3 to accommodate the fractional sixth, while the connecting cables PW22, PIV23, PJV24 _: and PJV25 serve to connect the counter Acc. 3 to accommodate the fractional fifths. The selector relay PS 3 is excited by a pulse corresponding to the digit value 5 from the digit selector DS 3, which is connected to a socket 941 of the first sensing station by means of the connecting cable PW2Q. The removal of the in counter Acc. 3, although not shown, occurs before a new set of fractions is introduced.

Claims (4)

PATENT CLAIMS: 1. Arrangement for calculating with number fractions by means of a counter provided for a certain number system, preferably for the decimal system, characterized in that the counter provided for receiving number fractions can be adjusted according to the denominator value of the number fractions, preferably the values 1, 2, 4, 8 relays (RE, RF, RG, RH) are assigned, which cause the input of the complement of the denominator value formed on the basis of the number system used in this counter after the numerator value of a first number fraction has been introduced and after the counter values of further number fractions the capacity of this Meter workstation has been exceeded. 2. Arrangement according to claim 1, characterized in that the switching elements (RE, RF, RG, RH) adjustable according to the denominator value of the number fractions cause the display of the value contained in the counter provided for receiving fractions of numbers minus the introduced complementary value when taking the value. 3. Arrangement according to claims 1 and 2, characterized in that in the initial state (deleted) all counters display the value 9. 4. Arrangement according to claims 1 to 3, characterized in that the input of the values is done by punch cards by a start magnet (AM) couples the counter to the common drive when sensing a hole until mechanical means in a certain section of the machine circulation Disengage the counter and then the tens complement of the denominator value is introduced by connecting the tens transfer contact (2397240 ') via relay (RJ) to the counter intended for recording fractions, until the next machine cycle, via contacts of the relays (RE, RF, RG, RH) controlled, the stop magnet (SM ) is excited by the pulse transmitter (£ 1) and disengages. For this purpose 2 sheets of drawings © 809 657 / 2ΪΪ 9.58