DE1047263B - Circuit arrangement for testing the fee recording devices in telephone systems - Google Patents

Description

GERMAN

The invention relates to a circuit arrangement for testing the fee recording devices in Telephone systems in which the call charges are stored on a magnetic storage drum and multiple subscriber lines are allocated to each memory section. The use of a magnetic drum for these purposes is already known; an example of this is described in patent specification 936 520. While such a register device compared to the more commonly used electromagnetically operated ίο made meters both in terms of the space required and in terms of the ease with which the readings can be taken has considerable advantages, there is a risk that always occurs in facilities that are common to a large number of participants in that an important piece of equipment can become inoperable. This can have a major disadvantage; in this case the stored count records may possibly be completely lost or changed so that they have no relation to the real facts. It is therefore important to ensure an indication of such damage at the earliest possible point in time and steps initiate in order to eliminate the fault or to switch to replacement equipment. The main object of the invention is to provide test equipment for a billing device of this type, which ensures that if an error occurs, the leads to an impairment of the operation of the system, an alarm is given or other equipment is deployed with the least possible delay in order to restore normal workflow, before a significant number of records are lost or the existing records to be mutilated.

According to the invention, pulses are used to test the common billing device in predetermined time periods for testing purposes provided parts of the storage sections of the magnetic drum are sent, these pulses serve at the same time for the step-by-step advancement of an electromagnetic counter, furthermore this pulse recording on the storage section of the drum is compared with that of the counter in a comparison circuit and an alarm is triggered in the event of a deviation. This arrangement becomes the same Equipment used for both testing and periodic record keeping. This one Equipment in relatively short periods of time, e.g. B. every 2 minutes, checked and monitored there is little risk that a breakdown will cause major damage.

Circuit arrangement for testing

of the fee collection devices

in telephone systems

Applicant:
British Telecommunications Research

Limited,
Taplow, Buckinghamshire (UK)

Representative: Dr.-Ing. H. Negendank, patent attorney,

Hamburg 36, Neuer Wall 41 '"-

Claimed priority:
Great Britain 14 October 1955

George Thomas Baker and Victor Edmund Mann,

Taplow, Buckinghamshire (UK),

have been named as inventors

In one embodiment of the invention it is assumed that the records are for one hundred Participants are recorded in a single track and that enough tracks for the required Number of hundred groups are provided. It is also believed that the capacity for each participant is 1024, that is ten elements in binary code. In the same way as in the arrangement according to the cited patent is also here a scanning device with the drum works synchronously, provided in conjunction with each track. This checks the various counting lines successively for the presence of a counting potential. Whenever the scanning device picks up such a potential, a unit becomes the record that relates to the concerned Participant relates, added. For the purposes of the present invention, there is a memory in each disabled group provided for auditing purposes and provision is made for a unit to be added to the record is added at this point depending on the pulses, which in appropriate time intervals, z. B. every 2 minutes. From the same or another synchronous to it working source are additionally on a step selector with only one direction of movement Impulse given whose rows of contacts are wired in this way

809 700/137

are that a binary output signal is generated according to the number of pulses received.

Figs. 1 to 4 show an embodiment of the invention. It shows _{; γΓ}

1 shows a counter consisting of two selectors each with only one direction of movement, whose rows of contacts are wired via coincidence circuits to generate various output signals on the control lines SUM and SUM as a function of the positions of the selectors and the arrival of the control time pulses 7 ¹ X1 to TX10 to create,

Fig. 2 shows a comparison circuit which gives an alarm if a difference between the recording in the test memory section and the positions of the voters are available,

3 shows a control circuit which, when the maximum storage capacity of the storage sections is reached, a Signal triggers,

Fig. 4 is a block diagram for carrying out the invention.

Fig. 4 shows a sampling selector SC, which is shown in the usual way as a selector operating with one direction of movement, but in the practical embodiment can be designed as an electronic selector device in view of the required operating speed, since the operating speed is so high that the selector must grind across all outputs in the time required for one drum revolution. It is assumed that one hundred subscribers are connected to the selector 5 "C. The voter outputs lead to the corresponding counting lines of the subscribers, as indicated by the bracket ML represents blind registers receives counting pulses applied at appropriate time intervals from the source P. The selector SC is connected to the drum control equipment DC and the circuit is such that when the contact arm of the selector SC picks up counting potential from a particular line , adds a unit to the record in the memory section allocated to the subscriber concerned. This is done in a known manner by cooperation between the write head WH and the read head RH. These heads define a track shown in dashed lines on the drum D. substantially the same speed rotated around its axis ht. Pulses from the source P or from another source which operates synchronously are also applied to the electromagnetic counter EC . The setting of this counter can be displayed in the comparison circuit CS at any time. This circuit also receives from the reading head RH an indication of the recording in the storage area on the drum representing the test point,

If the work is satisfactory, the indications given by the drum and the electromagnetic counter, respectively, will be the same. If, however, there is a difference between the two recordings, a voltage is applied to the line L in order to give an alarm and to effect an automatic switchover to replacement equipment, if possible. It should be noted that the drum accommodates multiple tracks and as many tracks are provided as are necessary to handle the number of hundred groups in the office. Conventionally, an incremental selector or equivalent device is provided which sequentially processes the tracks so that the drum control equipment can be shared. Obviously, however, the electromagnetic counters must be provided individually for each test memory section on the various lanes.

The details of a preferred embodiment of the electromagnetic counters will now be given considered, which emerge from Fig. 1. The counter has two working in one direction of movement

ίο selectors A and B , whose rows of contacts are wired in a suitable manner so that the position of the contact arms can be represented by a pulse train in binary code. The selector A is normally driven by pulses transmitted over the line P z. B. be fed at intervals of 2 minutes. Only the first sixteen positions, ie the. Positions 0 to 15 of selector A are wired in such a way that the aforementioned effect occurs. As soon as the selector contact arm moves to position 17 (step 16)

ao is enough, a home circuit is established via the contact arm 1 so that the selector continues to run in its 0 position. The contact arm 2 of the selector A has only one arm, so that it only becomes effective after one complete revolution and thus, after the selector has carried out thirty-two steps, produces a circuit for the magnet of the selector B. This selector is switched one step upstream as soon as the circuit is opened on the selector ^ which has reached its starting position. The selector B is also provided with a home circuit via the contact arm 1. The contact arm 2 is not wired. Only the first sixteen positions of the selector are used, although, as can be seen, the initial states are only reached when the selector has made a complete revolution, since the contact arms 7 and 8 are only one-armed. Accordingly, it takes thirty-two pulses to make one full rotation of selector A and thirty-two revolutions of selector A to make one full turn of selector B. As a result, the starting position is reached again after 1024 pulses.

It can be seen that rows 3 to 8 of the two selectors are wired in a similar manner. In the contact rows 3 the alternately successive contacts are connected to one another, in the contact rows 4 alternating contact pairs, in the contact rows 5 alternating contact groups of four and in the contact rows 6 alternating contact groups of eight contacts. In the contact rows 7 and 8, all contacts 0 to 15 ^ that are used are connected together, but as already stated, they do not work together, since the contact arms 7 and 8 are each only one-armed. The various contact groups are connected to earth via rectifiers, and the contact arms are partly connected to positive potential via a resistor and also to -10 V via a rectifier. The contact groups are also connected to the various timing pulses TX 1 to TX 10 in the manner shown. These time pulses correspond to the various elements 1 to 10 which are used for the binary recording of the total subscriber counting charges. For the contact row 3 of the selector ^ the pulse TX 1 comes into question, for the contact row 4 the pulse TX 2, and in a similar way the pulses ΓΖ3, TJ 4 and TX5 are to the contact

rows 5, 6 and the combined rows of contacts 7 and 8 are connected. Similarly, for the selector B, the pulse TX 6 is connected to the row of contacts 3, the pulse TX7 to the row of contacts 4 and TZ 8 to the row of contacts 5, TX 9 to the row of contacts 6, and TX10 to the rows of contacts 7 and 8. Consideration now shows that, as a result of this arrangement, the T-Y1 to TXIO pulses generate rows in binary code in which the potential corresponds to a one in the binary code on the line SUM and corresponding to a zero in the binary code on the line SUM is created. For each change in the position of the selectors A and B there is accordingly a different output signal on the lines SUM and SUM .

It is emphasized that, assuming that the pulses for actuating the selectors A and B are sent at intervals of 2 minutes each, there are no difficulties with the use of electromagnetically operated selectors of the known and proven type. The resulting wear and tear is not very significant for a large number of years so that voters used in these conditions are extremely economical.

It should be noted that the usual process of changing the record of a subscriber memory is effected in a known manner by the scan selector SC by reversing all binary records until a zero has been changed to a one when counting potential is encountered on its counting line. This circuit also operates on the test memory sections to enlarge the record when a pulse from source P arrives. Fig. 4 shows that the pulse source sends pulses to both the sample selectors 6 "C and to the electromagnetic counter EC . Due to the difference in the operating speed of the circuits involved, it may be practical to use different pulse sources which operate synchronously The circuits are arranged so that only one recording is made with respect to any connection of the counting potential, even if this continues while the scanning device scans the contacts several times.

Fig. 2 shows an embodiment of the comparison circuit CS. This uses an electronic relay or a flip-flop circuit MAA of known design, which can be actuated by each of the two inputs, which contain coincidence circuits. TPM is a common time pulse that can be used to cause the test to be performed at least once for each step at appropriate time intervals. It is emphasized that it does not matter how often the comparison is made, provided that it indicates every change in state. As explained below, it can be useful to change the time interval in which the pulses are sent from the source P.

As previously mentioned, lines SUM and SUM are provided with the normal and reversed output signals from the equipment of FIG. The normal and reversed output signal that has been picked up from the register track by the write head RH are present on the lines SLM and SLM. TZN is a time pulse that is assigned to the test section. Accordingly, when the time pulse TPM is effective and the read head is connected to the test section of the memory, a comparison is made between the output signal picked up by the read head RH and the output signal taken from the two selectors operating in one direction of movement. If there is any difference between the two records, the MAA relay is actuated. As shown, the normal and reversed output signals MAA and MAA lead to the

ίο windings of a polarized electromagnetic relay CR, which accordingly assumes one or the other of its two working positions depending on the state of the electronic relay MAA .

If a discrepancy is detected, the relay Ci? switched and thereby causes a control of the devices connected via the lines AL 1, AL2 and AL 3. In addition to triggering a visual and audible alarm, the switching of the relay CR can also switch on replacement equipment so that there is no risk of another recording being lost. It can e.g. For example, spare equipment could be provided which would keep further records in effect at the time it was used, and that those records would be automatically transferred to the normal register when the fault is cleared and that register is put back into use. The relay CR can be returned to its normal position by means of a switch KAA.

Fig. 3 shows a circuit which indicates when the test memory section has reached its largest storage capacity. It can be seen that whenever a one is present in the first position when the test register is scanned, the electronic relay MBA is actuated. If, however, a zero is later encountered in the test register, which means that this is not yet completely filled, a reset circuit is established for the relay MBA . However, if the record consists entirely of ones, the relay MBA will still be actuated when the next register and the output of MBA, which coincides with the timing pulse TZN, generates a potential at the end terminal RF to actuate an appropriate signal. If this procedure is used in which the next pulse resets the register to zero, the potential is removed the next time the register is scanned. Thus, in the case of binary recording, the counting can be carried out continuously in the manner proposed, and no special return to the normal position is required in addition to the already mentioned home circuit of the voters.

Although a 2 minute interval has been suggested, certain advantages can be obtained by taking a full count every 24 hours. This means that regular impulses occur at intervals of I ¹³ / s2 minutes. On the other hand, the same result can be produced by changing the pulse rate so that it is determined by 2 minute intervals for a certain part of the time and faster for the remainder of the 24 hours, e.g. B. is determined by 1-minute intervals.

It is proposed that the billing records that have been collected can be transferred to a punched tape every 24 hours, and it can be beneficial be to do this around midnight,

if the demand for the office is low. This transfer process can be done when the greatest The ability to record the test memory sections is achieved, corresponding to the circuit according to FIG. 3, or when the counts have reached a predetermined number 5; with the proposed arrangement this would happen every 24 hours. The records that are made on the punched tape can be kept available for testing purposes. It is sufficient if the information is used for billing purposes be used only after longer periods of time, e.g. B. after a week, collected. If the extract is required for this purpose, the information on punched cards will be used for the individual Transfer participants. These cards can usually be of the same type that they are used for single long distance calls outside the range of auto multiple counting can be used. The weekly cards and the individual cards for long-distance calls can then be sorted through a »o machined and evaluated together on a mechanical accounting basis, to prepare the participant invoice.

The invention accordingly provides a device for continuous testing in a simple manner of the billing devices and thus eliminates one of the difficulties which prevent could that the proposed counting system is fully satisfied in the application.

30th

Claims (6)

P A T E N T A N S P R V C H E: 1. Circuit arrangement for testing the billing devices in telephone systems, in which the call charges are stored on a magnetic storage drum and several subscriber lines are assigned to each memory section, characterized in that for testing the common billing device, pulses in predetermined time segments in the parts of the storage sections of the magnetic drum provided for testing purposes (D in Fig. 4) are sent and that these pulses are used at the same time for the step-by-step advancement of an electromagnetic counter (Fig. 1; EC in Fig. 4), and that this pulse recording on the storage section of the drum with that of the counter in a comparison circuit (CS in Fig. 4) compared and in the event of a discrepancy, an alarm is triggered. 2. Circuit arrangement according to claim 1, characterized in that the two rotary selectors (A, B in Fig. 1) existing electromagnetic counter (Fig. 1; BC in Fig. 4) is connected so that the second selector (B) one Step is advanced when the first selector (A) has carried out a full revolution, and that furthermore the contact rows (1 to 8 in Fig. 1) of the selector are wired in such a way that the number of test pulses received is displayed. 3. A circuit arrangement according to claim 2, characterized in that the rows of contacts of the selector are connected via a common output to current gates which are controlled by time pulses (TXl to TXlO), and in that the number of test pulses recorded are displayed in the form of binary pulses . 4. Circuit arrangement according to claim 3, characterized in that the output signal of the test memory section represents binary pulses and pulse by pulse with the binary pulses of the electromagnetic counter (EC) is compared. 5. Circuit arrangement according to claim 1, characterized in that the counting record is transferred from the drum to a punched tape when the record is in the test memory area has reached its maximum. 6. Circuit arrangement according to claim 5, characterized in that the maximum value of the Recording in the test memory area is achieved every 24 hours at a time when the Office is only weakly claimed. Considered publications:
German patent specification No. 929 376. 1 sheet of drawings © 809 700/137 12.58