DE1049436B - Method and arrangement for choosing a free one from a large number of facilities - Google Patents

Description

Since the voters used in telephone systems have the advantage of working quickly If important, these are increasingly being used largely or exclusively electronic means built up. Such electronic voters are already in different versions known or proposed. While some of these electronic voters use the Examination of the individual connected facilities for their occupancy status one after the other, i.e. in terms of time takes place separately and the working hours of these voters thus by the number of affiliated facilities is determined, the examination of all facilities takes place at the same time with other voters, whereby the The working time of these voters is at least largely independent of the number of institutions.

Particular attention should be paid to electronic voters, particularly those mentioned above second group to dedicate to the fact that during an election process that is taking place Subsequently report facilities that were initially still occupied and add these facilities to the Designation sequence can be before the first originally free facility. With the voters of the second group are in the process of avoiding double bookings due to such subsequent release of facilities to prevent special measures.

Such a measure has been proposed in an electronic search dial that uses all it checks connected facilities at the same time for their occupancy status and the facilities transmit the information about their occupancy status in the form of free and occupied potentials. In order to protect against disruptions as a result of the subsequent release of facilities is in every voter level a memory is provided, which is then transferred to the working position in the event of a time-limited release is when the relevant selector stage is supplied from the associated device free potential; In addition, means are provided by which the designation of the chosen institution until after completion the release of the memory can be blocked. Also, in some cases and from different ones Reasons appearing desire, that given by the search dialer as a result of a dialing process To be able to take labeling potential directly from the memory, in such a way that it is taken into account, that means are provided after the end of the storage and before the cancellation Blocking of the designation potential delivery, starting from a certain zero point, all memories in the working position with the exception of the dem Zero point in the designation sequence next procedure and arrangement to choose from

one free from a large number

of facilities

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Dieter Voegtlen, Munich,
has been named as the inventor

Return the storage unit lying in the working position to the rest position.

In order to keep the effort, which is already proportional to a very small number of steps, i.e. the number of facilities included in this, small with electronic voters and not to increase the working hours significantly, German patent application S 50 278 VIII a / 21 a ³ suggested the following procedure. The total number of devices is divided into groups, a group containing at least one free device is selected and designated by a first selection process and one of the free devices of this group is selected by a second selection process. The criteria which are equivalent to one another for a dialing process and which indicate the current occupancy status of the facilities are in each case fed simultaneously to the test inputs of the respective elector who is active. The criteria of all facilities in a group for the first selection process and the criteria for all facilities in the same position in the various groups for the second selection process are to be regarded as equivalent. The advantage of this method is to be seen in the fact that in the arrangement used to exercise it, the number of voter levels required is no longer equal to the number of facilities, but rather the sum of the number of groups and the largest number of facilities in a group can. As the number of facilities increases, this advantage becomes more evident and is optimal for any number of facilities if all groups have the same number of facilities

809 747/121

and also the number of groups switched to the same input sb . The anodes each correspond to the number of devices in a group. 'Same column associated tubes Tl are over

The aim of the inventive directional guide G 3 described below, summarized by means of a contradicting method and the arrangement serving to exercise this status J? 5 to the positive pole + Ub of the operating method, is to apply the principles 5 voltage source and via a capacitor C 2 in the two above-mentioned patent applications, the anode of a tube T2 assigned to the column in question to be combined in a particularly advantageous manner. Each of these tubes T 2 is anode-free and thus double-occupancy-free implementation from the side via a resistor R 6 and a contact r selection processes with the least possible effort to ensure the arrangement required at the positive pole + Ub of the operating voltage. io source and cathode side via a resistor R7. This method according to the invention initially has the features of the negative pole already mentioned above with a parallel-connected directional conductor G 4. In addition, everyone's cathode is driving; each of the two dial-up these tubes T2 thereby necessary via a capacitor C 3.an the operations here is the sequence of functions based anode of the respective preceding tube T2 he gewie for also aforementioned search selector 15 coupled with the T 2 for the first tube last is indicative. The distinguishing feature of the foregoing applies. The cathodes of the method according to the invention in each case consists in the fact that with the same column associated tubes T1 are combined via a coordinate combination of the one-directional conductor G 5 and via a memory associated with the directional direction and stand i? 8 at the ignition electrode of the tube T2 of the Column storage in which a column in each case has a subsequent column, with the last group of devices comprising the first column being the previous one. The Zündelek-Wählvorgang all in working position electrodes of all tubes Γ 2 are coupled via individual column memory with the exception of the column memory, capacitors C 4 to a selector control input swl of the relevant zero for this selection process. The points that are closest to each other via the directional conductors G3 and G5, combined back into the rest position, are fed individually to the devices, and through the second pre-selection memory with the tubes T 1, all of the lines in the working position are formed in each case a column store. This column memory, with the exception of the line memory, which is used to store the zero point at the reset level, which is equipped with the tubes Γ2 and which is next to each other, is individually assigned to the store, which forms the column reset device, whose activity, An arrangement that this Exercise procedure as later in. will be explained in detail below, via which selection is allowed, the control input swl can be triggered in the following with reference to the figure. In the same purifies. The figurative representation is limited to the extent necessary for understanding how this column resetting device is. A line resetting device is constructed, the individual of which is pointed out that neither the method 35 resetting stages are equipped with the tubes T 3 and nor the arrangement used for its exercise, as an example, the arrangement shown via its own selection control input sw 2 in the example can be. Each of their resetting of the number of devices, among which one level is a line of the devices individually selected -should, in a memory associated with telephony duel with the tubes T1 associated system framework "and that also 4 ° orders, with the Line formation by anode and, as in the procedure mentioned in the introduction, the interconnection of the corresponding parts on the pre-cathode side, the more the greater the number of devices in the tubes Π by means of directional conductors G6 and G7 The row is based on a defined designation sequence starting from a specific resetting device in the same way as the zero point.

Borrowed zero points can be added by a control device via the directional control G6 and G7.

device can be determined independently or in mutual combined memory with the tubes T 1 form dependency. together with one line memory each. Heard with it

Each device is assigned a memory which contains 50 each memory assigned to a device equal to a cold cathode tube T 1. The ignition electrode is connected to a specific column memory and to each tube T1 via a conventional line memory that is specific to protection. The division of the Gestand and one of a resistor R 1 and a total number of devices into groups is connected to the directional guide G1 existing electronic switch to summarize the memory assigned to them in a test input p , identical to that of the train 55 columns. The contacts r and t of the two hearing devices that their occupancy status are supplied to reset devices are used to determine the potential shown. The cathode of each zero point and thus the definition of the designation tube 7 "1 is via a sequence of a resistor R 2. They are controlled by their own electronic device (not shown in the figure and a directional conductor G2), switches to a designation output ζ and over 60 that in each of the two resetting devices only one resistor R 3 with a parallel connected single contact is opened, whereby, as can be seen in later densatorCl at the negative pole of an operating point, the voltage source connected to this contact is connected whose positive pole is ordered column or row to the first in the loading + Ub the anode via a resistor 7-4 drawing sequence. As already mentioned, for the sake of clarity, the two 65 can control the contacts in both electronic reset Switch each tube Tl only in one device independently or in opposition igen tube shown. The directional director Gl all-sided dependency take place.

licher memory are connected to a common memory.

control input .m and the directional ladder G 2 all standing, according to the arrangement explained execution memory an example of a common designation control 70 initially explained in general form.

V 04 # 43θ

5 6

In the idle state, all tubes T1, T2 and with the ignition of the T 3 provided with free potential are extinguished. A tube T1 is fed to the memory control input Ji for storing the occupancy potential, which is considerably below the ignition state of the ignition potential of the tubes T1 on the one-electrode side connected to the selector; directions ended. In all of the devices, the designation control input sb is assigned a potential 5, to which the associated inputs are fed, which is approximately equal to the potential of the negative direction during the duration of the storage pole of the operating voltage source. control input Ji supply part pulse free potential

Free devices lead to the test inputs p , now the tubes Tl burn. Each column of the selector stages assigned to them positive potential memory and each line memory that contains at least one tiale, which contains the tube T1 burning for the ignition electrode side, prepares the tube T2 of tubes Tl required minimum value above or T3 of the reset stage that rise to the following. Because of the low potential of the memory, the column or line memory is assigned. The directional conductors G 1 are permeable as input jj, next one of the free devices is now to be selected from the high potentials supplied through the test inputs p , which, as a characteristic feature already mentioned by the resistors Rl, an amplitude reduction 15, by two selection processes in this way learned that they should do the ignition of the appropriate that initially makes unsuitable through the first dialing tube. gang all at least one burning tube Tl

A positive column memory, with one exception, is fed back to the memory control input jj, the amplitude of which is at least 20 returned to the rest position and then reached by a potential value that a tube Tl to the tip - the second dialing process requires the same process with regard to manure, the amplitude reduction that the line memory is repeated,
the Prüfeingängen p supplied free potentials up to carry out the first selecting operation is lifted, whereby the tubes Tl with the free choice of the potential control input sw'l a positive pulse zuversehenen guided facilities associated memory 25th This will ignite in all reset stages. The duration during which the tubes can ignite via the capacitors C 4 to the ignition electrodes of the T1 is determined by the duration of the storage tube T2. The pulses supplied to the control input ss thus ignite in a limited manner from these tubes T2. After those who precede the burning tubes Tl-termination of this pulse, the column memory is prepared which occurs late; An off-free potentials remain ineffective, so that the temporal 30 would only form the tube whose anode limitation of the storage is guaranteed. With side contact r is open. The ignition of one of the ignited tubes Tl occur at its cathode tube TI can now result in two processes, with resistances i? 3 positive voltage jumps, one of which always occurs, the other only with the amplitude of the condensate connected in parallel when the C1 allocated to the igniting tube T3 is charged. The associated column storage tanks contain at least one burning tube drawing outputs ζ but contain about the potential. As already mentioned, when burning the tial value of the designation control input sb with a tube T1, the associated capacitor C 1 is charged, that is to say approximately the potential of the nega- tively charged. Due to the interaction of the anode tive pole of the operating voltage source, because the negative high cathode potentials of burning tubes Tl 40 occurring in the igniting tube Tl 40 direct voltage jump, which is now permeable via capacitor C 2 because of the permeable directional conductor G 2 under the and the corresponding, now permeable Directional conductor influence of the resistors R2 is sufficiently lowered (73 is transmitted to the burning tube Tl, and are. The cathode-side voltage jump of one of the voltage to which the already igniting capacitor Cl also reaches the tube Tl is charged, is the directional conductor G between the anode and cathode 5 and across the resistor i? 8 to the ignition 45 of the burning tube T1, the voltage below the electrode of the tube T2 of the reset stage that is assigned to the minimum value required to maintain a gas discharge via director G 7 Rö Your Tl is deleted and its capacitor Cl to the tube T3 of the reset stage that discharges the resistor R 3. In this way, the following line memories are allocated in each case. By igniting a tube T2, all of the column accumulators G5 and Gl placed under load, burning tubes Tl ge such a voltage jump through the cathode extinguishes and thus this column accumulator is returned to the resistors R 3 of non-ignited tubes Tl and a rest position . This is the result of the decoupling of the column and line memories. The burning of the corresponding tubes T1, expressing the amplitude of this voltage jump, is chosen so that the coming storage of the free state of the fact that the tubes T2 and T3 are only used for the ignition devices that can be prepared by this column memory. At the same time as belonging to the cathode-formed group, the reverse voltage jump occurs again when a power is ignited. This extinguishing process only takes place in the working tube T1 at its anode in a negatively oriented column memory with a voltage jump due to ignition. Since the tube T 2 comes into operation for this voltage jump 60, the associated resetting stage via resistor R 5 takes place. The directional conductor G 3, which is biased when igniting a tube T2 setting stage, has a blocking effect, and negatively occurring at its anode resistance R 6, it is not transmitted to its tube T2. The directional voltage jump is also supplied in the same way via the corresponding resetting stage, in which it, by standing the associated line resetting stage of the rectifier, blocks the capacitor C 3 to a negative pulse diverter G 6 and thus forms a transmission of the , appears at the cathode of tube T2, anode-side voltage jump to its tube T 3 Its amplitude is chosen so large that it prevents this. The task of the directional conductors G3 and G6 is also the ignition of the tube T2 if it has not been prepared for the decoupling of the column and the foregoing column memory as well. The line memories. 70 ignition of a tube T2 on the cathode side

again results in a negatively directed voltage jump at its anode resistor R 6, which is transmitted to the following tube and in this tube T 2 ignites, if it is not ignited immediately on the ignition electrode side due to the supply of the preparatory voltage to its ignition electrode by the pulse supplied to the selection control input sw I became. In addition, the voltage jump on the anode side of this igniting tube T 2

memories a, c and d are in the working position. In the case of the column reset device, contact r or t should be opened in the reset stage assigned to column memory A and in the case of the row reset device in the reset stage assigned to line memory b 5, and the zero point should be set accordingly. Corresponding to the column accumulators A, B and E in the working position , the tubes T2 B, T2C and T2A are used for ignition on the ignition electrode side

if necessary, the column to which is assigned to it has also been prepared. On the basis of this preparation, the memory is ignited by extinguishing its burning tube Tl when the first dialing process is supplied, returned to the rest position. The task of the directional conductor G4 assigned to each of the impulses to the selector control input sw 1 of the tubes tube T2 is to trigger T2B and T2C directly, while this ignition provides the required for the cathode-side ignition of the tube T 2 A because of its open anode-cathode resistance R 7 for the with after ignition 15-sided contact r does not occur. The ignition tube in the tube current flowing to short-circuit and T2B now deletes the burning in the memory Ba tube thus the formation of the largest possible chipboard Tl and hence to the column memory B in the voltage jump at the anode resistance R6 to enable rest position. The ignition tube T2C ignites borrowed. the tube T 2 D and this in turn the tube T 2 E,

After completing the above, initially with regard to 20, which now clears the tube T1 of the memory Ed. After its general sequence explained first selection sequence of this process, through which the column process burn only in a single column memory B and E returned to the rest position, memory one or more tubes T1, accordingly, burn from the tubes T1 only which the free state of the facilities, which the by the stored and ad. Belong to the group thus formed in this column memory. The line memories c and d located in the working position All other column memories are prepared for ignition in the line reset device by deleting the tubes of the tubes TZd and TZe that were ignited during storage. In Alloca- Tl returned to the rest position. The second generation of the Im-dialing process that causes the second dialing process, the result of which is the selection of a free pulse to the dial control input sw 2 , so that the group selected by the first dialing process can be these two tubes T3 d and TZe , all of them are now Line ignites, with which the tube TZd deletes the tube Tl of the memory, which are in the working position, with a memory Ad and thus , as a single exception, returns the line memory d to the rest position. the rest position returns. The tube TZe ignites the each tube TZa in the working position, which in turn is unable to ignite the tube TZb because of the line memory only a single burning tube 35 opened contact t. After T1, which lies in the sequence of this second dialing process and thus of the selected group as a result of the first dialing process. Since the second pre-selection process only burns the line of all line memories with the exception of a tube T1 of the memory Ac.

can only be returned to the rest position, the two dialing processes explained above

after completion of the second selecting operation show only 40 that the burning regardless of the number at Eineine single tube Tl as storage for clearly- the occupancy status in the working position

transferred column and line memory for each individual dialing process always only a single column or. Line memories not returned to the rest position, the reset stages of which are operated by the tubes TZ and that these are always the column pieces. After completion of the first selection process or line memory, the reset stage of the

Contact r or t is open or which is closest in a given sequence to this reset stage containing the open contact. The execution of the second dialing process is the selection sequence is supplied by the interconnection of control input sw 2, a positive pulse on the column or line memory with the reset between the line memories and the stages and the interconnection of the reset stages line reset device the same processes determined from one another. This guarantees unambiguous column storage and the column resetting device 55 both for the game and in general for the first as well as for the second selection process. The functional sequence at an explained. After this second selection process, order with any number of column and line burns, as already stated above, only one memory, any position of the zero points in the two single tube T1, whereby a very specific, still reset devices and any combination of free device is designated . the free and occupied states of the connected

The above general explanation of the entire 60 devices can be further illustrated with the aid of a simple, typical operating case derived without difficulty from the dialing process explained above.
For this purpose, the following is an arrangement with five
Saving rows is considered to be the total
twenty-five facilities are attached. 65 or t of the reset stages can, according to the If the columns with A, B ... E and the lines with the scheme, consequently always only a single contact r a, b. . . e are designated, so should be done after completion or t is open, expediently by a relay of the storage in the memories Ac, Ad, Ba and counting chain, in which a relay is always energized Ed the tubes Tl burn and accordingly and the z . B. with each dialing process the column memory A, B and E and the line 70 is switched on by one step. Since such relay counting chains

ability of the result of the two dialing processes is required. For the return of those in the working position Line memory is used by the line reset device

Of these tubes TZ, only those are prepared in whose previous line memory a tube Tl is still burning. To get through.

The control of the setting of the zero point :; in each reset device serving contacts r

are already known, there is no need to go into details.

From the foregoing explanation of the operational sequence in a particular operating case results in further a generally valid condition for the duration of the two selection control inputs and JW1 sw 2 pulses applied. Only through these pulses and thus only during their duration are the ignition electrodes of the tubes T 2 or Γ 3 so strongly biased that these tubes can be ignited in the event of a cathode-side potential drop as a result of the ignition of the tube T2 or T 3 of the previous reset stage. If only the column or line memory whose assigned reset stage contains the opened contact r or t , and also only the column or line memory that is furthest away in each case have been transferred to the working position, then in the course of the two Dialing processes all tubes T 2 with the exception of the tube whose ignition is prevented by the open contact r , and all tubes T 3 with the exception of the tube having the open contact t are ignited. The time required for this in each reset device determines the duration of the pulse supplied to its selection control input szv 1 or sw 2. In this connection it is pointed out that the successive ignition of the tubes T 2 and T 3 can take place at the highest possible speed and that no time conditions that are mandatory for any delays need to be taken into account.

If cold cathode tubes are used in the resetting devices, which can be operated with a high operating voltage Ub when the ignition voltage requirement on the ignition electrode side is low and the operating voltage is low, the above condition may not be required for the duration of the pulses causing the selection processes. When using such tubes and suitably dimensioned, it is sufficient to ignite the tubes T2 or T 3 prepared by the column or line memory with the pulse fed to the selector control input swl or sw 2; the voltage jump occurring at the anode resistance of each ignited tube can then be made so large and its load given by the cathode resistance of the respective following tube so small that this tube ignites even when its ignition electrode has already decayed due to the decay of the selection control input sw 1 or sw2 supplied pulse again has the potential of the negative pole of the operating voltage source, which is communicated to it from the preceding column or line memory, which is in rest position.

After both dialing processes have elapsed, the device determined by these dialing processes is supplied with the potential used for its designation. The designation potential is the cathode potential of the only tube TX that is still burning after both dialing processes have elapsed, which, like the cathode potentials of all tubes T 1 ignited in the course of storing the occupancy state, during the storing and during the dialing processes under the influence of the designation output ζ upstream Resistance R2 is reduced very sharply in terms of amplitude. The low potential supplied to the designation control input sb , on the basis of which the directional conductors G 2 are permeable, is decisive for this reduction. To output a designation potential, the designation control input sb is supplied with a positive potential which is approximately equal to the cathode potential of a burning tube T 1 and thus, by blocking the directional conductor G 2, cancels the decrease in amplitude at the cathode potential supplied by the still burning tube T 1. In this way, the cathode potential of the memory containing the burning tube occurs at the designation output ζ of the burning tube Π as the designation potential.

ίο After finishing the designation of the selected The device is to trigger the arrangement and thus make it available for a new dialing process. These It is triggered by 'extinguishing all tubes that are still burning. The necessary means and their insertion is assumed to be known.

As can be seen from the foregoing description, a complete dialing process comprises four reqs of their beginning and their duration defined steps: the storage of the occupancy status of the.

closed facilities, the first dialing to determine and designate the given one The group containing at least one free facility, closest to the first zero point, the second selection process to designate the closest facility to a given zero point in the group determined by the first dialing process and finally the group used to designate this facility leading delivery of a designation potential. The time separation of these four steps is this ensures that the first dialing process only begins when, with regard to the state of the d ^ .. Connected facilities associated memory no more changes can occur that the second dialing only takes place after a specific group of institutions has been named and there & the delivery of a designation potential only takes place when the result of the entire dialing process unambiguous and no longer subject to changes. '

In the embodiment shown in the attached figure and explained in the description above, the two reset devices operate with a variable zero point and thus with a changing sequence of names. If it is desirable, each of these resetting devices can be modified without difficulty in such a way that the relevant selection process is based on a fixed zero point and thus a constant sequence of names. In this case, the first reset stage can be omitted in the corresponding reset device because, as can be seen from the above explanation, the first column or line memory differs from all other column or line memories in that it cannot be returned to the rest position . For all reset stages, the contacts r or ί that are no longer required can then be replaced by permanently connecting the operating voltage source.

The above description is restricted to the explanation of an exemplary embodiment in which cathode tubes are used. In their place, gas discharge tubes with a heated cathode can easily be used. The coincidence current gates, which are equipped with at least two ignition electrodes and only ignite when corresponding voltages are supplied to these two ignition electrodes, are particularly advantageous in these heated tubes. When using such tubes at the location of the tubes T 1, the task of the resistors Rl and the directional conductors Gl can be

809 747/121

standing coincidence circuits can also be taken over by the tubes, for which purpose the test inputs p are to be connected to the first ignition electrodes of the individual tubes and the memory control input jj to the combined second ignition electrodes of all the tubes. Similarly, when using such coincidence current gates in the two resetting devices, the preparatory voltages can be fed to the first ignition electrodes of the individual tubes and the pulses controlling the dialing processes to the combined second ignition electrodes of all tubes are each fed to a resetting device. Another possible modification of the embodiment shown in the figure consists in the ignition of the tube of a reset stage by the ignition of the tube of the previous reset stage not on the cathode side in the reset devices, but in the same way as the ignition of the tube during preparation by the preceding column or reset stage. Line memory on the ignition electrode side. To do this, each tube has to be preceded by an "OR" circuit, the two inputs of which are supplied with the preparation voltage supplied by the corresponding column or line memory and the ignition voltage supplied by the tube of the previous reset stage, which is now to be taken from its cathode resistor. In this case, the directional conductors on the cathode side of the tubes in the restoring steps are to be omitted. This modification is preferably applicable when using gas discharge tubes with a heated cathode, which differ from cathode tubes in that they require little control voltage. These and similar measures can all be carried out with known means.

Claims (15)

Patent claims: 1. Procedure for choosing a free facility from a large number of facilities divided into groups, in the one containing at least one free device by a first dialing process Group is selected and designated and one of the free ones by a second selection process Bodies of this group is chosen and the . ■ equivalent to one another for a dialing process, the current occupancy of the .. facilities indicating criteria at the same time the test inputs of the respective in ; Activity stepping voters are fed using the facilities assigned Save the time-limited release by the connected facility Her subsequent supply of free potential can be transferred into the working position, using of means through which the delivery of a ■ designation potential to the chosen institution until after the release of the memory ., is blocked and using means, After the end of the storage and before the blocking of the designation potential delivery, starting from a certain zero point, all: stores with the exception of the one in the working position closest to your zero point in the designation sequence that are in the working position are returned to the rest position, characterized in that with coordinate-like combination of the memories assigned to the devices into row and column memories, in which each column comprises a group of devices, by ^: Zero point is closest, are returned to the rest position and that all line memories in the working position with the exception of the line memory, which is closest to the zero point relevant for this selection process, go to rest due to the second selection process age. 2. Arrangement for performing the method according to claim 1, characterized in that the Column memories and the line memories are each assigned a common reset device, the number of reset steps corresponding to the number of columns or rows is subdivided, and that the memories belonging to the same column or row for the formation of columns or. Line memories connected in parallel on the output side with respect to the respectively assigned reset stage are. 3. The method using an arrangement according to claim 2, characterized in that that every column or line memory in the working position has the reset stage of the following Prepared column or line memory for activation that each activated reset stage one Column or line memory, the reset stage of the following column or line memory is activated and, if necessary, their own column or line memory in the working position Rest position leads back that in the first column or line memory in the designation sequence the return to the rest position if the working position is present and if the the reset stages assigned to these two memories, the activation of the reset stages of the each following column or line memory is prevented and that all prepared Reset stages of the reset device assigned to the columns or rows, each at the same time to be activated. 4. Arrangement for performing the method according to claim 3, characterized in that each memory associated with a device contains a cold cathode tube (TV) , the ignition electrode of which via a resistor (RV) to a test input (p), which is used to supply the occupancy status of the associated Device indicating potential is used, and is connected via a directional conductor (Gl) to a memory control input (ss) common to all memories, which is used to supply a potential that controls the storage. 5. Arrangement for performing the method according to claim 3, characterized in that each memory associated with a device contains a coincidence gas discharge tube equipped with a heated cathode and at least two ignition electrodes, the first ignition electrode of which is connected to a test input (p) which is used to supply the occupancy state of the associated device is used, and the second ignition electrode is connected to a memory control input (ss) common to all memories, which is used to supply a potential that controls the storage. 6. Arrangement according to claim 4, characterized in that in each reset stage both return Control devices a cold cathode tube (T 2, T 3) is provided, the ignition electrode of which is connected via a decoupling means (C4) to a selection control input (sw I, sw 2) common to all reset stages of a reset device, which is used to feed all prepared tubes (T2, T3 ) is used for the reset stages of the respective associated reset device triggering pulse, and that the ignition electrode of each of these tubes (T2, T3) is preceded by a resistor (RS) , via which it receives the preparatory voltage output from the preceding column or line memory is fed. 7. Arrangement according to claim 5, characterized in that a coincidence gas discharge tube equipped with a heated cathode and at least two ignition electrodes is provided in each reset stage of both reset devices, the first ignition electrode of which is connected to a selector control input (sw 1, sw 2) common to all reset stages of a reset device serves to supply a pulse which ignites all prepared tubes of the reset stages of the respective reset device, is switched and whose second ignition electrode forms an input via which the preparatory voltage from the preceding column or line memory is supplied. 8. Arrangement according to one of claims 4 to 7, characterized in that the cathodes of the tubes (Tl), each equipped with a cathode resistor (R 3) of the memory, are combined in columns via the first directional conductor (G5), each to the resistor (RS) , via which the preparation voltage is fed to the tube (T2) of the reset stage of the following column memory, and combined line by line via a second directional conductor (G 7), in each case to the resistor via which the tube (T 3) of the reset stage of the respective following line memory supplies the preparation voltage is supplied, are switched. 9. Arrangement according to claim 8, characterized in that the anodes of the tubes (Tl) each equipped with an anode resistor (i? 4) of the memory are combined in columns via first directional conductors (G 3), the collecting points of which via individual resistors (R 5) to the positive pole (+ Ub) of the operating voltage source and via individual capacitors (Cl) to the anodes of the corresponding tubes (T 2), each equipped with an anode resistor (R 6) , of the reset stages assigned to the columns, and line by line via second directional conductors (G 6), whose collecting points are connected via individual resistors to the positive pole (- \ - Ub) of the operating voltage source and via individual capacitors to the anodes of the corresponding tubes (T 3) of the reset stages assigned to the lines, each equipped with an anode resistor are, and that the cathode resistor (R 3) of the tube (Tl) of each memory, a capacitor (C 1) is connected in parallel. 10. Arrangement according to one of claims 6 to 9, characterized in that in each reset stage the tube (T 2, T 3) is equipped with a cathode resistor (R7) and an anode resistor (R 6) and that the cathode of each of these tubes ( T 2, T 3) a capacitor (C 3) is connected upstream, via which it is supplied with the voltage that causes ignition and is output by the respective preceding reset stage, and that its anode has an output for outputting the tube (T 2, T3) of the respective following reset stage forms the igniting voltage. 11. Arrangement according to one of claims 6 to 9, characterized in that in each reset stage the tube (T 2, TS) is equipped with a cathode resistor (R7) and that the cathode has an output for the output of the tube (T 2, T 3) the following reset stage forms an igniting voltage. 12. Arrangement according to claims 8 and 11, characterized in that an "OR" circuit is connected upstream in each reset stage of the tube (T 2, T 3), the two inputs of which are used to supply the preparation voltage output from the preceding column or line memory and the voltage emitted by the preceding reset stage and used to ignite the tube (T 2, T 3). 13. Arrangement according to one of claims 4 to 12, characterized in that in each memory associated with a device, the tube (Tl) is equipped with a cathode resistor (R3) to which a designation output serving to emit a designation potential is connected via a resistor (R2) (2) is switched, and that the designation outputs (z) of all memories are connected via directional conductors (C2) to a common designation control input (sb) which is used to supply a potential that controls the designation potential output. 14. Arrangement according to one of claims 6 to 11, characterized in that all reset stages of each reset device form a ring circuit that a contact (r, t) is inserted in each reset stage in the operating voltage supply of the tube (T 2, T 3) and that means are provided for each resetting device by means of which these contacts (r, t) are controlled in such a way that only a single contact (r, t) is always open in each resetting device. 15. Arrangement according to one of claims 6 to 11, characterized in that a first Column memory and a first line memory are provided, to which no reset stage is assigned is, and that those assigned to the remaining column memories and those assigned to the remaining line memories Reset stages each form a chain circuit. 1 sheet of drawings © 809 747-121 1.59