DEI0008436MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: March 23, 1954. Advertised on May 3, 1956

GERMAN PATENT OFFICE

The invention relates to a control device for multiple memories in telecommunications, in particular telephone systems in which the memory is divided into individual separate sections and the sections are divided into individual elements and the individual sections with the help of control circuits dispatched in cyclical order.

If, for example, the known drums with magnetisable ones are used for the storage units Tracks, as well as recording and playback heads, are used for such arrangements the merit of a relatively large storage speed and capacity. The record of messages through magnetic impressions, soft appropriately after the binary system takes place, besides the advantages mentioned, has the shortcoming that in the event of faults, for example in the power supply or in the control circuits wrong identification and thus wrong Messages are saved.

In order to eliminate this deficiency in a simple and reliable manner ^l , an arrangement is proposed according to the invention in such a way that one of the memory sections is used as a control section in such a way that it is correct

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Work of the associated control circuit alternately with one of two possible pieces of information (ζ. Β, - positive or negative. magnetization) and that this information in a comparison device with an 'inevitably changing P call identifier and compared the faulty operation of the control circuit is displayed by the comparison device will.

ίο Through this particular control section will every switching function checked during the storage and playback processes, so that in the case of Incorrect storage an alarm device is actuated and, if necessary, a replacement memory in

Function can be brought. . - ■

According to a further development of the invention, in the event of an incorrect imprint or incorrect evaluation a distributor through a control circuit jointly assigned to a multiple memory, which periodically switches on the test organs to the individual memory, shut down and thus an identification of the memory concerned made.

The invention will now be based on exemplary embodiments with the aid of FIGS. 1 to 6 described. Here shows

Fig. Ι the basic diagram of an embodiment

example, in which the storage section by a .Magnetspur on the circumference of a rotatable Drum is formed,

Fig. 2 control circuits connected to the system of Fig. 1,

3 shows a basic diagram of an exemplary embodiment in which the memory is a mercury delay line QVL,

4 shows the basic diagram of an embodiment in which a cathode ray tube is used for the memory is used,

5 shows the principle diagram of an exemplary embodiment, wherein the memory is represented by a ferromagnetic matrix, and

6 shows the basic diagram of an exemplary embodiment, the memory being formed by a ferroelectric matrix.

The one used in the embodiment of FIG The brass drum has a magnetic skin on the circumference and is powered by an electric motor driven at a constant speed of 3000 revolutions per second. the Magnetic skins, which can consist of finely divided nickel powder, are composed of a number of components Assigned recording and playback heads. For each composite recording and playback head belongs to a track located on the circumference of the drum, with the playback or scanning part of the head before the recording or storage part is arranged. The recording head is used to receive messages in the form of a Record sequence of uninterrupted saturated longitudinal magnetizations of one or two polarities.

Each memory track on the drum is in one Divided into number of independent memory sections.

These memory sections appear one after the other on the associated recording and playback copies.

In Fig. 1, the drum 1 now shows three Storage tracks 2, 3, 4 with the associated composite recording and playback heads 5, 6 and 7. These tracks are really close together on the surface of the drum and provided with no special visible mark. This means that the drum , must be precisely adjusted in their journal bearings, which have negligible longitudinal play.

A common control circuit is connected to each recording and playback head, wherein in FIG. 1 only the common control circuit belonging to the assembled head 7 8 is shown. This circuit works in sequence with all of the storage sections Track together, and when a storage section under the head is over, the common becomes Steuerstromkrae 8 in its zero or rest state deferred. Therefore, when the next memory section appears at the head, the Work together again with the relevant section in the control circuit.

The majority of the switching operations caused by the common control circuit 8 are by pulse trains recorded on other tracks located on the surface of the drum are controlled. As already stated, each track consists of a number of independent ones Memory sections, and it is now assumed that ten such memory sections are provided. Each track contains a further section, the purpose of which is described in more detail below will. This results in eleven sections per track. Because these sections are on the trail do not bear any visible markings, a control track 9, the so-called marking track, is provided. This has a marking recorded along the track, that of the first element position each section corresponds to a track. The marking track is assigned to all memory tracks together.

A playback head MH, the so-called marking head, belongs to the marking track 9. The output voltage of this head is applied via an amplifier MPA to a counter MPC , which also has eleven units, corresponding to the number of sections located on each track. If now z. B. the first section of a track moves past the associated head, MPC has operated its unit no. 1, while: the other units are at rest, ie the unit belonging to each section is always operated.

To ensure that the counter MPC and the marking pulses of the track are in step, the marking track has a second record which corresponds to the second element position of a section, ie it immediately follows the marking for the section in question. This is evaluated by the circuit and used MPC MPC 1 after each revolution on reset.

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There is also a second control track on the drum, the so-called clock pulse track, on which a marking is recorded for each element position. These recordings are scanned by a playback head CH and fed to a counter CPC via an amplifier CPA. This counter has a number of units which corresponds to the number of element positions per section or, if not all sections are of the same size, is equal to the largest number of element positions in a section. This does not lead to inaccurate or incorrect control, since the clock pulse counter is controlled back to its first position CPCi 'by each marking pulse. Where all sections are the same size, this switch is only a check that CPC is reset to CPC ι for the next section.

Further control pulses are derived from one or both of these pulse sources. If such a switching process is to be initiated in the element position 3 of a section, this switching process can only be carried out when the counter CPC operates its unit 3 and its output CPC 3 is live.

As has already been stated, the common control circuit 8 works one after the other with the track sections. In the system for which the present invention was developed, the sections are each assigned to one of a number of upstream circuit devices and are used to count the electrical pulses received by the respective circuit devices. Each such pulse sets one of the terminals UTi to UT 10, which correspond to the "calling" switching devices, under voltage in a known manner.

Between the terminals UTi to UT 10 and the common control circuit there is a set of ten gates G 1 to G 10. These gates are shown as circles with a number that corresponds to the number of control lines, with each gate only having a single output. Each control line is labeled with its respective source. If all the control lines of a gate are energized at the same time, the gate in question opens.

This shows that each gate emits an output pulse when the element is in the first position a section is located under the head 7, and a counting pulse on the input line the corresponding upstream circuit device is located. Because of this, can these gates can be said to be an electronic equivalent of a viewfinder switch. When a gate releases a 'signal, causes the common Control circuit that everything stored in the corresponding section is carried out by the head 7 sampled and with the addition of a one. or a pulse through the recording head 7 again is recorded. This is done in a known manner, it should also be noted that a pulse is only added once, even if a signal is transmitted over several revolutions of the drum consists.

The main invention feature now consists of a circuit arrangement for checking the switching processes of circuit 8. The already mentioned further section per track serves this purpose.

The entrance gates of the circuit 8 are assigned a special gate G ι ι, which is prepared once per revolution of the drum 1 by two control lines from MPC 11 and CPCi, ie at the first element position of the eleventh section. The third input of the gate 11 is a test input T. This input is always under voltage, so that with each revolution of the drum a pulse is added to the section used for test purposes. If, as in the above-mentioned system, circuit arrangements are provided which ensure that a pulse which exists for more than one revolution is only added once, then the relevant. be excluded from this test process. However, this is done under the control of MPC11 ; switching means are provided which cancel this switching function when MPC 11 is live. The test circuit can also be designed in such a way that the exclusion of this function is tested.

From the above it can be seen ¹ that every time the check section appears at the header 7, "one" is added to the relevant content. Since the recording in the system to which the invention relates takes place according to the binary system, the first element position of the section alternates between one and zero in sequence if the addition is carried out correctly. The test section can therefore only consist of one element position.

The output voltage sampled by the head 7 is fed to the common control circuit 8 and to a comparator 13 via a gate G 12, which only opens at MPC 11. This emits an output voltage in order to activate an alarm device 14 if the comparator detects an incorrect switching process.

When several storage tracks are located on a drum with a single control circuit which can be assigned to any lane via certain gates, the comparator is assigned to the tracks one after the other for every two drum revolutions. Such an arrangement is shown in FIG.

Since the relevant tests are carried out by assigning test devices to each lane for a period of two revolutions, a further lane selection counter TC is provided. This is controlled via a gate G 19, which will be described later, from a distributor via a bistable multivibrator DT, which is switched by MPCi of the marking pulse counter. This shows that each output of TC is energized for two revolutions of the drum. The single test gate Gn

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the Fig. ι is through a number of goals, z. B. G 20 replaced, which corresponds to the number of memory tracks. Each of these ports has four expensive lines: T, the output of TCi, CPCi and MPC 11. It has been assumed herein that the test memory section is always section number 11 of a track, but this need not be so. If any other section is used, the control of the respective test gate must be changed accordingly. The outputs of the test gates lead to the common control circuit.

Common to all tracks is a splitter in the form of a flip-flop CA-CB, which controls two anode base amplifiers CFCA and CFCB, which generate the output pulses CA and CB.

Each track is provided with a bistable multivibrator MA-MB , in which MA is normally excited. This controls the relay AL , which is shown schematically in Fig. 2 and which is normally operated so that its contacts al 1 and al 2 are open. To switch the device on, the reset button R is closed, which briefly applies positive potential to all M ^ tubes. As a result, these are switched and in the same way the other restoring arrangements shown in FIG. 2.

The second unit MB of the flip-flop circuit MA-MB is controlled via two gates G 21 and C-22 with four control lines each and one gate G 23 with one control line. The two gates G 21 and G 22 compare the output voltages of the multivibrator CA-CB with the voltage sampled by the first element of the test memory section. As the control line for C-21. corresponds to the element ο and is energized when ο is scanned from the track, determine MPC11 and CPC ι and CA the first element of the test memory section. When the first MPC i pulse appears, CB is triggered via gate G 24 and CA is extinguished. The fact that the flip-flops CA-CB and DT1-DT2 flip over in MPCi makes it necessary that the section corresponding to MPC 1 is not a test section.

From the consideration of the gate G 22 it follows that the S expensive lines CB, CPCi and MPC 11 are energized at the beginning of the test memory section during the first revolution of that track which is determined by the flip-flop MA-MB. At this point in time, the track "o" is scanned so that the control line 1 is not energized and the gate G 22 therefore does not open. Therefore, MB is not switched.

The second rotation of the drum in relation to this track affects G 21. At the beginning of this revolution, CA is switched again, so that when the beginning of the test section is reached again, the control lines CPC1, MPC11 and CA of gate G 21 are live. Since "1" was added to the previous revolution and was therefore scanned by track "1", the fourth control line from G 21 is not energized, so that G 21 does not open. Therefore MB is not switched either.

In the previous section, the condition of gates G 21 and G 22 when the common control circuit was working properly was described. If the common control circuit does not work properly, "o" instead of "1" or "1" instead of "o" is scanned. As a result, G 21 or G 22 is opened and tube MB is switched via G 23. Has the tube MB. ignited, this sets a second control line to gate G 19, which has a short horizontal line, under voltage. This dash indicates that the control line in question should prevent a switching process. If z. B. the tube MB is ignited, there, s gate G19 no pulses through, so that the counter TC is stopped on the output corresponding to the track on which an error has been found. As soon as the tube MB has ignited, the tube MA is blocked, the relay AL is triggered and the alarm device is activated. As can be seen from FIG. 2, there is a lamp L and a common buzzer Su for each track.

When the error has been eliminated, the supervisor actuates the reset button R in order to trigger the normally proceeding switching processes again.

Is the fault in the track - and not in the common Control circuit, a reserve lane is used, if any.

This arrangement can also be used when each track has its own control circuit, the test processes triggered by the test section gs depend on the respectively assigned circuit devices. Likewise are the number of element positions of the test section and the execution of the comparator of the type of current Monitoring dependent. ',

In some systems that use magnetic tracks on a rotating drum, the recording and playback head separate and usually arranged diametrically. In such cases it contains a memory section a separate track.

The second embodiment of the invention shown in Fig. 3 uses a mercury delay line QVL as a memory. In this case, the pulse feed, which has previously been carried out by tracks located on the drum, is carried out by external switching means, e.g. B. a clock pulse generator CPG. The pulses from this generator are applied to the clock pulse counter CPCA , which is similar to the counter CPC in FIG. A second counter MPCA, whose outputs each determine the independent memory sections, in the present case 100, into which the memory space is divided, is also controlled by the clock pulse generator CPG. The outputs of CPG, CPCA and MPCA control all switching processes.

The use of a mercury delay line as a memory is associated with electronic Particularly known to counters.

It is now assumed that a series of numbers stored in the delay line

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QVL circles. These numbers are sampled at the right end of the delay line and applied to a detector DET via an amplifier MDO. The latter is necessary because the message is stored in the delay line in the form of high-frequency pulses of 13.5 MHz.

The sampled pulses are applied to a pulse amplifier and former PAS , which has two outputs. On one output, P, it gives a positive pulse, while the other, M, is at ground potential when the delay line gives off an output pulse. When no element is being sensed, P is at ground and M is at positive potential. The output voltages of P ^ vS * are scanned by clock pulses from the generator CPG via the gates POG and MOG and fed to the common control circuit.

The pulses of the common control circuit to be recorded become! the gate IG out and so placed under keying by the clock pulses at the input of the amplifier IA . The pulses keyed through gate IG and applied to amplifier IA are high-frequency pulses of the order of 13.5 MHz.

The third embodiment shown in Fig. 4 has an electrostatic storage tube as a memory. A cathode ray tube CRT is used in this system and the memory is based on a known arrangement of the dot-and-dash display system.

A signal or scanning plate PU, consisting of a metal foil or gauze, is tightly attached at the front end to the outside of the cathode ray tube CRT. Each storage position of an individual element of the CRT screen is capacitively coupled to a common channel as in an ionoscope. The stored digits are represented by charge distributions on the screen of the cathode ray tube CRT , which is divided into small areas.

These areas are scanned one after the other line by line and the signals corresponding to the stored message are obtained by the scanning plate PU . In a known manner, three different types of impulses are used, shortest, short (dot) and longer (dashed) impulses. The other required pulses are also derived from the shortest pulses in a known manner. The circuit for the time deflection in the horizontal direction of the cathode ray tube is similar to the dot-and-dash system, while the circuit for the time deflection in the vertical direction is similar to the time base in television receivers, in which the cathode ray progresses across the screen of the tube emotional.

It is assumed that a series of numbers have been stored in the cathode ray tube and that the first element is a bar that has just been scanned by the beam. The positive output voltage is amplified by the amplifier AMP and fed to a gate SG 1, where it is scanned by a shortest pulse in order to get a positive output voltage from the gate concerned. If the scanned element was a point, the output voltage of the amplifier is negative, so that no output voltage is emitted from the gate.

The output voltage from gate SG 1 is applied to an inverter IVR and, in parallel, to the " bar anode base amplifier DSF" . The output voltage of the inverter is fed to a gate SG 2 , which is also controlled by the shortest impulses, the output voltage of which is applied to the "point" anode base amplifier DTF . When a "bar" element is scanned by the beam in this way, DSF gives a positive output voltage and DTF no voltage, and vice versa when a "dot" element is scanned. The output voltages of these anode base amplifiers are applied to the common control circuit.

The output voltages of the common control circuit are led to / to the gates DSG and DTG , whereby AS ¹ G is controlled by "dashed pulses" and DTG by "dot" pulses. When a line is to be recorded, a “line” pulse comes from DSG, and when a point is to be recorded, a “point” pulse comes from DTG. The output voltages of these ports are negative, but are reversed by an inverter IVS and applied to the grid of the cathode ray tube via the anode base amplifier ICF.

The individual parts of the screen are used as separate storage sections. One of them is used to test the common control circuit in the manner previously described.

In the next exemplary embodiment shown in FIG a ferromagnetic matrix is used as a memory in a known manner.

Such a matrix contains a number of cores of magnetic material which can assume one or two stable states and which are usually called positively or negatively magnetized. One core is per message element to be stored. intended. These cores are arranged in such a way that m columns and η rows are formed. n ₀

Each core has three windings, two of which are used as control windings and one as a sensing winding serve. From Fig. 5 it can be seen that the top windings of all cores are connected by a line are connected and form a common output. These windings serve as sensing windings. The control windings are connected to one another in terms of coordinates.

In order to search for the core m +2, for example, the associated vertical line V and the horizontal line H are selected. Each line carries half the current necessary to energize the core so that it is brought into a steady state. The direction of the current is such that the core is positively magnetized. Only w + 2 can be fully excited, and he can

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can only be magnetized if it was negatively magnetized beforehand. A magnetization reversal but in such a case causes a large change in the flow through the sensing coil of the core concerned and thus an output pulse. The recording will be described later. The core windings are each wound individually on the corresponding cores.

As with the delay line memory

ίο and the cathode ray tube it is necessary to provide pulse sources. These are taken from a clock pulse generator which, via a pulse shaper PF and two delay circuits Di, D2, generates a set of three staggered control pulses, t'2 and 1, per clock pulse. testifies. The input circuit to the memory is also able, if required, to generate - 12 - pulses;

The "row" counter EC has a number m of equal units, which corresponds to the number of elements per row, and is set at every ^ pulse. · Forwarded. The counter MC has a number η identical units corresponding to the number of nuclei per column, and is over the gate G at the coincidence of the ECM of the counter EC and an ISS-pulse gradually switched 100th

The outputs from EC are connected to the gates which control the currents in the "column" windings, and the outputs from MC to the gates which control the currents in the "series windings. A ferromagnetic element consists of an annular core on which the windings are individually applied, the amplitudes of two currents acting in the same sense being necessary to generate a magnetomotive force that magnetizes the core via the bend in the hysteresis loop. However, one of these currents is not sufficient to excite a core beyond the kink.

In the scanning process, the core is in a known manner regardless of the preceding Positive magnetized state. Was the core of the

. If the previous state is positively magnetized, no output pulse is generated. If, on the other hand, the core was previously negatively magnetized, an output pulse is generated in the sensing winding of the core. It is emphasized that the sensing windings are arranged in such a way that the cores alternately generate pulses of opposite polarity in order to overcome the accumulating demagnetizing forces in a known manner. It is assumed that the units m and η of the counters EC and MC are each energized. The iß impulse of this element position brings EC to ECi, and at the same time the gate Gioo opens at the coincidence of £ 3 and ECm, so that MC is switched to MC 1. When the 1 1 pulse occurs, gates G 102, G 103, G104 and G105 are open, so that a current pulse is sent through the first "column" and the first "row" of windings. As can be seen from FIG. 5, only the core 1 can be fully excited, the two control windings of which are traversed by a current pulse. The polarity of these current pulses is such that the core is positively magnetized, so that the core 1 remains untouched if it was previously magnetized positively, and is unmagnetized if it was negatively magnetized. In the latter case, a sampling pulse is generated at the common output.

The output pulses are applied to both the common control circuit and the input circuit ESK of FIG. 5 via a connecting line (not shown). The input circuit ESK is designed in such a way that if the core is to remain positively magnetized after scanning, it does not emit an output pulse. If, on the other hand, the core is to be magnetized negatively again after scanning, ie in order to retain the negative message, a negative pulse - ί 2 is generated. This pulse is applied and opens gates G107, G105, G106 and G 103 so that pulses having the opposite polarity of the sampling pulses are sent through the same control windings. As before, only the core 1 is detected, so that the core is magnetized fully negative.

The next i3 pulse switches the counter EC to EC 2, so that the gates of the second column and the first row open with the next 1 1 pulse. Therefore, the core 2 is positively magnetized or left in its state, and an output pulse is generated or not generated according to its previous state. As described, the switching process runs alternately for each core in the sequence shown in FIG. 5, the counter EC selecting the column and the counter MC selecting the row.

It is noted with respect to FIG. 5 that, in order to simplify the basic diagram, symbols for Spannutngstore were used. However, as has been described, the matrix is current driven, with the required Currents z. B. generated by tubes controlled by the gates shown will.

The coordinate matrix shown schematically in FIG. 6 is essentially similar to that shown in FIG. 5, with the difference that it is made up of ferroelectric elements. Ferroelectric materials are dielectrics in which electrical dipoles form by themselves and which interact with one another. Their curves of dielectric induction as a function of the electrical field show a course similar to that of the hysteresis loops of the BH knuckles of ferromagnetic materials.

Barium titanate (BaTiO ₃ ) appears to be the most common ferroelectric material at present.

The switching processes are in many ways similar to those of the ferromagnetic matrix. In addition it is noted that a recording pulse applied to an element converts it into a stable electrical State shifted and that a tapping pulse the element in question in the other brings a stable state, whereby a strong output pulse is generated. When the item is

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when scanning is already in the other stable state, very little or none occurs Output pulse on. When using barium titanate, an output pulse of 25 volts, with a storage capacity or a marking, if the input button 5 ms with 30 volts occurred compared to: 0.6 volts when none. Storage made or a distance had been marked. In the present case it will be.

shorter pulses are used, whereby the distinction is even easier.

In the matrix in FIG. 6, the elements are connected in columns and rows like the ferromagnetic elements. Elements in Fig. 5. The gates in Fig. 6 have the same reference numerals as the corresponding gates in Fig. 5. The counters and the pulse sources used are the same as in Fig. 5 and are therefore not shown. In order to select a certain element for tapping or for storage, one half of the required voltage is applied to the series and the other half to the column. The two halves of the applied voltages have opposite polarity. As has been shown in the previous exemplary embodiment, it is sampled at the t i pulse and stored at the i2 pulse.

A capacitor with a rectifier connected in parallel is assigned to each individual element in series. As can be seen from FIG. 6, these switching elements are assigned to the columns. The outlet pipes are taken from the columns and the arrangements are the same as those in FIG. Sampling takes place via the pulses + 1 1 and - ti, the storage process, however, is done by applying the pulses 4-i2 and - i2.

A preferred embodiment of the matrix contains a single large crystal of barium titanate from 0.1 to 0.2 mm thick, to which a seat of parallel ladders is assigned on each side.

The two sets of ladders are orthogonal to each other. There is a single storage element at each intersection.

Claims (1)

PATENT CLAIMS: i. Control device for multiple memories in telecommunications, in particular telephone systems, in which the memory is divided into individual ^ independent sections and the sections are divided into individual elements and the individual sections are processed with the help of control circuits in a cyclical sequence, characterized in that one of the memory sections is used as a control section in is used in such a way that, when the associated control circuit (8) is working correctly, it is alternately provided with one of two possible pieces of information (e.g. positive or negative magnitude) and that this information is provided in a comparison device (13) with a Compulsory changing test indicators (CA, CB) are compared and the incorrect operation of the control circuit is displayed by the comparison device. 2: Control device according to claim i, characterized in that the test identifier is generated in such a way that the pulses (9 or 10) which mark the position of the individual elements or individual sections control a bistable multivibrator {CA, CB). 3. Control device according to claim 1, characterized in that the comparison device (13) consists of a bistable flip-flop circuit controlled by gates (G 21 to G 23). 4. Control device according to claim i, characterized characterized in that the control section consists of only one element. ■ 5. Control device according to claim 1 to 4, characterized in that each individual memory (e.g. track 2, 3, 4 in Fig. 1) has a control circuit (8) is assigned. 6. Control device according to claim 1 to 4, characterized in that a multiple memory a common control circuit is assigned. 7. Control device according to claim 6, characterized in that, for monitoring the common control circuit, the test elements and the switching means serving the display via a common distributor (TC) ; periodically and only for as long as is necessary for a proper test. 8. Control device according to claim 7, characterized in that if faulty Working of the control circuit, the common distributor is shut down and thus the relevant memory through which a faulty switching state has been caused, indicates. 9. Control device according to claim 1 to 8, characterized in that a multiple memory consists of a magnetizable drum driven at constant speed and that the individual memory through on tracks attached to the drum as well as the associated recording and playback organs and the messages are imprinted in these tracks. 10. Control device according to claim 1 to 8, characterized in that the memory is an acoustic delay line (z. B. a Ouecksilberverzögerungsleitang QVL) , in which the messages are stored in the form of pressure waves. 11. Control device according to claim 1 to 8, characterized in that a cathode ray tube ( CRT) is used as the memory, in which the messages are stored in the form of individual surface charges. 12. Control device according to claim 1 to 8, characterized in that a memory 609 508/159 18436 VIII a / 21 a ³ is formed from a number of bistable storage elements in which the messages in Shape one of the two bistable states is impressed in each case. 13. Control device according to claim 12, characterized in that a memory made of ferromagnetic or ferroelectric elements exists, which are interconnected in terms of coordinates. Referred publications: British Patent No. 684079. For this purpose 2 sheets of drawings