DE1283711B - Method for remote monitoring of the operating status of a number of devices - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

G08c

German class: 74 b-11

Number: 1283 711

File number: P 12 83 711.5-35 (S 92257)

Filing date: July 24, 1964

Opening day: November 21, 1968

The invention relates to a method for remote monitoring of the operating state of any large, limited only by the width of the frequency band available for signal transmission Number of devices, the number of which is divided into main groups by subdividing them into different channels is by a control center that sends out interrogation signals in a cyclical sequence, which from a Responder in each of the devices to be monitored in its operating state in indicative Way are convertible to response signals.

There are many applications in which a data display of status data is displayed on a central station. or operating conditions of a device located at a remote location is required. Typical Examples of such cases are the monitoring and reading of various display and measuring devices at remote stations, interrogating aircraft to determine their identity, interrogating the measurements made by a satellite or the status of those in earth satellites Devices or polling television receivers in the case of so-called subscription television.

One way of transmitting such information from a remote station to a control center is to use a system in which each remote station has a transponder is provided, which is put into operation by certain signals from the control center in order to in turn the Operating status of the equipment to be monitored to transmit the corresponding response signals back to the control center.

Use known monitoring systems for a wider range of stations for differentiation mechanical pulse generator of these individual stations. On a special sent out by the headquarters A mechanical signal begins in a station selected by this special signal Encoder to generate pulses which are characteristic of their operating state or identity.

Experience has shown that such known devices have significant shortcomings and are subject to them various restrictions regarding their usability.

The possibility of varying or combining different impulses - and thus the number of stations or the message content of the signals - is limited due to the mechanically generated impulses. The duration of these pulses is approximately in the range of milliseconds, which corresponds to a frequency of 10 ² Hz. The bandwidth that can be used is therefore extremely low.

Remote monitoring procedures
the operating status
a number of devices

Applicant:

Skiatron Electronics & Television Corp.,

New York, N.Y. (V. St. A.)

Representative:

Dr. phil. G. Henkel

and Dr. rer. nat. WD Henkel, patent attorneys,
8000 Munich

Named as inventor:

Herbert W. Sullivan,

New York, N.Y. (V. St. A.)

Claimed priority:

V. St. v. America July 24, 1963 (297 397)

The mechanical pulse generators used in the known devices are also used extremely uneconomical and due to the construction (contact release by a synchronous running camshaft, by a gear or by punched tape, etc.), which a high degree of precision makes indispensable, very expensive even in mass production. On top of that there is sometimes that for sure undesirably large space requirements of the mechanical components. Other negatives are the lack of it Operational reliability of the mechanical contacts, their mechanical wear and tear as well as the often tedious and complicated adjusting process of the same.

In addition, almost all of these devices are due to their design features only if they exist a cable connection between the device to be monitored and the control center. In addition there is also the fact that, according to the known method, the individual stations are only queried one after the other can be, so a query cycle takes a considerable amount of time.

The invention accordingly has the object of providing a method for wired or wireless Remote monitoring of devices indicate that there is practically no limit to the maximum

809 633/1580

The number of stations to be monitored is subject to the identification of the stations or coding the messages do not require the use of complicated mechanical components that are prone to wear and as a result, and beyond that, a previously unattained maximum of operational reliability, Capacity, small footprint, simplest manufacturing and design.

According to the invention, this object is achieved in that at least one signal sequence in each cycle which makes a certain main group of reply senders ready for operation in each main group and on it then an interrogation signal is sent out and the interrogation signal in all of the selected answer transmitters Main groups on the one hand in a characteristic for each individual device of this main group, it is modified in a way that distinguishes it from all other devices only in the relevant main group becomes, whereas one device of each group in each main group has the same characteristic modification is assigned, and on the other hand in a characteristic of the operating state of the device in question Way to be modified logically.

Basically, the responder located at the remote station does not generate the data pulses, which indicate the operating status and identity of the device to be monitored, but instead according to the invention polling signals sent by the central station, which are received by the remote station, modified according to the identity of the station and its operational status and then sent back. In this way, relatively simple coding means can be provided at the remote station as the frequency and pulse sequence of the signals are generated by the main station itself and on the remote station only modifies and modifies these signals for data transmission for identification is made. The invention also makes it possible from the subdivided into main groups total number of stations out to specific remote stations individually or in groups Select query at any time. According to this feature of the invention is each responder with circuitry for recognizing and answering a predetermined Group of outgoing signals provided by the control center. To a selected group or an individual To put the response transmitter into operation for the purpose of interrogation, the control center first sends a first Signal group, which partially puts the reply transmitters of a first main group of stations into operation, and then a signal group of a lower spectrum, giving way to the responders of certain subgroups of stations of the previously selected main group for querying. the finally selected responder, selected by both signal groups and thereby in Are set to operation are able to receive the query signals subsequently sent out by the control center to receive, to modify according to the identity and operating status of the respective device and in the to be sent back to the head office in the same period of time.

The method according to the invention is described below with reference to exemplary embodiments and the drawings explained in more detail. It shows

F i g. FIG. 1 is a block diagram of a complete subscription television system incorporating the features of FIG Invention,

2 shows a schematic representation of the typical transmission spectrum,

F i g. 3 is a schematic illustration from which the various sections of the interrogation cycle can be seen are,

Figures 4A, 4B and 4C are schematic representations various embodiments of transponders operating according to the method according to the invention,

ίο F i g. 5 and 6 are schematic representations of various Types of response circles for the logical modification of the query signals received from the control center,

7 shows a schematic block diagram of an embodiment of the control center and

F i g. Figures 8 and 9 are schematic representations of other embodiments of the responder.

Referring to Fig. 1, there is shown a system incorporating the features of the invention which can be used with pay TV television sets. In the system shown, transmitter branch lines 20 a, 20 & etc. are provided, which originate from a control center 30 and to which similar subscription or subscriber stations are connected, of which the stations connected to line 20 a are indicated by 2Ia-I, 21a-2, 21a-3, etc. and the stations of the other lines are designated 216-1, 216-2, 216-3, etc., 2Ic-I, 21c-2, 21c-3, etc., respectively. Each subscriber station receives the program transmitted from the center 30 via a branch line. The stations connected to a branch line form an "upper group" of stations.
Each subscriber station consists of two main components, namely a program receiver 31 and a transponder 32. Depending on the type of this program receiver 31 - radio or TV of different frequency ranges - lines 20 with a corresponding frequency range are to be provided.

The programs supplied by the center 30 are generated by several program transmitters 33, soft on the output side are connected to a modulator 34 in which the individual programs a carrier frequency are impressed.

The modulated carrier frequency is then fed to a power amplifier 35, the output of which is connected to the parallel-connected inputs of several amplifiers 36a, 36 & etc., one of these amplifiers being provided for each branch line 20. Each of the amplifiers 36 serves as a buffer amplifier for the branch line 20 a, 20 b , etc. connected to it.

The selection and interrogation signals for billing are generated by a signal source 37 which is controlled by an interrogation control system 38 and also reach the lines 20 via the power amplifier 35 and the buffer amplifiers 36.
In Fig. 2 shows a typical frequency band output by the power amplifier 35, which e.g. Example, from the image channels X, Y and Z and two frequency modulation and FM channels FML 2 consists. The two FM channels can also be used to transmit amplitude-modulated signals and are preferably used to transmit the various selection and query signals. The carrier frequencies used in the application example are listed below:

5 channel Frequency (MHz) Image channel X 26 to 32 FMl channel (selection and
Query signals) 34 to 35.2
36 to 42 Image channel Y 45 to 51 Image channel Z 53 to 55.5 Channel FMl

The interrogation signals are emitted from the control center as soon as a final group of stations to be interrogated is selected in each branch line with the aid of the selection signals and arrive - as already described - via the lines 20 to the responder 32 of the selected station. There they are modified according to the operating status of the respective program receiver 31 (ON or OFF or selected channel) and according to the identity of the respective station. The latter is necessary in order to be able to differentiate each individual station from the common subgroup, and is done by modulating the interrogation signals characteristic of each station before they are returned to the control center. The modified query signals are either fed back via a separate line, not shown, for example a telephone line, or the branch lines 20 a, 20 b , etc. that the charge calculation runs in the cycle of the interrogation of the stations. In the exemplary embodiment, the response signals of the interrogated stations are in the audio frequency range and are tapped from lines 20 by low-pass filters upstream of the buffer amplifier 36 and fed to the charging and error checking device.

The selection of a group of stations to be interrogated on a branch line is preferably carried out in the manner described below: Each responder 32 has η band filters tuned to different frequencies. These frequencies represent a selection of m frequencies which the central unit is able to send out as a whole as selection signals, but where η is always less than m . At each branch line 20, several stations with the same combination of η band filters are combined into main groups. If a certain combination of frequencies is broadcast from the control center, which corresponds to the frequencies of the η band filters, the corresponding main group is selected, so to speak, and thus made ready for operation. The individual main groups are further subdivided, which can be selected by each main group's characteristic combination of signals. If the control center issues a second signal sequence following the first signal sequence, which corresponds to the characteristics of the previously selected main group of stations, this sub-group is finally made ready for the query, while the other sub-groups of the main group remain unaffected. The number k of the second frequency combination is always smaller than the number η of the first frequency group and consists of frequencies that are also used in the first frequency group. As a result, the same bandpass filters can be used to receive the first and the second frequency group, which results in economical and space-saving savings. As soon as the respective subgroup is finally selected, the center sends 30 query pulses which are only modified by this finally selected subgroup and sent back as response signals, the

ίο individual stations of each subgroup together be queried. This selection and query process is carried out in turn for each main group and the various subgroups of stations within each main group of all branches carried out until all receiving stations have been interrogated one after the other. The total number of stations to be interrogated according to the scheme described above results from the product of three different factors, firstly the

Number of combinations of η frequencies of the first signal sequence selected from the m frequencies that can be emitted by the control center

"- will - d. H. () -, secondly the

\ n!

Number of combinations of k signals resulting from the η frequencies of the first signal sequence

be chosen - ie (") -, and thirdly the ■ '

Number of stations in each subgroup.

F i g. 3 shows a complete selection and interrogation cycle as a function of time for the case m = 9, η = 4 and k = 1 and with the assumption that eight stations belong to a subgroup. Under these conditions you can then

• 8 = 126-4-8 = 4032

Subscriber stations can be connected to a branch line. One of the 4032 subscriber stations Branch lines are the 32 subscriber stations of a main group through four of the nine possible Frequencies of the first signal sequence transmitted by the control center selected, and from this main group a subgroup of eight stations is further selected and queried by the second signal sequence.

According to FIG. 3, the control center transmits η = 4 from m- 9 available frequencies to all subscriber stations on all branch lines during the first section of an interrogation process. These four frequencies are e.g. B. denoted by A, B, C, D and are transmitted on so-called channels A, B, C and D. The other available frequencies E, F, G, H and / ( not shown) are transmitted via corresponding channels E, F, G, H and /. The combination of the tone signals A, B, C and D is only recognized by those responders (in the present example 32) of the subscriber stations of each branch line whose input circuit is matched to the combination of the frequencies A, B, C and D. The four selection frequencies A, B, C and D of the first signal sequence can be transmitted during the first part of the interrogation cycle either continuously and simultaneously or one after the other and repetitively in rapid succession.

7 8

In the application example, the frequencies have increased the number of binary digits

zen m, which from the control center in sets of to the extent that one logical circuits

η = 4 individual frequencies are broadcast, fol- with a higher basic frequency used,

Low values: It is recommended to use the data transmission

. _ _vw 5 necessary binary digits according to a certain code

^{A ä / 4} ' ^{8 /;> ktlz} to be transmitted so that the control center can check

B 637.875 kHz whether during transmission, modification

C 700.875 kHz ^run and / or retransmission of the query signals

η ΊϊΛίΠ * VHV ^{an error} has occurred.

^u /oj.ö/jnnz _io during the third section of the query cycle

E 826.875 kHz, taking into account the capacity of the data

F 889.875 kHz processing system and the cutoff frequency of the

G 984 875 kHz logic switching elements, the signal sequence of the fre-

'sequences A, B and C constantly from the central

■ "1 078.875 kHz _ig . At the same time, the frequency D of the two

/ 1173.875 kHz th signal sequence sent continuously by the control center, around the identification registers of the queried

After the first signal sequence A, B, C, D , the subgroup of stations transmits during reception

Centralize the second sequence with k - \ frequencies to keep the interrogation signals operational,

which during four different interrogation cycles ao during the fourth part of the interrogation cycle

of subgroups one through the signal sequence A, B, the control center detects no signals, but evaluates them

C, Ό addressed main group alternately the response signals of the subscriber stations for the

characteristic frequency fee calculation for each subgroup. When using

A, B, C or D. The subgroup D, with error codes, is also checked at the control center, for example an upper group A, B, C, D, is thus selected as if errors occurred in the data transmissions in such a way that a first signal sequence is included. If such errors are found, the frequencies A, B, C, D and then the interrogation cycle for the same subgroup of a second sequence of the frequency D is repeated by the central eight stations in the same way as long as it is repeated. The interrogation process from others until either a correct answer is received from subgroups of this main group or from all Un- 3 ° or until a predetermined number of interrogator groups of other main groups is carried out analogously through cycles with incorrect answers. In this way, in the present case, the query of this relevant out of the total number of 4032 stations of a branch subgroup is stopped.

line always only one group of eight participants. After completing the interrogation process, this one is selected and then interrogated at the same time. The control center switches the subgroup during a licherweise, the subgroups can also consist of more fifth sections of the cycle in their program than eight participants, in which case, of course, further. Then, in the same order as before, the control center must be designed so that it receives the response signals characteristic of a first signal arriving at the same time, a main group through different tone frequencies and one of their subgroups through a second signal sequence , up to and capable of separating. In the same way, it is of course necessary for all subgroups of all main groups, one after the other, that the total number m of frequencies that pen has been selected and queried.
Number η of the frequencies of the first signal sequence or an interrogation cycle of the above-described number k of the second signal sequence within the form is shown in FIG. 3 limit values set up as a function of time can be varied at will. The five cycle sections can have the following meaning, in order to increase the number of stations:
to decrease.

After a subgroup requesting transmission of the first signal sequence A, B, C, D _{1 has} been selected as described above, selecting a main group of 32 stations during ^{the interrogation cycle, the control center sends 50 out of the} total number of 4032.
a third period of the interrogation cycle interrogation _n transmission of the second signal sequence D, selection signals, which are preferably _{modulated from the sequences of the first signal sequence to those Freedner subgroups of eight} stations, the thirty-two of the main group,
have not been sent as a second signal sequence of k frequencies. In the present example, 55 ΠΙ transmission of the interrogation signals with the carriers stand for frequencies A, B and C for frequencies A, B, C and simultaneous connection. The query signals consist of the binary words used by the selected subgroup.
pay 1 and 0, where the inventive esterification _"r". ... _, .., _x ",". . , the binary digit 1 (maximum amplitude) and the ^W spring test, resetting of the registers and binary digit 0 (minimum amplitude) drive the frequencies A _} 60 billing.

B, C at the same time and in a known manner aufmodu- y handoff from headquarters to a Zähliiert. step.

For example, if in the responders

logic circuits with a cutoff frequency of F i g. 4A shows a preferred embodiment 1 kHz can be used, i.e. That is, if the binary digits 65 of a responder who is at each subscriber station each have a length of 1 ms, can be used. The during an interrogation of the third cycle section seventy-five of the cycle, for example, binary digits are transmitted via a coaxial cable branch. Self-routing 20 signals sent from the control center

9 10

are received at the subscriber station and off. During this time, the frequency D is also fed to a blocking circuit 50 of the transponder. continues to be broadcast constantly to the circle 56Ö This trap circuit has a band filter, which only keep the operational. The FM channel that lets through at its output, which has the selection and the "!" Signal on the one hand, holds the register 60 query signals modulated by the control center 5 ready for operation and, on the other hand, controls one of the inputs, but all the others via the coaxial line a coincidence stage 65, whose incoming signals, for example image and music second input through the operational register signals, keep away from the responder. The output 60 is controlled. The interrogation signals, which are modulated cyclically on the frequencies of the trap circuit 50, are modulated at the input of a demodulation 4, B and C and are connected by the central unit 52, in order to separate the interrogation signals sent out from the carrier wave by the interrogation signals. The signals detected by the speaking circuits 56-A ₁ 56-B and 56-C and demodulated by the demodulator 52 are thus applied via a circuit 66 to the third input of the then through a limiter stage 54 to the same ampli-coincidence stage 65.

tude cropped. The from the limiter stage 54 The F i g. 5 and 6 show the construction of Schaltabgegebenen signals are the parallel-connected 15 circles 66 which is supplied for modifying the received inputs of four circuits that serve corresponds interrogation signals corresponding to the operating state of speaking the frequencies A, B, C and D of the first of the associated subscriber station .
Signal sequence to which they are coordinated, with F ί g. 5 shows a circuit for generating

56-A, 56-B, 56-C and 56-D, respectively. Each of the four different modifications of these circles 56, for example, has both a selective interrogation band filter transmitted in this way only on the channels A and B , for example an LC filter, crystal filter bmarch digits. This circuit has a Umkefirod. Like. As well as a conventional demodulation amplifier 80 and a switch 82 with several circuits, so that at the output of each circuit the switching levels are fed to one level of which the frequencies enveloping the transmitted binary digits - that is, the circles 56-A and S6-B with direct current pulses - pending. as the frequency / i at the contact A US and TVX and the

The outputs of the four circles 56 are connected to the four frequency B at the contact TVY and TVZ . The inputs of a coincidence circuit 58 connected galvanically interconnected contact arms, at the output of which the signal 1 occurs as soon as the two switching levels are switched to the subscriber station on one of the programs at the same time when switching over to all four inputs. This signal controls a subsequent switched channel X, Y or Z moved.

tetes register 69 , which causes the four different switching positions at its output

Signal 1 also appears. In the case of the one in Fig. 4:

This functional sequence is shown when the switch 82 is in the OFF position.

then initiated when, as assumed, finds the four, that is, when the receiving device is switched off frequencies A, B, C and D as the first signal sequence of 35, the binary fed in on channel A of the control center will be transmitted. The second signaling signals in their original form, the width approximately in the subsequent follow in the present case from the frequency D. is the referred to as A, directly by the As a result, the circle S6D during the first switching circuit 66 to the coincidence stage 65 of the second portion of the Polling cycle con- ceded. If, on the other hand, the operator is in the stant the signal 1, which causes that a 40 position is TVX , i. That is , if the receiving device connected to the output of circuit 56D is switched to television channel X , the inverter 62, which is connected to the input of the binary signals of channel A to the input of the UmRegister 60, sends a "0" signal, Reversing amplifier 80 is supplied, and at the output of this, whereby the register 60 remains in the state, circle appears the inversion ~ Ä of the binary signals A _r in which it is toggled 45 during the first signal sequence, ie it is a conversion of the binary digit 1 to is. On the other hand, if you select the central unit with the second binary digit 0 (and vice versa). In a similar signal sequence to another subgroup and radiates, if the receiving device is switched to one of the frequencies A, B or C , television channel Y and thus the switch 82 in position, the circle 56 Z) of the station shown is switched to TVY is, the binary digits B directly from the "O" signal, which an inverter 62 is fed into a 50 at the output of the circuit 66, while "1" signal converts to the register 69 again when the switch 82 is in position TVZ is about to reset the idle state. In this case, the logic center at the output of the reversing amplifier 80 from all stations has complement 2? of the fed-in binary signals B first only the main group A, B, C, D and then the appears.

Subgroup D selectively made operational. There- 55 In circuit 66, according to FIG. 5, if there are four with, this is a subgroup ready to modify the interrogation signals received from the possibility of modifying the interrogation signals sent out by the control center 30 before answering them, whereas all other stations are forwarded to the coincidence stage 65 will,
are not ready to query. In circuit 66, as shown in FIG. 5, can only

If the second signal sequence consists of two or more four different logical output signals generated reren frequencies, the inverter will be 62. In Fig. 6, however, a switching arrangement is replaced by a conventional reverse coincidence switching device for generating logically modified output signals. In the absence of at least one of these three frequencies ^, B and C illustrated. This generates frequencies of the second signal sequence. Analogous to the reverse coincidence step in connection with FIG. inverse output 84 depending on the position of the

During the third section of the: query cycle level switch 83 modified binary values, the control center sends the actual query pulses digits to inputs A, B and C.

Switch position Output signal 1 Ά 2 Έ 3 t 4th ~ Α + Έ 5 Z + C

11 12

The following combinations occur: The LF response signals are sent from the emitter of the

Transistor 70 removed and a conventional emitter follower amplifier 75 with relatively low output impedance, so that the 5 response signals easily through an attenuator and adapter 77 of the branch line 20 or a separate transmission line 78, for example one Telephone line, which leads them back to the central office.

ίο The query signals issued by the control center 30 are therefore in a logically modified form to. Obviously, when used, the corresponding control center is sent back. This means that the of the logical components a multitude of extension transmitters which correspond to the respective operating status options of the modifying device corresponding to the associated receiving device give. Does not have to generate 15 encrypted pulses yourself,

As often as the circuit 66 in the course of the interrogation cycle but rather that this data outputs a binary digit "1" to the central unit and thus all three are generated and the response transmitter only assigns the potential "1" to the inputs of the coincidence stage 65 corresponding to the respective operating state of the, will be logically modified at the output of this level of the binary-hearing receiving device, pulse »1« is emitted. According to FIG. 4A, this is so. In addition, the response signals NF-module are fed to a specific subscriber station from a transistor 70 via a coupling circuit 68 to the base of a transistor 70, the emitter of which is fed out via a group of interrogated subscriber stations through a coil 71 and a capacitor 72 to be able to identify. Overall, this creates a resonant circuit that is connected to earth. The collector represents a relatively simple arrangement, which one of the transistor is connected to a current (not shown) 35 considerable number of different information source Έ , while its base is over biased with respect to the identity of the subscriber station and a resistor 73 in the forward direction of the operating state of their receiving devices. As soon as a binary signal "1" - that can carry you through.

positive direct current pulse is shown - in Fig. 4B shows a modified embodiment

the base of the transistor 70 arrives, this 30 blocks a responder, with soft the character momentarily. Due to these sudden low current LF response signals in a way other than the break at the transistor, the resonant circuit will be generated in the device according to FIG. 4A. To bump, which emits a pulse of practically the same duration designation of the individual parts of this responder as the fed data pulse, which the same reference numerals are used as in Fig. 4A but in contrast to the input pulse in the NF-35. In this embodiment too, controls range is. In this way, each binary signal emitted by the first signal sequence with the frequencies A, B, C coupling circuit 68 generates an LF and D the register 60, which in the case of a second signal, which is thus also the binary digit "1" signal sequence of the frequency!) Maintained ready for operation corresponds, whereas a signal »0« does not oscillate. The operational register 60 switches on the LF circuit, since conventional LF oscillator 87 is switched on in 40, which in turn generates a signal of characteristic frequency through the negative input of the transistor, which voltage remains in the pass band. The oscillation of the respective responder of the interrogated circle is designed in such a way that it identifies one for its answer subgroup. The signal emitted by the other seven, which is characteristic of the low-frequency oscillator 87 transmitter, is fed to a conventional modulo response transmitter of the respective subgroup sub-45 converter 88, by which it generates different frequencies. Binary signals occurring in a subgroup of eight subscriber stations are modulated as the characteristic frequencies output of the circuit 66. These amplitude-modulated, for example, the following low-frequency frequencies low-frequency signals are used by the emitter follower amplifier 75: and via the attenuation and matching element 77

50 is fed to the transmission line 78. The coincidence stage 65 for identifying the second signal sequence D of the responder according to FIG. 4A has been omitted from the responder according to FIG. 4B. In spite of this, no LF signals can be delivered to line 78 unless register 60 is kept ready for operation by a second signal sequence of frequency D at inverter 62.

Fi g. 4C shows a further embodiment of a responder suitable for use in the method according to the invention. Again in this case the same for the same components reference numbers are binary digits The query the control panel, which, like and used in the responders according 4A originally on the frequencies A, B and C exceeded 4B. The transponder according to FIG. 4C were thus carried by the resonant circuit 65 differs from that of FIG the respective responder, but rather to the one of the interrogation signals. Central is generated.

Participant status Frequency (Hz) 1 595 2 765 3 935 4th 1105 5 1275 6th 1615 7th 1955 8th 2380

13 14

To the responder according to FIG. 4 C from circles 128 to ask the interrogation signals in the desired, the center transmits during the third sequence of transmission, while the other AND section of the interrogation cycle via the branch circuit 128 continuously the frequency of the second together with the interrogation signals on the respective Signal sequence emits which the carrier frequency detection register modulates eight low frequency frequencies. This keeps 5 of the selected responders ready for operation, arrive according to FIG. 4 C via the demodulator 52 The outputs of the AND circuits 128 are connected to one and the limiter stage 54 to an LF bandpass filter 89, the only output line, which is only one of the eight LF frequencies (namely on the one hand with the transmitter and on this with which is connected to the subordinate branch line 20 which is characteristic of the respective responder.
lets through. This signal is then applied to an electronic check of the response signals from the front switch 90, which opens as soon as the register 60 is made operational by the second signal sequence of the frequency section of the query cycle by the computer during the third has been. As long as 120 generated interrogation pulses via a switch of the switch 90 is in the pass band, it transmits the 140, which only occurs during the third section of the continuously occurring LF signal to the one cycle through the computer 120 on passage ge input of the modulator 80, where it analogous to the switching, a logic circuit 142 leads to a sequence described in connection with FIG. The amplitude-modulated LF signal is then generated (Fig. 5, 6) at the transponders, a number of signals generated via the coupling circuit 68 to the emitter sequence ao encoded data, amplifier 75 and from there via the attenuation and the at hand from F i g. 6 described example adapter 77 of the transmission line 78 to a circuit 66 which is performed using the. Query frequencies A, B and C five logical modi

The reply transmitter according to FIG. 4C needs decorations of the encrypted signal, no oscillator for producing the characteristic frequency, as at the output of the logic circuit 142 the same on which the reply signals to the control center to five logic code modifications ~ Ά, Έ, ü, Ά + Ή be retransmitted. This represents a significant or ~ Ä + ü shown. These signals are saved in a data memory 143, for example a sound safety factor in the calculation of charges, tape or punch cards, recorded in order to be able to use an oscillator at the control center with an error checking circuit 144 without difficulty much more effort, for example to be supplied. If desired, a temperature-stabilized or quartz-stabilized oscillator can all be created, these possible modifications of the response signals can be created and the response signals can thus be specified in the data memory 143, so that they always have a constant frequency. logic circuits 142 and switch 140

F i g. 7 shows a block diagram which can be omitted in the case of the invention.

Use the appropriate method at the control center. The logically modified binary pulses, the ten tax and fee calculation facility. during an interrogation cycle by the participant-Ein Conventional stations of a subgroup provided in this circuit are transmitted back to who-computers 120, which the interrogation control system 38, the corresponding characteristic LF pulses according to FIG. 1, controls the generation of the 40 will be from the transmission line 78 of a series Selection and interrogation signals and the charging of filters 152-1 to 152-8 supplied, of which calculation arrangement. Although for all stations each one during the third section of the interrogation common computer 120 are provided that a specific subscriber station of the cycle Fig. 1 illustrates. 7 shows an arrangement in which the corresponding LF signal is softened when the group is queried A computer 45 filters a single branch line 20 and a data memory 154 for storage 120 is assigned. reads. For each station there is 154 in the data memory

A programming output of the computer 120 actuates a special memory unit provided,
a control matrix 122 having nine output lines In the case of error checking that an AND circuit in the 124-A through 124- /, each of which gear 154 stored pulses from one of the one input data memory 128 ^ 4 may CONNECTED to 128 / 50 reading device 156 is one to the error checking circuit 144, the other input of which is linked to the output of an oscillator 126-A to 126-7 that has been read and is associated there with possible logic code modifications of the originally sent interrogation link. Each of these oscillators 126 generates signals to be tested. If the reproduced continuously one of the m frequencies Λ, B, C etc. data match one of the possible code modifications

The computer 120 controls the generation of the information, so at the output 160 of the error checking selection and interrogation signal during the various circuits 144 a signal indicating “no error” is generated for sections of the interrogation cycle. To this end testifies. At the same time it is confirmed that the information stored in the data, the AND circles 128 corresponding to the selection memory 154 is accurate and is used to generate each section of the interrogation cycle - the signal groups are controlled through to calculate charges. Where previously 60 can. This signal "no error" switches the example described above, in which m = 9, η = 4 ner 120 by one step, so that the next and k = 1, are subgroups of subscriber stations on cycle four during the first section AND circles controlled while the written way can be checked. If, in the second section of the interrogation cycle, one of these four AND circuits is found to be activated 65 when one of the memory units is checked, the will be. During the third section of the interrogation "error" output line 162, a signal is generated, which activates the arithmetic unit optionally three of the cycles with the result that the interrogation cycle repeats for these first-mentioned four through-connected AND-matching group of subscriber stations

I 283 711

15 U

will. At the same time, the content of the data memory is also significantly less interference-free than conventional ones either deleted or marked as faulty, the loan process works.

so that it is not used for calculating the fee. 8 is a for any ferasfation

can be. If desired, for each - preferably an earth satellite - more suitable Memory unit generates a special error signal from 5 reply transmitters for the return transmission of data so that the identity of the faulty part of the station is represented. Be from the head office subscriber station can be easily determined. in the application example binary data by two

After a predetermined number of repetitions, different LF frequencies ^, B are shown, which fetches the query cycle of a faulty sub- common but after different modulation groups, the computer 120 automatically switches to the process (z. B. amplitude-phase-frequency modulus query of the next subgroup of »subscriber! ation, etc.) is modulated on a carrier frequency and subscriber stations continue, and these erroneous sub-radiated. At a later point in time, a receiver 172 is also queried via an antenna 170 and a group, the carrier wave is interrogated in each case in order to determine whether the error is still occurring at a demodulation stage 174 where the error occurs. If this is the case, the received signal is demodulated again by means of a display 15, and the disturbance of a subscriber station of the relevant subgroup is reported according to the two types of modulation with which subgroup. the two LF signal sequences were previously impressed

The center shown in Figure 7 is in their the. The two binary signals are supplied to the extension per se for combination with the response circuit 66 , which is intended to transmit the same task according to FIGS. 4A and 4B. Should ao be fulfilled, the arrangement according to FIG. 5 ate previously in connection with FIG. 7 however with the Ant and 6 were described. The circuit 66 is used verbatim according to FIG. 4C, so controlled by a measuring device 176, which they are supplemented by LF oscillators, for example the temperature, the operating state of the soft generating the identification frequencies and station, the radiation intensity or the number of registered 25 meterite impacts during the third section of the interrogation cycle. Which are brought into use by the computer 120 from the measuring device. 176 emitted signals control the setting of the The eight identification frequencies are thereupon circuit 66, in which the interrogation signals are modulated on the same carrier wave to which the selection and interrogation signals are also converted by the logical modification into response signals. There will be another one. 3a Querying several stations in parallel (see Fig. 4 B)

The method according to the invention is possible via the. The modified! Application example also with wireless and with the characteristic frequency of the station in question Transmission instead of the branch line 20 applied impulses to the input of the emitter follower. One of the great advantages of the invention occurs in amplifier 75 and then modulator 178 to it Case in the foreground, namely that the 35 passed, where they passed one through a carrier wave transmitter long, complicated key numbers for the carrier wave generated 180 are modulated, transmission are generated in the central station. This modulated carrier signal is then transmitted via the instead of as before e.g. with IFF systems (friend transmission antenna 182 for data processing to the Zen enemy identification) for airplanes or vehicles, returned to trale.

40 Fig. 9 shows schematically a response transmitter with frequency generators etc. to make necessary. Inven- lower bandwidth for the transmission of the selection according to z. B. in this case the and query signals. In this case, the pulses transmitted at the ground station, for example, the frequencies 1 and 2, the same selection and received from an aircraft, modified by the query functions as the four at the response transmitter circuit 66 and - according to the 45 in Fig. 4 used frequencies ^, B, C and ZX described in connection with FIG. 4C. During the first section of the interrogation cycle, these two frequencies are continuously selected from the frequencies emitted by the corresponding identity and sent to the control center and sent back via the corresponding. Receiving circuits to the inputs of selective

By generating the identification demodulators 190-1 and 190-2, which The IFF system uses band filters to activate the registers as the key signals in the control center less susceptible to interference, and it can also select certain frequencies. The ones from the more complicated and thus more secure keys use demodulators 190 signals emitted be det. If desired, the method according to the invention can be used directly on the one hand, and via delay-related methods on the other hand, to send flight circuits 192-1 or 192-2 to the four unit groups to be queried in total or placed in the course of the coincidence level 65,! ede this connection with a radio beacon system used delay circuits 192 causes a delay, that once through the one from the radio beacon, which is about as long as a binary digit of the sent signals whose identity is indicated, during the third part of the interrogation cycle while the signals returned by the aircraft β »transmitted interrogation signals, the identity of the aircraft and other information if the two frequencies 1 and 2 at the same time

how altitude, flight direction, airspeed are sent from the control center, the Koinziusw. contain. denzgrad 65 by the two undelayed and the

The two delayed signals according to the invention can also be advantageously used in terrestrial satellites according to a delay method, since there is substantial savings in terms of space and technology to operate the register 60, compared to the duration of a binary digit. This decent expense of the equipment for the transmission speaks the first selection signal with the frequencies of the data from various measuring devices with it brings zen A, B, C and D of the responder according to the

Figures 4A to 4C. During the second section of the interrogation cycle, the control center sends signal 2 as the second selection signal. If the described Responder is to be queried, a coincidence circuit with an inverse output is used accordingly the reversing stage 62 according to FIGS. 4A to 4C switched so that it receives the delayed and the undelayed signal 2 at two of its inputs, while it receives the control signal from register 60 at its third input. The instantaneous Signal 2 from the output of demodulator 190-2 is delayed through a delay circuit 194 with a delay fed by a binary digit length, so that all signals at the same time at the input of the inverter 62 appear. As long as frequency 2 is received as the second selection signal, the register remains 60 ready for use. However, if the inverter 62 does not have one or both signals at its three inputs receives, it emits a pulse to reset the register 60 via a coupling circuit 61.

During the third section of the interrogation cycle, the central unit continuously outputs frequency 2, which the register 60 keeps operational. The query signals are as binary signals on the frequency 1 transferred. The query binary digits appearing without delay at the output of the demodulator 190-1 are applied to one input of an AND circuit 198, while that of the delay circuit 192-1 output delayed query binary digits to one input of a second AND circuit 196 can be applied. In this way two binary pulses 1 or 0 are generated, a direct and a delayed one, while only a single binary signal was sent. AND gates 196 and 198 also receive a continuous turn-on signal from the »Stelk output of register 60, so that when the query binary signals are received, they each receive a signal output, which is fed to the circuit 66, where both signals in the manner described be modified. The modified binary signals are either sent back to the control center directly or via an amplitude-modulated, frequency-modulated, phase-modulated or the like Channel. In addition, one of the three can also be described in connection with FIGS. 4A to 4C Find facilities for AF modulation of the signals use.

So it can be seen when switching According to FIG. 9, the two supplied to the circuit 66 Interrogation signals generated by a single signal and not by the two separate signals, as in the case of the reply transmitters according to FIGS. 4 A up to 4 C were required to produce the two signals. This arrangement leads to a saving with regard to the bandwidth of the transmitted spectrum, since the same selection and query produced by using only two signals in place of the four previously used signals will. Of course, however, this order can be expanded to include any Contains number of signals used for selection and / or interrogation.

Claims (18)

Patent claims: I. Procedure for the remote monitoring of the operating status of an arbitrarily large number of devices, limited only by the width of the frequency band available for signal transmission, the number of which is subdivided into different channels in upper groups, by a control center that sends out interrogation signals in a cyclical sequence which can be converted into response signals by a responder in each of the devices to be monitored in its operating state in a characterizing way, characterized in that in each cycle at least one signal sequence which makes a certain main group of responders ready for operation in each main group, and then an interrogation signal is sent out, and the interrogation signal in all reply transmitters of the selected main groups on the one hand in a manner characteristic of each individual device of this main group, it is modified from all other devices only the main group in question, where the same characteristic modification is assigned to one device in each group in each main group and, on the other hand, can be logically modified in a manner characteristic of the operating state of the device in question. 2. The method according to claim 1, characterized in that that the response signals of all devices of each main group in the center to the characteristic Modifications and the operating status of the individual devices can be analyzed. 3. The method according to claim 1 or 2, characterized in that in each. Interrogation cycle first a first signal sequence is sent out, which is composed of η different frequencies, which are selected from m available frequencies and in each main group makes a main group of devices ready for operation, and that then a second signal sequence is sent out, which is composed of k different frequencies which are selected from the η frequencies of the first signal sequence and resets all devices of the main groups made ready for operation by the first signal sequence, with the exception of the devices in each subgroup, to the non-operational state. 4. The method according to claim 3, characterized in that the interrogation signals are transmitted to those of the η frequencies of the first signal sequence which do not belong to the k frequencies of the second signal sequence. 5. The method according to any one of the preceding claims, characterized in that the of the selection and query signals sent out by the control center are modulated onto a carrier wave will. 6. The method according to any one of the preceding claims, characterized in that the Query signals are represented by binary digits. 7. The method according to claim 6, characterized in that the logical modification of the Query signals in the generation and combination of real and / or complementary binary digits consists. 8. The method according to claim 7, characterized in that the logically modified binary digits the query signals are converted into response signals by the fact that the 809 658/1580 numeric digits through characteristic of the device Frequencies are represented. 9. The method according to claim 8, characterized in that the characteristic frequencies are generated in the reply transmitters themselves. 10. The method according to claim 9, characterized in that the generation of the characteristic Frequencies of the to be queried depending on the operating status of the respectively associated Device modified binary query signals is initiated. 11. The method according to claim 9, characterized in that that the characteristic frequencies are generated as long as the second signal sequence is received, and that the characteristic frequencies depending on the Modified binary response signals are modulated on the operating state of the respective associated device will. 12. The method according to claim 8, characterized in that the characteristic frequencies, the number of which is equal to the number of devices belonging to a subgroup and to which the binary interrogation signals are modulated, sent from the control center to the reply transmitters each of which has its characteristic frequency from the entire frequency spectrum filters out. 13. The method according to claim 12, characterized in that the characteristic frequency is allowed through as long as the second signal sequence is present, and that the characteristic Frequency modified depending on the operating status of the device to be queried Interrogation signals are modulated. 14. The method according to any one of the preceding claims, characterized in that the response signals for the purpose of checking for errors at the control center are compared with the query signals and checked to see whether they are possible Represent modifications of the same, and that the response signals of those subgroups for billing in which an error is detected. 15. Apparatus for performing the method according to any one of the preceding claims, wherein the individual reply transmitters are each assigned to a station provided with a program receiver and the stations are divided into main, upper and sub-groups, with a single center having a single device for delivering messages and with devices for transmitting signals between the control center and the stations, characterized in that the control center (30) has a signal source (37) for generating cyclical query signals in different signal sequences (A, B, C, D) of different frequencies (A to T), as well as devices for receiving and evaluating response signals received from the response transmitters (32) and that each response. transmitter has a device for receiving interrogation signals transmitted by the control center (30), a device for modifying these signals in accordance with predetermined information properties and a device for retransmitting the modified interrogation signals. 16. The device according to claim 15, characterized in that each responder (32) having a device with the help of which the modified response signals to a predetermined Frequency can be amplitude modulated or some other modulation for identification of the respective responder (32). 17. The device according to claim 15, characterized in that each responder (32) can only receive and answer certain signal sequences of the interrogation signals. 18. The device according to claim 17, characterized in that the transponder has a device (60) for partial actuation by a first signal sequence (A, B, C, D) and a further device (65, 66) for complete commissioning by a second signal sequence (D) . 19. The device according to claim 18, characterized in that the second signal sequence (D) has frequencies of the first signal sequence (A, B, C, D) . 20. Apparatus according to claim 18 or 19, characterized in that the interrogation signals are frequencies (A, B, C) of the first signal sequence (A, B, C, D) which are missing from the second signal sequence (D). 21. Device according to one of claims 15 to 20, which is based on the processing of in Interrogation signals present in the form of binary digits are set up, characterized in that for Modification of these signals in accordance with the operating status of the interrogation signals monitored device in the responder logic circuits (66) for generating a binary coded response signals are provided. 22. Device according to one of claims 15 to 21, characterized in that the responder (32) a simultaneously responsive to the first signal sequence and its delayed value Having means (62) for triggering the modified response signals. 23. Device according to one of claims 15 to 21, characterized in that the responder (32) two devices for receiving the first of two frequencies or the second signal sequence consisting of one frequency and two delay circuits (192-1, 192-2) which is connected to the first and second receiving means (190-1 and 190-2), respectively are and provide delayed values of the two signal sequences, and that one on the simultaneous occurrence of the two frequencies as well as device (65) responding to their delayed values Generating a preparation signal and initiating the retransmission of the modified Signals with subsequent reception of one of the two frequencies is provided alone. 24. Device according to one of claims 15 to 23, characterized in that a device (56) for the selective selection of the different frequencies (A to J) of the signal sequences of the interrogation signals is provided. 25. The device according to claim 24, characterized in that the device (56) for the selective selection of the different frequencies (A to T) consists of circles tuned to specific frequencies. 26. The device according to claim 24 or 25, characterized in that a register (60) is provided which, when the frequencies of the first signal sequence match the frequency ranges of the device (56) for the selective selection of the different frequencies (A to Γ) in operation is set. 27. The device according to claim 18, characterized characterized in that the signal sequences only depend on the successive reception of certain signal sequences responsive device (65) comprises an unlocking signal generating device which makes the return transmission device (70, 75, 77) operational. 28. Device according to claims 15 to 27, characterized in that a preparatory signal emitted when one of the device (56) for the selective selection of the different frequencies on the basis of a first signal sequence (A, B, C, D) occurs , a first through - Ao laßsignal generating coincidence stage (58) and a set by this pass signal for generating a second pass signal in readiness for operation register (60) is provided that the device for selective selection of the different frequencies also occurs when one of a smaller number of frequencies than the first occurs Signal sequence existing second signal sequence (D) of predetermined frequencies generates a second preparation signal and the device (56D) generating the first pass signal continues to generate the first pass signal when the second signal sequence (D) occurs in order to keep the register (60) operational and the second Pass signal at the coincidence stage (65) to generate, and that a circuit (66) for the logical coding of the binary interrogation signals in accordance with the respective operating state and the respective transmitter selection of the device, a modulating device with an oscillating circuit (71, 72) for amplitude modulation of predetermined frequencies of the coded characteristic of the responder binary response signals and devices (75, 77, 78) for retransmission of the modulated signals are provided. 29. Device according to one of the preceding claims, characterized in that in the control center (30) means for generating the amplitude modulation in the reply transmitters (32) of the coded binary signals required frequencies that facilities for transmission these frequencies to the responder (32) and that in each responder of a subgroup differently tuned band filters (89) to filter out these from each responder (32) the subgroup characteristic frequency are provided. Considered publications: German Auslegeschrift No. 1090 271,
928.1082 942.1094 636; British Patent No. 949 055; French patents No. 974 280,
1165453; U.S. Patents Nos. 3,048,780, 3,050,712,
2674512; Electronics, May 18, 1964, pp. 28/29. In addition 3 sheets of drawings 809 638/1530 11.68 © Bundesdruckerei Berlin