DE2139629A1 - Telephone dialing and signaling systems - Google Patents

Description

vln / Fo Munich-Pullach, August 5, 1971

IiATRONICS PTY. LIMITED, The Crescent, Kingsgrove, New South Wales 2208, Australia

Telephone dialing and signaling systems

The invention relates to telephone dialing and signaling systems and, more particularly, to such devices that operate automatically on address an abnormal condition at a first location to provide information corresponding to that condition to a selected one to signal distant place.

Most known automatic telephone dialers work on the principle of a continuous cable loop or tape loop, on which the relevant dialing information is pre-recorded. Other systems use counting relays and rotary selector combinations, as well as a switch operated by means of a toothed wheel or just mechanical Devices for dialing a standard telephone handset. Existing embodiments thus use moveable ones Parts and are therefore exposed to physical and chemical influences, so that the reliability of the same is seriously restricted. They also require personal attention, at least at the receiving end, to the Answer phone call.

NAL INSPECTED 209816/1318

It is an object of the present invention to provide an automatic telephone dialing and signaling system which is electrical Solid-state components used in the dialing and coding sections to thereby achieve a high degree of reliability, and which also has one via a normal phone line or network can record transmitted messages without incurring any personal attention required at the selected station at the time of the call P to make.

It is also the aim of the invention to create a system of the present type which enables a selected Change phone number and also change a coded word or information.

The present invention thus provides an automatic telephone dialing and signaling system with one or more Alarm stations that can be connected to an automatic telephone network with one or more control stations, the stations having solid state registers for storing the preselected dialing code and encoded messages, these To capture and record messages, wherein the alarm station or stations can be triggered by an abnormal state in order to send signals to the control stations or stations, so that signals are sent out to the alarm stations or alarm station for the reception of the former Confirm signals.

In the case of the telephone dialing and signaling systems described above, in which there is no operator at the receiving station is present, it is important to provide security for the correct transmission of the message.

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According to an advantageous embodiment according to the present In the invention, measures are taken from the receiving station or the receiving end to the sending station or the sending end To send back signals indicative of the identity of the selected station and also of the one received Message or message are characteristic.

In general, the invention relates to the transmission of various Alarm signals over a normal telephone network = Such an alarm device can be caused by fire, a Burglary, breakdown of the ventilation or cooling system, or triggered by any other event where these events can be reproduced by a change in the states of an electrical circuit, connected to an alarm station.

When the alarm station is triggered, it automatically dials a preselected control station via the normal telephone network, and when the latter responds, it transmits a coded message that is consistent with the originating one Alarm type is.

This message is then recorded in the control station «, It should be emphasized that several alarm stations can work together with a single control station and vice versa .

As stated earlier, in many cases it is important that the receiving station sends a signal back to the sending station and according to one embodiment of the present invention, the general operational sequence is as follows *.

If an external device triggers the alarm station, the latter sends the er = via a telephone network

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necessary dialing pulses that are stored in their register in order to call certain control stations. After the selection the alarm station waits for an identification signal from the control station for a certain period of time. If this Signal is received within the time period, the alarm station sends the precoded information and then waits ■ on a confirmation signal from the control station. After this

Receipt of this latter signal disconnects the alarm station ^ itself until it is reset.

If no identification or confirmation signal is received from the alarm station in the prescribed time, so the latter begins to vote again. This process can be repeated several times as required.

The message sent to the control station will be visible and audibly displayed and at the same time a similar display can be made at the alarm station after receiving the confirmation signal provided by the control station to indicate that an alarm has arisen, has been sent and has been properly recorded and confirmed. If desired, facilities can be found at the control station be provided in order to provide permanent recording in a punched tape, magnetic recording tape, this to print or otherwise record a permanent record.

Further advantages and details of the invention emerge from the description of exemplary embodiments which now follows referring to the drawing.

In this shows:

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Fig. 1 is a block diagram of the main components an alarm station according to the present invention with the corresponding Links;

2 shows a block diagram of the corresponding control station or its components;

3 to 6 show an embodiment of a circuit according to the alarm station of the present invention}

Fig. 7 and 8 a Stromlaufρlan the relay unit, which cooperates with the circuit according to Figures 3 to 6;

9 to 11 show the current flow plan of a corresponding one Control station;

Fig. 12 gives instructions in which way Figures 3 to 6, Figures 7 and 8 and Figures 9 to 11 are put together to form a get full circuit; and

13 shows a modified embodiment of the circuit for the alarm contacts if different codes are to be used for individual alarm systems.

If, according to FIG. 1, a source from an external source

arises

Bener alarm / that for example from a fire alarm device or an intrusion signaling device

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can, this alarm triggers and locks the unit actuated, which may include means for preventing re-actuation of the device until it is reset by a reset button and switches off the unit after 3 minutes. The trigger unit is on the shift control logic is connected, which in turn is fed by a pulse counter. This counter is from a fc coding plug or plug fed from which the possibility manages to change the code passed through the pulse counter in a simple manner.

Tongue relays are used to dial and transmit the code, with the coded message in the form of tone pulses which are generated in a local tone generator.

A 10 second clock creates the necessary time delay between the seizure of the telephone line and the transmission of dial pulses, and it also determines whether the identification signal was received by the control station within the 10 second period W. A 1 second clock provides the required interval between successive dial pulses.

When the dial pulses have been sent and the control station has been reached, the latter sends an identification signal, which is received via the telephone line and the Operated sequence counter, which in turn continues to send the relevant coded message to the control station in the form of To send tone impulses.

After the message has been recorded in the control station, a confirmation signal is sent back from this station.

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sent, received and decoded in the alarm station is actuated and a visual display of the alarm device in accordance with this message. The alarm station is then disconnected until it is reset by pressing the reset button will. If any irregularity occurs during the above process, the alarm station begins again to dial the required control station. This can be repeated three times, for example, under the control of the call counter.

The control station is illustrated schematically in FIG. The ringing button coming in over the telephone line will be detected by the ringing tone detector and actuated via the slide control logic the required reed relays to control the telephone line to be connected to send the identification signal back to the alarm station. This creates a 1 second impulse tone Then the encoded message is sent (controlled by the 1 second clock) over the telephone line received in the form of sound impulses from the alarm station, is decoded in the impulse decoder and displayed, for example by numeric display tubes. At the same time, an audible alarm signal can be given.

The control station then sends a confirmation signal in the form of a pulsed tone (which is from the local tone generator derived) back to the alarm station to turn off the latter.

The various steps of the control station are under the control of a sequential counter. Remains in the control station the alarm is visible and audible until the latter is reset by pressing a reset button on the control station.

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It should be emphasized that the system described above can also be used in the same way in connection with other communication systems can be used, for example in connection with carrier wave telephone systems or Eadio or Radio links.

There is also the possibility of dialing a second selected number when selecting the first Number remains unsuccessful (no identification signal is received within the specified time period).

In addition, measures for testing can be provided, with the signals from the alarm station at the control station identified as test signals. If an alarm occurs during the test period, this alarm can be the Masking test signals to provide the control station with the correct alarm.

With reference to FIGS. 3 to 8, the precise mode of operation of the alarm station according to an exemplary embodiment will now be discussed according to the present invention. In the following description, the first digit of each reference number indicates the Figure in which this reference number can be found.

When the alarm station is connected to a 751 telephone line the two relays 733 and 734- are in their not operationally clear, wherein the contacts 739 and 738 assume the position shown. These contacts switch a resistor 736 and a capacity 737 to the telephone line 751 and represent the normal AC load of a telephone bell. A 12 volt battery is connected to the unit, however, the power supply is cut off when the relay contact 19 of the relay 718 is open. However, E_ flows

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a constant current through resistor 702 and through the alarm contact 752, which is connected in parallel to a capacitance 701. This alarm contact can be the contact of a fire or intruder alarm unit or any other unit that is monitoring shall be.

When the alarm contact 752 opens, i.e. when an alarm condition exists, a current flows through the resistor 702 and charges the capacity 701. When the voltage on the capacitance 701 rises, a silicone-controlled rectifier is used 704 is turned on, as is transistor 712 via the Diode 705 switched on. This creates an impulse on the collector load resistor stood 753 of the transistor 712 and this pulse is over the capacitance 713 the silicone-controlled rectifier 714 supplied so that it is turned on.

If the silicone-controlled rectifier 714 is now switched on, the heater 718 is excited and the relay contact 719 closes. The 12 volts are supplied to all MF circuits via this relay contact fed to the unit and the clock circuits. the 12 volts are also fed to the 3.6 volt regulator 721. This control device then supplies all logical ones Circuits with the + Vcc voltage.

When the power is first turned on, some of the counters or divider stages of the logical network may have an undesirable effect assume logical state.

The '+ Vcc voltage is applied to gate 319 through resistor 319A and capacitance 319B. When capacitor 319B charges, gate 319 generates a reset pulse. This reset pulse resets the three-ring counter 428 to the zero condition or state. This pulse also sets the 24 count ring counter 335 on the count

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No. 1 and continues to set up the repeating flip-flop 116 return to its original state.

As soon as the 24 counting step ring counter 335 is correctly set or reset, the gate 336 in the decoder 320 generates step or counting step no. 1. During counting step 1, the transistor 476 energizes the relay 734 and the relay contact 738 is moved and connects a resistor 75 ^ - to the telephone line 751 · This creates a DC voltage loop through the telephone network and the telephone picks up this call and connects itself to the telephone line 751 · During this counting step 1, the gate 310 also turns off the transistor 301. This transistor represents a short circuit for the capacitance 303. When the transistor 301 is closed, the capacitance 303 begins to charge, and the current can flow through the resistor 302. After a preset time period of 10 seconds, the double base diode 304 generates a pulse which reaches an inverter 306 and from there to the gate 312. This gate 312 is connected to the gate 417 and the inverter 420, to which a buffer stage 422 is connected. The buffer stage 422 leads the pulse generated at 304 to the clock line of the ring counter 335. The ring counter 335 now counts to counting step 2. In counting step 2, the transistor 476 and the relay 734 are de-energized and the relay contact 738 returns to its normal switching position. At the same time, transistor 487 is turned on via gates 468, 477, 485 and 486 and relay 732 is energized. The corresponding contact 735 closes and establishes a short-circuit path across the telephone line 751, whereby the DC voltage loop is maintained. The transistor 424 is also closed via the gate 468. The transistor 424 had the capacitance 426 short-circuited to ground. The capacity 426 is charging

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through the resistor 4-25. After an on-time of 1 second turns on the dual base diode 427 and generates one Pulse that goes to gate 417. This is where the impulse comes from to gates 420 and 422 and finally it reaches the ring counter 335 · Der as a clock pulse or clock input variable Ring counter 335 then also counts the counting step 3 · Das Gate 338 in decoder 320 decodes counting step 3 and generates an output. This output variable comes from the Diode 359 to coding board 600 and then to one of the selected ones Inverter stages 611 - 620.

The output of the selected inverter becomes the corresponding one Gates 621-630 supplied.

A signal is also sent from gate 338 in decoder 320 via gates 470, 479, 488 and 492 to the digit pulse generator. The digit pulse generator 593a, 593b and the inverter 594 generate pulses that reach the counting stage 595 »596, which divides by 3. The pulse from the digit pulse generator has a Duration of 33 milliseconds. The counter dividing by 3 is switched in such a way that it generates pulses with a duty cycle of 2: generated. This gives an output pulse with a duration of 33 milliseconds with a pulse interval of 66 milliseconds.

From the counter dividing by 3, the pulses pass via the inverter stages 597, 598 to the digit pulse counter 599 · This is a binary coded decimal counter and the output variable of the same is decoded in a decimal decoder 500. The output size from the decimal decoder 500 is inverted in the inverter stages 501-5 ^ 0 and arrives at the corresponding gate 621-630.

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The output from the divide-by-3 counter also passes through gates 478, 4-85, 486 to transistor 487. Each Times when from the divide-by-3 counter 5951 596 a Pulse is generated, transistor 487 is closed. The relay 732 is de-energized and the relay contact 735 opens, see above that the telephone line is opened. These are the dialing pulses.

The digital pulse counter 599 receives successive pulses and the decoder 500 successively provides high levels or voltage values at its output 0 to 9. These high voltage values are inverted in the inverter stages 501 to 510 and arrive successively as zero to the gates 621-630. If a zero or a low voltage value has now been provided by one of the inverters 611 to likewise, which has been selected by the decoding table 600, then is the relevant gate output has a 1 or a high voltage value. This in turn has the consequence that one of the gates 631, 632 and 633, a zero or a lower voltage value generated at the output of the corresponding gate or offered w and after inversion by inverter 634 as 1 or as high voltage level to the gates 418 , 420 and to the buffer stage 422. This pulse shifts the ring counter 335 to counting step 4. At the same time, the shift pulse appearing at the output of the gate 420 is fed to the digital pulse counter 599 and also to the counter 595 »596 counting through 3. These two counters are reset to their original state.

During the counting step 4, the transistor 424 is closed again via the gate 468 and the 1 second clock generator, which consists of the resistor 425, the capacitance 426 and the double base diode 427 is excited. At the end of the 1 second

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period, the dual base diode 427 feeds a pulse into the Gate 417, so that through gates 420 and 422 the ring counter 335 is shifted to counting step 5. The counting steps or counting positions 5, 7, 9, 11, 13 and 15 are operational similar to the counting step or counting position 3 Every time a new set of gates 621 to 630 is generated by the diode 360, 361, 365 selected via the decoding table 600. In a similar way In terms of operation, counting steps 6, 8, 10, 12, 14 are similar to counting step 4.

When the ring counter 335 is shifted at the end of counting step 15 is, gate 351 decodes counting step 16. While of counting step 16, gates 474, 483 drive transistor 490. Relay 733 is energized. The relay contact 739 this relay is connected to the line transformer 74-0, so that the telephone line 751 is now connected to the transmitter. The relay 733 remains via the gates 472, 480, 474, 483 energized during subsequent counting steps I7, 19 and 21. The relay 733 also remains via the gates 473,. 482, 474, 483 energized during counts 18, 20 and 22.

The relay 733 is also energized during the counting step 23 of the decoder 320 via the gates 474,483. The relay 733 is now energized during counting steps 16-23. The transistor 491 is switched on via the gates 475> 4-84, the relay 731 is energized and its contact 74-1 is connected to the line süb he carrier 740 with the LF amplifier, which consists of the transistor 74-3, 74- 6 and associated circuits. During counting step 16, the 10 second clock also runs. The transistor 3OI is brought via the gates 309 _s 308 and 310 ■ in the unsaturated area. The output of the 10 second clock is now sent via gates 306, 311 and 313 to the repeat circuit. If an initial burst of sound from the control station during the 10 second period

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is received over the telephone line 75 ^, the capture LF amplifier transistors 74-5, 746, the rectifier 74-9 and the gate 850 this tone impulse and lead it to the gate 418, to generate a counting or shifting pulse. The ring counter 355 now counts to 17. During counting step 17 the relay is on 7J1 de-energized, the relay contact 441 of the same returns to the normal position and the tone generator, consisting of the Transistors and associated circuitry 751-756 now connected to the line transformer 740. The 1 second clock is excited via the gate 472, 480, 486 and turns transistor 424 off. The 1 second clock generator 427 with the assigned time constants according to the resistor 425 and the Capacity 426 is now running. Arrived at the end of the 1 second period a pulse to gate 417 for a count or shift pulse through gate 420 and driver stage 422. Of the Twistor ring counter 335 then also counts counting step 18. During counting step 18 as well as counting steps 20 and 22, which are similar, the digit pulse generator 593a, 593b is turned on via gates 473, 482, 488 and 492.

The divide-by-3 counter 595 »596, the digit pulse counters 599 and 500, the inverters 501 to 520 and the gates 621 to 634 operate in the manner described earlier. The signal coming out of the gate 353 of the decoder 320 is fed to the coding table 600 via the diode 366. This selects the number of pulses that should be generated for the first digit. The digit pulse train or pulse train now reaches the oscillator prevention transistor 756 via the gates 481 and 489. The tone generator, consisting of the transistor 755 and the tuning circuits 7 ^ 3 and 754, is switched on and off by the digital pulse train. The transistor amplifier 7 ^ 2 and 7 ^ 1 then sees a tone-coded pulse train on the relay contact 741 and the transformer 74-0

changed according to input

Received on ... ■ d & .i & l.SO .....

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Telephone line 751 in front of the ^ every consecutive digit indicates. If the correct number of pulses are generated for that particular digit, it will get a pulse of 334 through gate 418, 420 and buffer stage 422. This is a counting or shifting pulse and this shifts the ring counter 335 to the counting step 19. The 1 second clock 427 is energized through gates 472, 480 and 468, with transistor 424 being closed. When the 1 second time has passed is, a pulse passes through the gates 417, 420 and 422 to the ring counter 335 'so that it counts to 20. The counting step 20 is similar to counting step 18. Counting step 21 is similar to counting step 19

The digit coding of counting step 22 from gate 356 of the decoder 320 is not passed via a direct connection to the coding table 600, but via the switchover relay contact from 711 »to select one of two possible coding forms for the last digit. This form of coding is selected either by a normal alarm or during a test condition. The signal from gate 356 (decoder 320), which is activated via the changeover contact of relay 711 reaches the coding table via one of the two diodes 729 and 730 600 headed. When the counting step 22 is completed, the ring counter 335 counts to the counting step 23-Der Counting step 23 is similar to counting step 16. The 10 second clock is energized and the tone impulse amplifier is activated via the Line transformer 74-0 and relay contact 741 to the telephone line 751 connected. If a confirmation pulse before the When the 10 second period has elapsed, the burst of sound amplified by the transistors 743, 7 ^ 6 and transmitted by the Diode 749 and gate 850 was detected as a counting pulse or Shift pulse passed through gates 418, 420 and driver stage 422. The ring counter 335 now counts on the counting step

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24. Counting step 24 is performed by gate 358 in the decoder 320 decoded. A signal is passed from gate 358 to a silicone controlled one Rectifier 828. This silicone-controlled rectifier is switched on and the capacitance 826 can discharged via the signaling relay 827 (flag relay). That Signaling relay 827 comes into action and gives a permanent visual indication (not shown) that a message has been received has been sent, received and acknowledged. The signal decoded by gate 358 through gates 533 and 534 is passed via the capacitance 717 to the transistor 715 · the latter switched on for a short period of time and conducts the current, which normally flows through the silicone controlled rectifier 714. The silicone-controlled rectifier is switched off, the relay 718 is de-energized and the relay contact 719 of the same opens. The unit is now disabled. The relay 733 is de-energized and the relay contact 739 of the same becomes folded over, so that the line transformer 740 is disconnected from the telephone line 751 and the network, consisting of the resistor 736 and the capacity 737 back to the phone line is connected.

In those cases where the alarm station is not working properly works, measures have been taken to disconnect the alarm station from the telephone line after a period of 3 minutes. A clock, consisting of the double base diode 531 and the associated time-determining resistor 529 and capacitance 530, generates a pulse after a 3 minute period. This pulse arrives via gates 533 and 534 the switch-off or cut-off transistor 715 »as at an earlier point was declared.

If either during counting step 16 or 23 a tone burst is not received by the control station to allow the alarm station to operate before the 10 second period has elapsed

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initiate or confirm, the 10 second timer 304, with the associated circuit 302 and capacitance 303 »generated pulse via the gates 306, 311 and 313 to the Repeat flip-flop 316 passed. The zero output of the Flip-flops 316, which was originally set to a "zero", now becomes a "1" output variable. This "1" comes to the gates 483 and 484 and de-energizes the relays 733 and 734 via the transistors 490 and 491. The contacts 738 and 739 of these Relays will then return to the reset position and the original DC loop over telephone line 751 is now interrupted because the resistor 736 and the capacitance 737 are switched on again via the telephone line 751.

If the ring counter 335 has stopped counting, the 10 second clock continues via the gates 309, 308, 310 energizes and generates a second 10 second period. During this 10 second period, the telephone line 751 remains in their normal disconnected state. When this second 10 second period has passed, the pulse output becomes of the clock 304 again passed to the repeating flip-flop 316 via the gates 306, 311 and 313. The flip-flop 316 changes its state. The zero output is now too a "1" output and it is sent over the R / C network 370 generates a pulse that goes to the input of gate 321. This pulse reaches the reset line via buffer stage 323 371 of the counter 335

The ring counter 335 is reset to its original counting state or counting step "1". At the same time will the pulse which appears at the "zero" terminal of flip-flop 316 is fed to the 3 ring counter 428. This counter counts by one unit Further. The alarm station has now returned to its original starting condition or condition and is kicking again the second time for the counting step 1 to 16 or counting step

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23 in operation.

The alarm station tries to establish a connection three times in a row with the control station, and if no start or initiation signal is received in counting step 16 is received or at ^ ählstep 23 no confirmation signal the cycle is repeated, but each time the three ring counter 428 increments one unit.

When the third hoof is completed by gates 532, 533 and 534- a switch-off pulse passes through the transistor 715 and this switches off or disconnects the entire alarm station.

To call a 6 digit number, gate 350 decodes im Decoder 320 the fifteenth counting step of the ring counter 335 and a pulse reaches the gate 3I4- »whereby the gate 315 a count or shift signal through gates 4-18, 4-20 and 4-22 sends. The ring counter 335 counts directly to the counting step 16.

If a test of the circuit arrangement is required, the test pushbutton 709 is depressed, the capacitance 707 charges up through the resistor and this voltage is fed to the control connection of the silicone-controlled rectifier 710. The silicone controlled rectifier 710 is switched on and relay 711 is energized. The contact of the relay 711 is switched. The transistor 712 is through the diode 706 switched on and generates an impulse which reaches the silicone-controlled rectifier 714- via the capacitor 713. The silicone controlled Rectifier 714 is switched on and relay 7I8 is energized, relay contact 719 closes and it arrives Electricity to the alarm station. The alarm station now goes through all stages as described above until the counting step

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22 is reached. That during counting step 22 from the decoding gate 356 in the decoder 320 is now fed through the contact of the relay 711 through the diode 730.

This connection ensures a different coding for the third digit of the tone-coded pulse train and sees one Identification in the control station for the test sequence instead of the normal alarm sequence.

A push button 703 is also provided to the alarm station disconnect and the silicone controlled rectifier 704-, or 714-, as required, out of readiness to set.

In the case where different alarm signals in the system are to occur, the alarm contact 752 in FIG 7 is replaced by an arrangement as shown in FIG. A variety of alarm contacts AC1, AC2 .... A09, AC10 each have an isolating contact and a closing contact on. All isolating or normally closed contacts are connected in series with terminals F1, F2 (Fig. 7), so that an operation of any of these contacts will trigger the alarm device triggers. The individual contacts can be used e.g. for test purposes, fire, break-in and certain temperature conditions etc. may be provided. In order to be able to differentiate between their operations, the corresponding ones are normally open Closing contacts connected to the coding board so that a specific code is sent or transmitted for each alarm, that for the alarm type according to any condition occurring is characteristic.

According to FIGS. 9 to 11, the entire circuit arrangement supplied with power via a voltage regulating arrangement 1001, the

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the respective voltage regulators contain to 12 volts to drive all relays and indicator lights, and 5 volts for the indicator tube and the driver stage for the indicator tube to be provided. Two series connected diodes (not shown) in the voltage regulator arrangement 1001 produce the required Voltage drop to provide the 3 x 6 volts fed to all other logic circuits.

Assume that the station is in another reset position and that the reset button 1030 is depressed became. The two 10 pedometers 902 and 903 are located themselves in their "zero" positions or states and see a drive voltage for transistor 904 and indicator lamp 905 before. This indicates that the unit is operational and ready to accept any incoming message to record.

When an alarm station is a control station over a telephone line calls, a ringing button is normally fed into the telephone line and arrives at the control station. This Ring tone signal consists of a pulse-modulated AC signal with a frequency between 12 and 50 Hz.

A contact 1006 of a relay 1012 normally connects the telephone line 907 to a bridge rectifier, the consists of 4 diodes 1008-1011. The return to the telephone line is via a 1.5 microfarad capacitance 1013

The voltage developed across the diode bridge is fed to a relay 1014. A zener diode 1016 acts as a protective device against increased tension. During the first push of the ring, relay 1014 is energized. The relay contact 1015 of this relay is switched over and connects the capacity 1017 with the "zero" output of the 10 step counter 903.

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A voltage of 3.6 volts is available at this output and the capacity 1017 is charged as a result.

When the first push of the loudspeaker stops, the relay 1014 is de-energized, the relay contact 1015 is switched over and the Capacitance 1017 is now one of the inputs of gate 1018, 1019 connected, which form an RST flip-flop. That flip-flop was originally deferred to provide a low voltage on the output of 1019 and a high voltage on the output from 1018. If the capacitance 1017 is connected to 1018, the latter changes its state and with this also 1019 · The output of 1019 should rise to + Vcc and generate a pulse which is passed through capacitor 1020 reaches gate 1021. This pulse is passed from gate 1021 to a step counter 902. This counter counts one step further. The output of 902 is decoded by the decoder 903 and a signal is now sent to output no. 1. The signal at output no. 1 of 903 now goes to the gates 922 and 923. From gate 923? to which the inverter 1024, the gate 1025 and the inverter 1026 will connect the signal decoded at 903 is fed to transistor 1027. The transistor 1027 is switched on or brought into the saturated range and energizes the relay 1012. The relay contact 1006 is now transferred so that the telephone line 907 is disconnected from the ringer detection circuit 1008-1011, and the telephone line 907 to the carrier line 1128, is closed and is connected to an LF amplifier or an oscillator connected to it. The relay 1012 remains closed during steps 1, 2, 6 and 7 of the counter and decoder 902, 903. These four steps are going through • the gate 923i as previously set out, decoded. The relay 1012 remains closed during steps 3, 4 and 5; these three steps are performed by gate 929 to which the Inverter 930 connects, decoded.

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The output from this inverter comes from the second connection from gate 1025t to which the inverter 1026 is connected, and then arrives at transistor 1027 as previously mentioned.

Gate 922 is also energized during step 1 and closes transistor 906. This allows the capacitance Charge 1003 through resistor 1002. When the voltage of the capacitance 1003 reaches the correct value (after 1 second) the double base diode 1004 ignites and generates a pulse which reaches the gate 1021. This, is a count or Shift pulse. This pulse shifts the 10-step counter arrangement 902, 903 from counting step 1 to counting step 2.

In counting step 2, the transistor 906 is switched off again in accordance with the decoding by the gate 922. After a second the transistor 1004 enters the saturation region again. During counting step 2, gate 901 is the same energized and a voltage value is passed to transistor 1101 to turn it on.

The transistor 1101 then provides a signal which comes out from the tone generator 1102 to the buffer transistor and amplifier 1103 and to the emitter follower transistor 11Θ4 / Γ That from the Outgoing signal from emitter follower 1104 is brought to the secondary side of line transformer 1128 by relay 1007. An identification tone will then be emitted from the control station transmitted to the alarm station. At the end of the 1 second period, the dual base diode 1004 re-ignites and it spills over the gate 1021 a count or shift pulse to the 10 step counter or counting arrangement 902, 903, so that counting is shifted from counting step 2 to counting step 3. During the counting step 3 as well as during counting steps 4 and 5

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the gate 929 through the inverter 930 the transistor 1022 and energizes relay 1007 · relay 100? or its contact 1107 is switched so that the secondary side of the line transformer 1128 is separated from the tone generator (1104) and the secondary side is connected to the sound amplifier (1105). The control station is now ready to receive coded tone impulses to be received by the alarm station. The encoded tone pulses from the alarm station are stored in transistors 1105 and 1106 amplified, which are connected as a selective amplifier, and are rectified by the diode 1103. After rectification these impulses reach a pulse shaper stage, which consists of gates 1022 and 1023, which are connected as Schmidt triggers. Closes to this Schmidt trigger an inverter stage 1024 connects. The tone-coded pulse train is now conducted in two directions: First, it passes through the inverter 1112 to the gates 1109, 1110 and 1111 and to the counter and display system 1113, 1114, 1115 »and secondly to that "End of burst detector circuit" (gates 908 through 911).

In counting step 3, the inverter 1116 feeds a signal from the step counter to the gate 1109, so that this gate is on standby is set to receive a coded pulse train and this pulse train to 1113 »a binary coded decimal counter which is followed by a decoder 1117 which drives the visual display device or system 1118.

When a pulse train is received, a counting step is transmitted to 1113, and then after decoding the correct number of received pulses is displayed. The one available from the 10 stage counter during counting step 3 Signal also goes to gates 1110 and 1111 without being inverted beforehand, and this signal blocks these two gates so that they do not let the coded pulse train through.

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The pulse train is also fed to the "end of the sound burst detector" * The first pulse of the pulse train, which is fed to the "end of the sound burst detector", represents the RS flip-flop, the consists of gates 908 and 909, back. The output variable of 908 falls immediately afterwards. As a result, the gate 910 is set to readiness and after inversion by 911 the first pulse and all subsequent pulses become a transistor 912 headed. The transistor 912 is turned on and discharges the capacitance 913 · The voltage then increases slowly of the capacitance 913, with each newly appearing impulse however, transistor 912 turns on and discharges the capacitance 913 · As long as there is a train of impulses, the discharges Transistor 912 the capacitance 913 · When the pulse train completes is and during the period of 1 second that occurs between two successive pulse trains, the capacitance becomes 913 charged to a value, so that the transistor 915 becomes conductive and the gates 1028 and 1029, which form a Schmidt trigger, generate an output pulse. This impulse is forwarded in the following way:

1) It arrives at gate 909 and resets it. This means that any 1
910 to arrive.

any further impulses are prevented from reaching the gate

2) It arrives at gate 1021 and generates a counting or shifting pulse which is sent to the 10-stage counter arrangement 902, 903 arrives.

As a result, if there is a gap at the end of a pulse train, the counter counts from counting step 3 to counting step 4.

The same sequence is repeated during counting step 4- of events to represent the second digit then follows

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the counting step 5, with the third digit being displayed.

The effect of gates 1109, 1110 and 1111 with inverters 1116, 1120 and 1119 is similar to that for the first Digit was written in counting step 3. If the third digit was received in counting step 5, the output shifts of the gate 1029 through the gate 1021 the stage counter arrangement 902, 903 for counting step 6. During the counting step 6, a 1 second delay is generated, as explained earlier in connection with counting step 1 became. At the beginning of counting step 6, the transistor 1022 is switched off, the relay 1012 is de-energized and the tone generator is again sent to the line transformer 1128 by the Contact 1107 connected. When the 1 second delay time has elapsed, the shift input via gate 1021 Shift pulse the 10 stage counter 902, 903 in the counting step 7. This counting step is similar to counting step 2. The tone generator applies a tone signal to telephone line 907, da the transistor 1102 is now switched on or conducting through the gate 901.

The 1 second clock generator 1004 is set to readiness via the gate 922 and the transistor 906. For the duration of one Second, a sound signal is sent back from the control station to the alarm station to indicate that the encoded message has been received to confirm. When the 1 second time has elapsed, clock 1004 shifts the 10th through gate 1021 Step counter 902.903 in counting step 9.

At counting step 9, a signal is sent to the inverter buffer stage 916 and an audio tone generator 917 is on standby set to a. through transistors 918 and 919 Speaker 920 and an audible warning indicator that

209816/1318

to indicate that a message has been received and displayed.

To return the control station to its normal, standard operation or to reset the state, the reset push button 1030 is depressed and the capacitance 1005 sends a pulse via the buffer levels IO31 and 1032 to the following levels to reset to the "zero" or original state: The 3 display 11 or display counters 1113, 1114 and 1115, den Ring tone detector flip-flop 1018, 1019 and the 10 step counter 902.

The relay 1012 is now de-energized, the contact 1006 of the same is switched over and connects the ringer detector 1008-1011 the telephone line 907 · The indicator light 905 »that of the transistor 904 is driven, is turned on again to indicate that the unit is in the operational state.

A number of modifications can be made to the circuits and components to suit specific conditions or to meet requirements as long as the encoded message is automatically sent to an automatically selected control station is transmitted, which in turn automatically identifies and receives the message from confirmed by the alarm station.

All recognizable in the description and in the drawings The technical details shown are important for the invention.

209816/1318

Claims (7)

PATENT CLAIMS Automatic telephone dialing and signaling system, characterized in that one or more alarm stations are provided that are connected to one or more control stations via an automatic telephone network The stations can be solid state registers for storing a preselected dial code and encoded messages have, as well as a device for receiving and recording the messages that further the alarm station (s) can be triggered by an exceptional state in order thereby to send signals to the control station (s), and that the control station (s) have facilities for sending the signals to an alarm station or stations that acknowledge receipt of the first-mentioned signals. 2. System according to Claim 1, characterized in that the control station (s) have means for sending back an identification signal to the calling alarm station. i 3. System according to claim 2, characterized in that the Transmission or transmission of the coded message from the alarm station to the control station can be automatically delayed until the identification signal from the control station is received at the alarm station. 4. System according to claim 3, characterized in that the Dialing message and the encoded message is automatically repeatable if the identification signal is not within is received at a prescribed time. 209816/1318 5. System according to claim 4-, characterized in that a Hoof counter is provided for determining the number of repetitions. 6. System according to any one of the preceding claims, characterized in that each alarm station is provided with a time delay device is equipped to transmit or send a Wählkpds and an encoded message a certain Time period after triggering. 7. System according to any one of the preceding claims, characterized in that the confirmation information or Message is recorded at the alarm station. 209816/1318