RU2036515C1 - Signaling device - Google Patents

Abstract

FIELD: communication engineering. SUBSTANCE: device has two-wire communication line connected through band filters to radio-pulse generator, receive-monitor console, sine-voltage generator. Line is also connected to inputs, outputs, and power inputs of N subscriber stations. Radio-pulse generator polls subscriber stations. Supply voltage is passed from sine-voltage generator to subscriber station. Polling signals of subscriber station go through noise-suppression unit to radio-pulse-to-video-pulse converter. Response delay element in subscriber station counts out definite number of video pulses and enable operation of message-code shaping unit which shapes station status code in case subscriber status signal is applied to its second input. Subscriber station response in the form of radio pulses arrives at receive-monitor console. Subscriber station also incorporates polling signal identification unit and subscriber polling time space shaper. EFFECT: improved noise immunity, enlarged number of subscriber stations without reducing validity of polling results. 8 cl, 8 dwg

Description

 The invention relates to control devices and can be used in devices for voting, as well as for monitoring the status of objects and communication lines in remote control systems.

 A device is known for automatically counting the number of votes cast in meeting rooms [1] with the installation of contact switches in delegate places and step seekers, which alternately connect individual contact chains to electric counting mechanisms, taking into account the total number of closed contacts by the number of received pulses. The device employs capacitors in the number of delegate seats, pre-charged from current sources and alternately connected to the thyratron anode circuit using one of the contact finder contact groups, the contacts of the second group of which are used to simultaneously connect the corresponding contact at the delegate location to the thyratron grid so that when this contact was closed, the thyratron ignited, causing one of the capacitors to discharge to the circuit of the counting mechanism.

 Also known are devices for automatic vote counting [2] using contacts installed at delegate places and step finders, which bypass their contacts sending current pulses to the counters.

 A disadvantage of the known technical solutions is to reduce the reliability of the survey results with an increase in the number of subscribers. This is because the subscriber response signal in known devices forms the discharge of the corresponding capacitor after the subscriber presses the button and closes the corresponding circuits. In this case, the amplitude of the generated pulse must be preserved until the moment the interrogator polls this circuit. The presence of leakage currents in known devices has a negative effect on the stability of the amplitude of the response pulse, and with a large number of subscribers in the circuits with the highest leakage currents, the amplitude of the response pulse can be indistinguishable for a step finder, for example, a positive response of the subscriber can be taken as negative. In addition, the presence in the devices of a large number of switching contacts causes, as a result of sparking, the constant presence of an interference signal having a wide frequency spectrum and unstable amplitude-frequency and temporal characteristics. This reduces the noise immunity of known devices.

 The closest technical solution to the proposed one is a device for security and fire alarms [3] Subscriber devices and a transmitter of the known device are powered from one power source and connected by a power bus. The output of the transmitter and the inputs of the subscriber units are connected via a communication line. The outputs of the subscriber devices are connected via a second communication line, a switch and a rectangular pulse generator to the input of the transmitter, which is connected to the control panel by the second output through filters. Each subscriber unit contains a detector, a code switch and alarm sensors. In addition, at the input of each subscriber unit, except the first, delay units are installed. The transmitter generates a powerful rectangular test pulse at its output, which appears at the outputs of the detectors with a delay corresponding to the code number of the subscriber unit. The signal from each alarm sensor enters the detector through the code switch also with a corresponding time delay. Thus, in the prototype, the feature of the subscriber device is contained in the value of the time delay of the pulses from the outputs of the detectors with respect to the test signal.

 A disadvantage of the known device is that it has a limit on the number of subscribers served. This is because the delay of the test signal in the subscriber devices is carried out using analog delay lines, and the higher the serial number of the subscriber, the greater the delay value of the delay line at the input of the subscriber device. This leads to a strong attenuation of the test signal and to increase the number of subscriber devices requires an increase in the power of the transmitting device.

 In addition, the known technical solution has low noise immunity, since subscriber devices are in a constant state of readiness, i.e. The supply voltage is supplied to them immediately after turning on the device to the network until a test pulse is supplied from the transmitter. In this case, the detector response signal is a short pulse, and the noise immunity of the device is determined by the threshold of the switch. Therefore, in the event of interference in the communication line with the transmitter, the detector, being in constant readiness, produces a short pulse at the output. If its amplitude exceeds the threshold of the switch, this pulse is fed to the input of the rectangular pulse generator and causes its false response. If such a situation arises during the interrogation of subscriber devices (since the supply voltage from the interrogated subscriber devices is not removed) and some of the subscriber devices generates a repeated pulse at the output with an amplitude exceeding the threshold of the switch, then the whole device may fail .

 Thus, the known devices for voting and for signaling do not allow to increase the number of subscriber devices without reducing the reliability of the survey results, as well as to increase noise immunity.

 The invention allows to create a device for signaling, in which it is possible to increase the number of subscriber devices without compromising the reliability of the survey results, as well as increased noise immunity.

 Connection to a communication line of a sinusoidal oscillation generator, a radio pulse generator and a control panel via bandpass filters provides communication with subscriber devices via one common communication line. This excludes special requirements for the communication line, which can be used as any two-wire line with a wave impedance of 100 to 1000 Ohms. Connecting a sinusoidal oscillation generator to the communication line through its band-pass filter allows you to separate the operating frequencies of the radio pulse generator and the sinusoidal oscillator. This, in turn, allows you to transfer power interference to a frequency range different from the operating frequency of the radio pulse generator, which increases the noise immunity of the device and allows you to combine the information channel with the power network. The use of a sequence of radio pulses as a polling signal made it possible to form a subscriber response delay time by counting each subscriber station for a certain number of radio pulses. Moreover, due to the fact that each subscriber station has its own delay time, it forms it independently, an increase in the number of subscriber devices does not reduce the reliability of the survey results. An increase in the number of subscriber stations limits only the degree of signal attenuation in the line. At each subscriber station, the separation of the interference signal from the useful signal is achieved by monitoring the signal frequency, amplitude and duration, i.e. all the main parameters.

 Converting radio pulses to video pulses allows you to organize the temporary work of each subscriber device. The former of the polling time interval for the first video pulse generates a permission signal for generating a response delay and stores it at its output only for the duration of the polling of subscribers. The latter also increases the noise immunity of the device, as it eliminates the unauthorized response of subscriber points. The response delay element counts the video pulses arriving at the input of the pulse counter connected to the inputs of the multi-input element I. The polling signal identification block generates a strobe pulse, which in time coincides with approximately 1/2 of the video pulse. It also increases the noise immunity of the device. At the end of the countdown, the multi-input element And generates a pulse, which, due to communication with the second input of the polling signal identification block, disables the latter. This eliminates the repeated operation of the counter in the response delay element until the end of the subscriber polling time interval and also increases the noise immunity of the device. The signal generated by the multi-input element And is at the same time a permission signal for generating a subscriber’s response and starts the message code generating unit. The response code is converted by the converter into radio pulses and enters the communication line.

 Figure 1 shows a functional diagram of a device for signaling; figure 2 is a functional diagram of a response delay element; figure 3 is a functional block diagram of the interference suppression; figure 4 is a functional diagram of the Converter of radio pulses into video pulses; figure 5 functional block identification signal polling; 6 is a functional diagram of a converter of video pulses into radio pulses; 7 is a functional diagram of a power supply; on Fig diagrams explaining the operation of the device.

 Functional diagram of the device for signaling contains a communication line 1, a radio pulse generator 2 connected through a first band-pass filter 3 to a communication line 1; control panel 4 connected to the communication line 1 through the second band-pass filter 5; a sinusoidal voltage generator 6 connected by an output to communication line 1 through a third band-pass filter 7, N subscriber stations 8 connected by inputs and outputs to communication line 1.

 Each subscriber station 8 comprises a message code generating unit 9, an interference suppression unit 10, the inputs 11, 12 of which are the inputs of the subscriber station; a converter 13 of radio pulses into video pulses, a polling signal identification unit 14, a subscriber polling time interval generator 15, a response delay element 16, a subscriber status sensor 17. The interference suppression unit 10 is connected to the input of the converter of radio pulses to video pulses, which is connected to the first 18 input of the response delay element 16, to the first input 19 of the polling signal identification block 14 and to the input of the subscriber's polling time interval 15. The response delay element 16 by the output 20 is connected to the second input 21 of the polling signal identification block 14, the output of which 22 and the output of the polling time interval driver 15 are connected respectively to the second 23 and third 24 inputs of the response delay element 16, the output of which 20 is connected, in addition, to the second input of the message code generating unit 9, the first input of which is connected to the subscriber status sensor 17.

 In addition, the subscriber unit 8 includes a converter 25 of video pulses into radio pulses and a power supply 26. The converter 25 is connected to the output of the message code generating unit 9 by the input and by the output 27 to the communication line 1.

 The power supply 26 is connected by inputs 28 to the communication line 1.

 Block 10 interference suppression contains a serially connected broadband filter 29, the inputs of which are inputs 11, 12 of the subscriber station 8, an amplitude limiter 30, a narrow-band filter 31, the output of which is the output of block 10.

 The converter 13 of the radio pulses into video pulses contains a series-connected amplifier of radio pulses 32, the input of which is the input of the converter 13, an amplitude detector 33, a low-pass filter 34, a low-frequency amplifier 35, a video pulse shaper 36, a duration selector 37, the output of which is the output of the converter 13.

 The interrogation signal identification block 14 contains a fall-off pulse shaper 38, the input of which is the first 19 input of block 14, the delay element 39, the OR element 40, the second input of which is the second 21 input of block 14, and the output is the output 22 of block 14.

 Shaper 15 time interval polling of the subscriber can be performed, for example, in the form of a standby multivibrator with a restart.

 The response delay element 16 contains a pulse counter 41, the counting input of which is the first input 18, the recording enable input by the second input 23, the zeroing input by the third input 24 of the element 16. The outputs of the counter 41 are connected to the inputs of the multi-input element And 42, the output of which is the output 20 of the element 16 .

 The converter 25 video pulses in radio pulses contains a carrier frequency generator 43 connected to the input of the element And 44, the second input of which is the input of the converter 25, and the output is connected to the input of the power amplifier 45, the output connected to the bandpass filter 46, the outputs of which are the output 27 of the converter 25 .

 Shaper 36 video pulses in the Converter 13 of the radio pulses in the video pulses may be, for example, a Schmitt trigger.

 Shaper pulse generator 38 in the polling signal identification block 14 can be performed, for example, on the elements NOT and OR, the input and output of the element NOT connected to the inputs of the OR element, the output of which is the output of the driver 38, and a capacitor is NOT connected in parallel with the output of the element.

 The generator 2 radio pulses can be performed, for example, similarly to the Converter 26 video pulses into radio pulses.

 The Converter 51 of the radio pulses in the video pulses in the reception and control point 4 can be performed, for example, similarly to the Converter 13 of the radio pulses in the video pulses in the subscriber station 8.

 The power supply 26 contains a series-connected bandpass filter 47, the input of which is the input 28 of the block 26, the rectifier 48, the filter 49 of the rectifier and the voltage stabilizer 50, the output of which is the output of the power supply 26.

 The control panel 4 contains a converter 51 of the radio pulses into video pulses, the interface unit 52 and the computer 53. The input of the converter 51 is the input of the console 4. The converter 51 is connected to the interface unit 52, the input-output of which is connected to the computer 53, and the output of the interface unit 52 is the output of the remote control 4.

 Block 9 of the formation of the message code can be performed, for example, in the form of a pulse counter, which counts a certain number and the output of which is connected to the input of the element And, the second input of which is connected to the sensor 17 state of the subscriber. The sensor 17 can be made in the form of a contactor, which, when triggered, connects a unit level to the AND element.

 The device operates as follows.

 After turning on the supply voltage from the output of the generator 6 of the sinusoidal voltage through the communication line 1 to the subscriber points 8 to the power inputs 28 receives an alternating voltage. The power supply 26 converts it into a constant stabilized voltage, which is supplied to the functional units of the subscriber station 8 and brings them into working condition (wiring of the supply voltage is not shown). The counters 41 in the elements 16 of the delayed response in the subscriber points 8 are reset.

 To interrogate subscriber stations with the Start signal, the radio pulse generator 2 is started from the output of the control panel 4. The sequence of radio pulses through a band-pass filter 3 and through a communication line 1 is fed to inputs 11, 12 of the interference suppression unit 10 of each subscriber station 8. In this case, the subscriber station 8 works as follows. The interference suppression unit 10 passes a signal to an amplitude detector 30 through a broadband filter 29. The latter monitors the input signal in amplitude and, in the case of an interference signal with an amplitude exceeding the amplitude of the useful signal, attenuates it, and then passes the interrogation signal through a narrow-band filter 31 (Fig. .8, a, b).

 Next, the polling signal is fed to the converter 13 of the radio pulses into video pulses at the input of the radio frequency amplifier 32. The amplified radio pulses are detected and fed through the low-pass filter 34 to the input of the low-frequency amplifier 35 (Fig. 8, c). The amplified signal is input to the shaper 36 of the video pulses, which generates at the output a sequence of rectangular pulses supplied to the input of the selector 37 pulses in duration. The selector 37 once again controls the presence of an interference signal in the useful signal, selecting pulses by duration. As a result, at the output of the transducer 13 of the radio pulses into video pulses, a polling signal is generated in the form of a sequence of rectangular pulses (Fig. 8, d).

 The sequence of rectangular pulses from the output of the Converter 13 is supplied to the response delay element 16, to the polling signal identification unit 14 and to the subscriber polling time interval generator 15. In this case, the shaper 15 sets at the input 24 of the element 16 (the input of resetting the counter 41) a signal of permission to the account (Fig. 8, g). The polling signal identification block 14 generates strobe pulses from the decay of each rectangular pulse arriving at its input (Fig. 8, e). By means of the delay element 39 and the delay to the OR element 40, the resulting gating pulse (Fig. 8, e) is installed at the write permission 23 of the counter 41 of circuit 16 at the time when the middle of the pulse arriving at the counting input of the counter 41 coincides with its middle. This is carried out auto-synchronization of the counter 41 on the decline of each previous video pulse of the polling signal pulse. A signal shifted in time relative to the middle of the strobe is regarded as a hindrance and is not passed to counter 41. Counter 41 counts a certain number of video pulses corresponding to the response delay time of subscriber station 8, at which unit-level signals are set at all inputs of element And 42. As a result, an impulse is generated at the output And 42, which goes to the input 21 of the polling signal identification block 14 (the second input of the OR element 40), prohibits the passage of the block of gating pulses 14 and removes the write enable signal to the counter 41 pulses arriving at its counting input 18 (Fig. 8, i). At the same time, the same pulse from the output of the And 42 element is permissive for the message code generating unit 9. Block 9, upon a signal from the output of element And 42, in the presence of closed contacts of the sensor 17 (sensor 17 activated), generates a sequence of rectangular pulses, the number of which and the location correspond to the status code of the subscriber station 8 (Fig. 8, k), which are received at the second input of the element And 44 converters of video pulses into radio pulses, the first input of which receives a signal from the output of the carrier frequency generator 43. At the output of the And 44 element, a sequence of packs of video pulses with high-frequency filling is formed. Then the received signal amplifies the power 45, after which the signal already has the form of a sequence of radio pulses and through a band-pass filter 46 enters the communication line 1 (Fig. 8, l).

 On the receiving side, the signal containing the results of the survey is fed through a bandpass filter 5 to the control panel 4. In the example of the device, the control panel 4 is made on a computer, which allows you to fully automate the processes of polling subscriber devices and processing the results of the survey. For this, the received radio signal is converted into video pulses, which allows further processing of the signal in digital form. The interface unit provides interaction between a computer, a converter of radio pulses into video pulses and a generator of radio pulses.

Claims (8)

 1. A DEVICE FOR SIGNALING, containing a communication line, a control panel, a radio pulse generator, two bandpass filters, one of which is connected to the output of a radio pulse generator, in addition, the device contains N subscriber stations connected by inputs to the communication line, each of which contains subscriber status sensor connected to the input of the message code generating unit, characterized in that a sinusoidal voltage generator and a third bandpass filter connected in series are inserted, which is connected by an output It is connected to the communication line, to which, in addition, the power supply inputs of subscriber stations and the outputs of subscriber stations are connected, the output of the first bandpass filter and the input of the second bandpass filter, the output of which is connected to the input of the control panel, the output of which is connected to the "Start" input of the generator radio pulses, a power supply unit, the inputs of which are the power supply inputs of the subscriber unit, an interference suppression unit, the inputs of which are the inputs of the subscriber unit, a video pulse to radio converter are introduced into each subscriber station pulses, the outputs of which are the outputs of the subscriber station, a converter of radio pulses into video pulses, a polling signal identification block, a subscriber polling time interval shaper, and a response delay element, while the output of the interference suppression unit is connected to the input of the radio pulser into video pulses, the output of which is connected to the input of the interval shaper the polling time of the subscribers, to the first inputs of the response delay elements and the polling signal identification block, the second input of which and the output are connected respectively venno yield and second input response delay elements, the third input of which is connected to the output driver poll time interval, subscribers, and the output, in addition, connected to the second input message generating code block, whose output is connected to the input of inverter video pulses in radio pulses.  2. The device according to claim 1, characterized in that the response delay element comprises a pulse counter and a multi-input element And connected in series, while the counter's counting input, recording enable input and zeroing input are the first, second and third inputs of the circuit, respectively, and the output of the element And the output of the element.  3. The device according to claim 1, characterized in that the converter of radio pulses into video pulses contains a serially connected amplifier of radio pulses, the input of which is the input of the converter, an amplitude detector, a low-pass filter, a low-frequency amplifier, a driver of video pulses and a pulse selector in duration, the output of which is converter output.  4. The device according to claim 1, characterized in that the interference suppression unit contains a serially connected broadband filter, the input of which is the input of the interference suppression unit, an amplitude limiter and a narrow-band filter, the output of which is the output of the interference suppression unit.  5. The device according to claim 1, characterized in that the polling signal identification block comprises a fall pulse shaper, the input of which is the first input of the block, the delay element and the OR element, the second input of which is the second input of the block, and the output as the output of the identification block polling signal.  6. The device according to claim 1, characterized in that the converter of video pulses to radio pulses contains a carrier frequency generator, the output connected to the input of the element And, the second input of which is the input of the converter, and the output is connected to the input of the power amplifier connected by the output to the bandpass filter, outputs which are the outputs of the converter.  7. The device according to claim 1, characterized in that the control panel contains a converter of radio pulses into video pulses, the input of which is the input of the remote control, and the output through the interface unit is the input of the computer, the output of the interface unit is the output of the remote control.  8. The device according to claim 1, characterized in that the power supply contains a series-connected bandpass filter, the input of which is the input of the power supply, a rectifier, a rectifier filter and a voltage regulator, the output of which is the output of the power supply.

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