RU2226002C1 - Object device - Google Patents

Abstract

FIELD: object devices for monitoring and controlling terminal alarm and warning devices at object. SUBSTANCE: device is designed for two-way digital data exchange with message transfer systems through busy telephone communication lines. Object device can be adjusted to optimal modes of data reception and speed of data exchange with message transfer system for each actual telephone communication line. EFFECT: enhanced communication reliability. 1 cl, 1 dwg

Description

The invention relates to object devices, monitoring and controlling terminal devices for security and signaling at the object and performing two-way digital information exchange with notification transmission systems via busy telephone communication lines.

A device is known object system for the transmission of notifications "Cyclone" (TU 25-08.430-80, TU 25-08.431-80, TU25-08.432-80 "Security Equipment No. 1/94"), containing security lock loops, a block of switches, display units, a signal generator, a code lock, a power source, the disadvantage of which is the low reliability of the device associated with a large number of false alarms due to a decrease in the level of a continuous frequency signal of 18 kHz transmitted from the guarded object when the telephone line is degraded.

A device is known object system for the transmission of notifications “Comet - K” (II1.220.003.TU Security Technique No. 1/94), containing security lock cables, pulse-width signal block, display units, code lock, power source. The disadvantages of this scheme are the low simulation stability and reliability of information transmitted over the communication line.

The closest in technical essence to the proposed solution is an object device (RF Patent No. 21110094) containing a microcomputer, an address block, a level control unit, a matching unit with a communication line, a resonant amplifier block, a digital signal driver, a cipher number block, a reserve level block power supply, controlled divider, mains voltage supply block, mechanical lock control unit, group of security lock loops, switch block, code lock, the first group of microcomputer inputs connected to the group security lock loops, respectively, the second group of inputs - to the group of outputs of the switch block, the third group of inputs - to the group of outputs of the address block, the fourth group of inputs - to the group of outputs of the cipher number block, the group of inputs and outputs is connected to the code lock, the first group of outputs of the microcomputer is connected with an indication unit, the second group of outputs - with a group of inputs of the level control unit, the output of which is connected to the input of the matching unit, the input-output of which is connected to the communication line, and the output through the block of the resonant amplifier and a digital signal former is connected to the first input of the microcomputer, the second input of which is connected to the output of the power supply unit, the input of which is connected to the input of the power supply and the input of the backup power supply, the output of which is connected to the third input of the microcomputer through the backup power level unit, the third group of outputs which is connected by a controlled divider.

The known circuit device object (UO) works as follows.

After turning on the power to the UO, its microcomputer with built-in ROM and RAM executes the test diagnostics program and the initial settings program and sets the minimum information exchange rate on its internal serial transceiver, and the code for the minimum signal level on the level control unit. Information on the results of the test diagnostics is recorded in the status register of the RAM of the microcomputer for transmission to the notification transmission system. After that, the UO microcomputer includes a survey of the corresponding loops of the group of security interlock loopback loops (such as “Police Call”, “Fire” and the like), information about which is available in the UO microcomputer's memory. If during the survey there were violations of the integrity of any of these security lock loops, then at the next communication session with the notification transmission system, the UO sends alarm messages to it about the status of the broken alarm loops.

Communication UO with the notification system is carried out in the following way. The notification transmission system periodically polls the UO group on the corresponding telephone line, transmitting successive messages with the command “Issue Status” and the block number modulated by the carrier frequency. Serial transmission is received simultaneously at the input-output of each UO in this group and through the matching block with the communication line, which transformer matches the UO with the external communication line, through the block of the resonant amplifier that extracts a signal from the line with a given carrier frequency through the block of the digital signal shaper, where the low level modulated analog signal is amplified, filtered out from the interference signal, the generated digital signals of units and zeros of a given duration are detected and represent m a sequential sending, at the input of the microcomputer vivo. Having received the parcel with the command “Issue Status”, the microcomputer reads the address code from the address block and compares it with the received code of the number of the UO. If the code does not match, then it switches back to the reception mode from the external line. If it matches, then a parcel (response) is formed on the corresponding branch of the microcomputer program about the current state of the UO, which from the output of the microcomputer goes to the first input of the controlled divider, the second input of which receives the reference frequency from the microcomputer. In the controlled divider, the reference carrier frequency is obtained from the reference frequency by dividing, which, after addition to the sending signals from the microcomputer, through the level control unit, which generates the specified signal amplitude, is fed to the input-output of the notification system via the matching unit with the communication line and the communication line .

To set the UO under protection, it is necessary to go out the front door and close it, insert the key token into the code lock 4. Microcomputer 1 UO reads the key code, encrypts it, adds the necessary control bits and puts it into its RAM in the group of status registers. After the next polling of the status of the UO, the notification system sends the UO its status, as described above, and awaits a response at the next interrogation. At the next interrogation of the alarm system, having received the “arming” command from the communication system in the above-described way by the microcomputer 1, it starts periodic polling and monitoring of the status of the corresponding (status of “Security”) loops from the security lock loop group 3 and includes on the display unit 2, the “Security” indicator, and the “confirmation” indicator, which is structurally integrated into the code lock 4, displays signals of a given duration. Similar to the above, but with the polling of the corresponding security loops and the "Security" indicator turned off, the operation of disarming the object is performed. If during the protection in the UO there were violations of the integrity of any security lock loops, then at the next communication session with the notification system the UO sends alarm messages about the status of the corresponding security lock loops and receives a confirmation of the receipt of these messages.

The disadvantage of this UO is the low reliability of communication over communication lines, made structurally in a common cable and having a large attenuation of the carrier frequency signal at the end of the line. The automatic increase in the CI of the amplitude of the signals transmitted in such lines in order to increase the reliability of its reception at the end of the lines by the notification transmission system increases the level of interference caused by mutual interference from signals in neighboring communication lines, which leads to a decrease in the reliability of communication with object devices on these lines or to the termination of communication with MA in general.

In addition, there is a limitation by mandatory regulatory materials of the amplitude of the signal transmitted from the UO to a busy telephone line at 0.45V (+ 0.5V, -0.5V), which makes the operation of this UO unreliable with a notification system on telephone lines that have deviations in the parameters from the standard (including on long communication lines).

The aim of the invention is to increase the reliability of the communication device object.

This goal is achieved by the fact that in the object device containing a microcomputer, a block of indicators, a group of security lock loops, a code lock, a digital signal generation unit, and the output of a digital signal generation unit is connected to the first input of a microcomputer, the group of inputs of which is connected to a group of security lock loops , a group of inputs and outputs is connected to a code lock, and the first group of outputs of a microcomputer is connected to a block of indicators, an amplifier-transmitter, a block of dividers, a voltage limiter, a block of strip filter, amplifier-receiver, the first output of which is connected to the second input of the microcomputer, the second output is connected to the input of the digital signal generating unit, and the input is connected to the output of the divider unit, the group of inputs of which is connected to the second group of outputs of the microcomputer, and the input of the divider unit is connected to the output of the bandpass filter unit, the input of which is connected to the output of the voltage limiter, the input-output of which is connected to the communication line, and the input is connected to the output of the amplifier-transmitter, the input of which is connected to the output of the microcomputer.

The drawing shows a block diagram of a device object.

The object device contains a microcomputer 1, a block of indicators 2, a group of security lock loops 3, a code lock 4, a digital signal generating unit 5, an amplifier-transmitter 6, a voltage limiter 7, a band-pass filter 8, a divider block 9, an amplifier-receiver 10.

The object device (UO) works as follows.

After connecting the power to the UO, the microcomputer 1 with built-in ROM and RAM runs a test diagnostic program for the UO nodes. The results of how the test diagnostics passed normally or abnormally are displayed on the indicator block 2. When the diagnostics are completed normally, the microcomputer 1 executes the initial settings program for the UO circuits and sets the minimum information transfer rate on its internal serial port of the transceiver, which is the output of the microcomputer 1, and the divider unit (for example, resistive) 9 through the second group of outputs sets the number of the divider, providing minimal attenuation of the signals coming from the communication line through the voltage limiter 7, the bandpass filter unit 8, the divider unit 9 to the input of the amplifier-receiver unit 10, and then to the second input of the microcomputer 1. Information about the results of the test diagnostics is recorded in the status registers of the RAM of the microcomputer 1, and then through the output the microcomputer 1, the amplifier-transmitter 6, the voltage limiter 7 and the communication line transmits this information to the notification system for intended use. Information is exchanged between the UO and the notification transmission system (via the communication line) at the initiative of the notification transmission system by transmitting to the communication line a given group of pulses of the UO status interrogation signal. In order to ensure the operation of UO on busy dial-up communication lines, communication between the UO and the system for transmitting notifications over telephone lines is carried out in the suptonal frequency range by amplitude-manipulated signals. The speed of digital information transmission from the UO to the notification transmission system during the exchange is set by the notification transmission system and is selected from minimum to maximum, depending on the reliability of the two-way communication and the quality of the received information.

Communication UO with the notification system is carried out in the following way. The notification transmission system periodically polls the UO group on the corresponding telephone line, transmitting successive digital information packets with the "Issue Status" command and the UO number modulated by the carrier frequency. The reception of packets of interrogation signals and information from the notification system is carried out by the UO from the communication line through the input-output of the voltage limiter 7, which limits the amplitude of the incoming signals to the amplitude of a given level in order to avoid overloading the input signals of the bandpass filter unit 8. The bandpass filter unit 8 has high sensitivity and is designed to isolate and pre-amplify the carrier frequency signals received at its input, which are then fed to the input of the divider unit 9, built by the microcomputer 1 through the second group of outputs for transmitting a signal of maximum signal level. The signals from the block of dividers 9 are fed to the input of the amplifier-receiver 10. The amplifier-receiver 10 is designed as an amplifier with a constant gain and has a linear gain characteristic in a given range of input signals. Amplified by the amplifier-receiver 10, the signals from the first output of the last are fed to the second input of the microcomputer 1, which is an analog-to-digital signal converter. Microcomputer 1 converts each received analog signal into digital form, determines the level of its amplitude and waveform. If the signals of a certain amplitude and shape are repeated a predetermined number of times with a given period, then the microcomputer 1 defines this series of pulses as the carrier frequency of the useful signal and selects such an input voltage divider in the divider block 9 for the amplifier of the receiver 10 through the group of outputs 2 that will provide the amplitude of the carrier signals the frequencies from the output 2 of the amplifier-receiver 10 are sufficient for the digital signal generating unit 5 to form reliable series “1” and “0” of digital signals from them at the first input of microcomputer 1 s received information packet. Microcomputer 1, having received a series of digital signals from the first input, combines them into a packet and checks its format and the reliability of the received information.

If the received information is determined by the microcomputer 1 as reliable, then the microcomputer 1 sends a message packet about this to the information transmission system (as described above) and processes the correspondingly received information. If the received information is false, then the packet of the received information is ignored, which is also reported by the message transmission system.

Messages and information intended for transmission from the UO to the notification system are formed by the microcomputer 1 UO in the form of a packet of digital information of a given format, dimension and protection methods. Next, the microcomputer 1 through its first output outputs each bit “1” of a digital information packet in the form of a pack of units of a natal carrier frequency and a packet duration equal to the minimum information transfer rate, and each bit “0” of a digital packet in the form of a packet of zeros of similar duration. These packs of digital “1” and “0” through the amplifier-transmitter 6, which generates signals of a given amplitude from them, through the voltage limiter 7, which matches the load of the amplifier-transmitter 6 with the communication line, are fed through the communication line to the processing system . If during a given time interval the quality of information exchange with UO at the existing exchange rate is determined by the notification transmission system as normal, then it gives the UO command to switch to a higher information exchange rate, and so on, to the maximum possible information transfer rate on each telephone line, respectively .

If during a given time interval the quality of information exchange with UO at an existing exchange rate on a given telephone line is determined by the notification transmission system to be unsatisfactory, then it gives the UO command to switch to a lower information exchange rate, and so on, to the lowest possible information transfer rate, until the normal quality of information exchange with UO on each telephone line of communication, respectively, is established.

To install the UO under protection, it is necessary, going out the front door and closing it, insert the key-token into the code lock. Microcomputer 1 UO reads the key code, encrypts it, adds the necessary control bits and places it in its RAM in the group of status registers. After the next polling of the status of the UO, the notification system sends the UO its status, as described above, and awaits a response at the next interrogation. During the next interrogation of the alarm system, having received from the communication line in the manner described above, from the notification transmission system, the command for arming by means of the microcomputer 1, it starts periodic interrogation and monitoring of the status of the security lock loops corresponding to the “Security” state and turns on the “Security” indicator on the indicator block 2 , and the “Confirmations” indicator, which is built constructively in the code lock 4, displays signals of a given duration, indicating that the object has been taken under protection. Similar to the above, but with the polling of the corresponding security loops and the "Security" indicator turned off, the operation of disarming the object is performed. If during security in the MA there were violations of the integrity of any security lock loops, then at the next communication session with the notification system, the MA will send alarm messages to it about the status of the corresponding security lock loops and will receive a confirmation of the receipt of these messages.

The above-described UO scheme with hardware-based control of the level of the incoming signal, performed on the basis of the results of programmatic logic control of the reliability of the received data, allows one to fine-tune it to receive useful signals from a noisy or long communication line having a large attenuation coefficient of the useful signal. Such a technical solution provides reliable communication of the UO with the notification transmission system.

Claims (1)

An object device containing a microcomputer, an indicator block, a group of security lock loops, a code lock, a digital signal generation unit, the output of a digital signal generating unit being connected to the first input of a microcomputer, the input group of which is connected to a group of security lock loops, the group of inputs and outputs is connected to a code lock, and the first group of outputs of the microcomputer is connected to a block of indicators, characterized in that an amplifier-transmitter, a block of dividers, a voltage limiter, a bandpass filter block, an amplifier are introduced an receiver-receiver, the first output of which is connected to the second input of the microcomputer, the second output is connected to the input of the digital signal generating unit, and the input is connected to the output of the divider block, the input group of which is connected to the second group of microcomputer outputs, and the input of the divider block is connected to the output of the strip unit filter, the input of which is connected to the output of the voltage limiter, the input-output of which is connected to the communication line, and the input is connected to the output of the amplifier-transmitter, the input of which is connected to the output of the microcomputer.

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