RU74232U1 - RADIO TRANSMISSION SYSTEM - Google Patents

Abstract

The utility model is intended for centralized radio surveillance of real estate, citizens' apartments, offices, warehouses, garages, etc., and for fire monitoring in the Ministry of Emergencies. The radio transmission system of notifications is organized by combining in a single radio system a synchronous-address type system with a two-way communication channel with subsystems of concentrators of notifications of asynchronous-address type with a one-way communication channel. Moreover, any of the object blocks of the synchronous-address radio system with a two-way communication channel is configured to assign it the status of a “repeater”, or the status of “working through a relay”. The radio transmission system of notifications has improved indicators for the reliability and speed of delivery of alarm notifications, as well as for unloading channels. 1 C.p.F., 1 ill.

Description

The utility model relates to wireless radio systems for transmitting notifications and can be used for centralized radio security of real estate, citizens' apartments, offices, warehouses, garages, etc., and for fire monitoring in units of the Ministry of Emergencies.

Known radio transmission systems for alarm notifications containing a central monitoring station (station) and sensors installed at security objects connected through object terminals and communication channels with the monitoring station. Conventionally, radio security systems (types of equipment) from the point of view of organizing the transmission of any messages from a guarded object to a monitoring station can be divided into several classes - asynchronous-address with a one-way communication channel (from a controlled object (KO) to a monitoring station), asynchronous-address with a two-way communication channel (from the CO to the monitoring station and vice versa), synchronously-addressable with a one-way communication channel (from the CO to the monitoring station at a certain point in time), and synchronously-addressable with a two-way communication channel (from the monitoring station to the monitoring station and back to the monitoring station).

The asynchronous type of systems with a one-way channel includes such equipment in which the moment of formation and transmission of the next message is not known at the protected facility and, as a rule, at the monitoring station. The transmission of a certain message from the protected object occurs both after the occurrence of the event causing the subsequent transmission, and in the case of transmission of the so-called test signals from the QoS, the time interval (control) between which can vary widely and depends on the purpose of the system,

the number of QoS, the duration of the transmitted message and the number of frequency channels for transmitting the message. The monitoring interval is known at the monitoring station; therefore, the reception of a test signal at the monitoring station for the period of the monitoring interval indicates the normal operability of the facility equipment and the communication channel.

Asynchronous address systems with a one-way communication channel include, for example, the ROSA alarm system described in patents RU 94027477, G08C 13/00, 05.20.1996 and RU 2069055, G08C 13/00, 11.10.1996. However, it has disadvantages associated with the contradiction between the duration of the control interval and the number of QoS. If, during an unauthorized intrusion, it was possible to immediately disable the transmitting device (that is, before transmitting the alarm notification), then the alarm signal to the monitoring station can only be the absence of a test signal with CO, which requires the maximum reduction in the duration of the monitoring interval. An increase in the number of test signals with QoS in order to reduce the duration of the control interval, as well as an increase in the number of QoSs, leads to the appearance in the receiving path of the monitoring station of a large number of overlays of test signals from all operating in the QoS system, which can cause a skipping the signal, as well as the loss of a real alarm notification from a separate object, to exclude a similar situation, an alarm notification is repeated several times after a certain time interval. At the same time, the delivery time for an alarm notification increases unpredictably.

Asynchronous-address systems with a two-way channel that implements a method of complex protection of objects, for example, according to patent RU 2159190, В60R 25/00, 20.11.2000, differ from asynchronous-address systems with a one-way communication channel in that the KO equipment receives acknowledgment of reception from the monitoring station alarming notices that

It is at the same time a team for stopping the transmission of an alarm notification and that, in general, increases the reliability of delivery of an alarm notification due to its possible duplication in the absence of confirmation of the fact of receiving a monitoring station. However, the disadvantage is the uncertainty in the delivery time of the alarm message, characteristic of asynchronous systems, associated with the possible superposition of test signals and alarms in the receiving path of the monitoring station.

For synchronous-address systems with a one-way communication channel at each guarded object, the moment of formation and transmission of the next message is predetermined. And at the monitoring station, with a certain degree of certainty, it is possible to predict the moments of reception of the next messages from each of the protected objects due to the clearly known sequence of their arrival. The number of test messages transmitted to the monitoring station from each CO for such equipment of the radio communication system is a sufficient amount (usually from 15 to 30 per hour). Such equipment is described, for example, in US patents No. 6188715, H04L 27/26; US No. 6700920, H04B 01/713; US No. 6870875, H04B 01/69. Its disadvantage: the speed of transmitting alarm notifications is very low (the time interval from the sensor’s triggering to the corresponding alarm message can be several minutes), the reason is the presence of the sequence of transmissions from the CO.

Closest to the claimed utility model is a synchronous-address system with a two-way channel for transmitting information (the radio-channel alarm system "ROS-1M"), which implements a method for monitoring and signaling about the state change of protected objects according to patent RU 2183352, G08B 26/00, 10/06/2002 (prototype). This two-way notification radio system

contains a central monitoring station (CMS) and object blocks (OB) associated with the monitoring station via a radio channel, configured to exchange information between the monitoring station and the control station on a carrier frequency continuously in the form of a cyclic stream of information packets, each information packet is designed to exchange information with a given the number of OBs and consists of individual (control) requests of the monitoring station to the OB and responses from the OB, and the OB is configured to transmit responses to the monitoring station only after receiving a request from the monitoring station, and the repetition period information packets is a multiple of the sum of the values of the time intervals of a request to one OB and receiving a response from one OB, and the monitoring station is able to process them after receiving responses from the OB, and when monitoring communication lines between the monitoring station and the OB if there is a repeated absence of a response from the OB to the monitoring station record a violation of the communication line. The radio system provides control of the equipment of protected objects due to their constant cyclic interrogation. The functioning of the system is based on the fact that the exchange between the monitoring station and the OB is carried out by alternately polling the OB in the form of a request sent by the local station containing the monitoring station to the OB and the responses generated by the OB, with their subsequent transfer to the monitoring station. The polling period of all OBs is a multiple of the sum of the time intervals for sending a request to one OB and receiving a response from one OB. The request is formed from a confirmation signal for receiving responses from any of the OBs polled by the local station and a polling signal sent simultaneously to the OB. The exchange in the form of a cyclic stream of information packets consisting of a monitoring station request and OB responses separated by a time interval characteristic of synchronous-address systems with a two-way communication channel eliminates the overlap of response signals in the receiving station path, and makes it possible to obtain

information on the operational situation on the OB at any time at the request of the requesting authority, monitors the transition of technical equipment to autonomous power, as well as the breakdown or failure of the transceiver antenna. The system is capable of operating at a single frequency, but in the case of active interference, it can switch to a spare frequency within a predetermined frequency channel, and a message about the jamming will appear at the system operator.

The disadvantage of the system, provided that the number of OBs is increased to several thousand, which is typical for centralized security, is the delay in the delivery of alarm messages from the OBs to the monitoring station up to several minutes, the reason is the tight cyclic polling algorithm that eliminates mutual overlapping of signals, as a result of which the transmission of an alarm message can to be realized only in the time interval allocated for a particular object device. The direct possible reduction in the time of delivery of an alarm message to the monitoring station can be associated with a decrease in the polling cycle due to, for example, an increase in the OB polling rate, however this is associated either with the expansion of the energy spectrum of the information signal, which requires the allocation of an additional frequency resource, or with a sharp decrease in the operating range radio systems, which in practice when building large centralized radio systems is unacceptable.

Especially the problem of the speed of transmitting alarm notices is exacerbated by the use of repeaters in large centralized security systems, which are necessary to expand the coverage area of systems. A fairly large number of patents (RU 2182088, B60R 25/00, 2002.05.10; RU 2198800, G08B 13/00, 2003.02.20; RU 2201363 B60R 25/10, 2003.03.27; RU 2231458 B60R 25/00, 2004.06.27 ) are used as part of

radio systems with a one-way communication channel, repeaters for receiving code messages from KO terminal devices, selecting them according to the “friend or foe” principle and relaying signals to the nearest base station or a nearby repeater. With an increase in the number of COs per one repeater, the problem of loss of alarm notification and the speed of transmitting alarm notifications to the monitoring station is aggravated by the presence of a large flow of test, event (for example, arming / disarming) notifications in the communication channel of the relay - monitoring station.

The task of creating a utility model is to increase the reliability of the transmission of alarm notifications and reduce the time of their delivery to the monitoring station in the notification transmission systems of significant capacity when building centralized radio security systems or fire monitoring radio systems, as well as reducing the load on the communication channel.

The task is achieved by the fact that in a radio transmission system of notifications containing a centralized monitoring station (CMS) and object blocks (OB) connected to the monitoring station via a radio channel, made with the possibility of exchanging information between the monitoring station and the OB on a carrier frequency constantly in the form of a cyclic stream of information packets moreover, each information package is designed to exchange information with a given number of OBs and consists of individual (control) requests from the monitoring station to OBs and responses from OBs, and OBs are configured to giving answers to the monitoring station only after receiving a request from the monitoring station, and the repetition period of information packets is a multiple of the sum of the time intervals of the request to one OB and receiving a response from one OB, and the monitoring station is able to process them after receiving answers from the OB, and when monitoring the lines communication between the monitoring station and OB in the presence of a repeated lack of response

from OB to the monitoring station to record a violation of the communication line, according to the claimed technical solution, the monitoring station is configured to transmit group requests from the monitoring station to the OB and alternate them with individual requests to the OB and to transmit information confirming the OB from the monitoring station in the group request to the OB before A notification sent to the OB, and all OBs are configured to immediately transmit responses to the monitoring station's group request to the OB regardless of the time of the last response to the individual monitoring station's request, provided an event or alarm information (alarm notification) having the status of immediate transmission to the monitoring station, as well as with the ability to store notifications and retransmit alarm alerts until the moment when, as part of a group request, it receives confirmation from the monitoring station of the monitoring station that it received the alarm notification in this case, asynchronously-addressed OB subsystems with a one-way communication channel are introduced into the radio system, each of which is formed by a notification concentrator and OB with a one-way communication channel included in the address field of the concentrator alarms configured to receive notifications on the carrier frequency of the asynchronous address subsystem from the OB with a one-way communication channel, to monitor the frequency of receipt of test signals from the OB with a one-way communication channel and to immediately transmit to the monitoring station from the OB an asynchronous address subsystem with a one-way communication channel to any group request to the concentrators of event-only notifications (alarm, arming / disarming) and messages about the loss of control over the communication channel between the notification concentrator and OB async on-address subsystem on the carrier frequency of a two-way synchronous-address system, while the monitoring station is configured to transmit and alternate individual, group to OB

and group requests to concentrators, and the possibility of transmitting information in the group request to concentrators of confirmation information to concentrators on receipt of monitoring station messages from concentrators, and the concentrator is configured to store notifications and retransmit notification messages until, as part of the next group request from monitoring station to concentrators, the concentrator will not receive confirmation of the reception by the monitoring station of the notification transmitted to them.

Any of the OBs of a synchronous-address radio system with a two-way communication channel can be configured to assign them the status of “repeater” or the status of “working through a repeater”, while OBs with the status of “relay” are made with the possibility of interaction with the monitoring station and receiving signals from OB with the status “operating through a relay”, notifications from which, when transmitted, cannot independently reach the receiving station of the monitoring station, but are capable of receiving signals from the monitoring station, while OBs with the status of “relay” are configured to receiving, storing and retransmitting OB notifications having the status “operating through the relay” until the receipt of a confirmation from the monitoring station as part of a group request to receive an alarm notification from the OBs having the status “working through the relay” and OB with the status “ working through a relay ”, is configured to store and retransmit notifications until a confirmation is received from the monitoring station from the monitoring station as part of the group monitoring station receipt of the notification.

The essence of the utility model is illustrated by the drawing, which shows a diagram of the construction of the proposed radio system for transmitting notifications, explaining the principle of its operation.

The radio system contains: the main synchronous system 1 OB with a two-way communication channel, which includes the monitoring station 2, N OB (figure 1

for example, two OB-3, 4) M concentrators are shown, interacting with the monitoring station 2 as with the main system 1, each of which in its subsystem 5 can track up to N1 OB with a one-way communication channel and at the same time perform the function of guarding the object on which it is located (figure 1 shows one hub - 6); M subsystems 5 OB with a one-way communication channel (the asynchronous subsystem 5 in the drawing includes a hub 6, OB 7, 8); To subsystems 9 of repeaters receiving signals from N2 OB with the status of working through a repeater (in FIG. 1, OB 4 has the status of a repeater, and OB 10 operates through a repeater).

The monitoring station 2 of a synchronous-address system with a two-way communication channel, as a rule, contains: an antenna-feeder path, including an antenna with a circular radiation pattern and a low-loss reduction feeder, a personal computer, a simplex-type transceiver unit connected via an additional interface device (control unit radio station) to a personal computer, with specialized operator software installed on it, a backup power source for the computer, transceiver and control unit p diostantsiey. As a transceiver unit, they can be used as mass-produced mobile radio stations of a given frequency range such as “Motorola”, “Kenwood”, “Icom”, etc., having external inputs for controlling channel switching, transmitting, modulation input, receiver output, etc. .d., and transceivers adapted for use in the monitoring station.

The interface device interfaces the computer ports, such as RS232 or USB, with the inputs of the transceiver and

transmission of control signals, data signals from the computer to the transceiver.

OB 3, 4 of a synchronous-address system with a two-way communication channel can include: an antenna, uninterruptible power supply, a simplex transceiver connected to a microcontroller with built-in memory, which controls the transceiver, displays operating modes of the OB, analyzes the status of alarm signal loops and controls external alerts. All OB 3, 4 are made with the ability to monitor the status of sensors connected to the loops, for example, a short circuit, a break in the loop, an alarm on the loop or the status "normal". Sensors of any type can be used, for example, detecting a change in state, smoke, temperature changes, gas contamination, increased background radiation, increased water levels, etc.

The composition of concentrators (for example, in Fig. 1, concentrator 6) differs from the composition of OB 3, 4 only in the presence of an additional receiver in it, which receives OB 7, 8 signals with a one-way communication channel. As the receiver can be used commercially available wearable radio stations such as "Motorola", "Kenwood", "Icom", etc., as well as any radio receivers made according to well-known schemes, with specified frequency ranges and types of modulation, providing the required reception quality . All concentrators are made with the possibility of working as security object equipment at KO.

OB 7, 8 of the asynchronous-address subsystem 5 with a one-way communication channel have a composition similar to OB 3, 4 with a two-way communication channel, except for transceivers, instead of which in OB 7, 8

introduced transmitters that transmit signals only in one direction, from, for example, about 7, 8 to the hub 6.

The radio notification system operates as follows. The monitoring station 2 at a known carrier frequency carries out a continuous cyclic interrogation of all OBs and concentrators of the main system 1 with a two-way communication channel. The survey is conducted by the monitoring station 2, broadcasting individual, group, and group queries to the concentrators one by one, the poll cycle is proportional to the number of OB N and concentrators M included in the main system 1, known to the monitoring station 2, and the period of the polling cycle, and therefore from N OB and M concentrators, defined as the sum of the time intervals of an individual request and the time to receive a response to an individual request of monitoring station 2, multiplied by (N + M) (the number of OBs and concentrators of the main system 1), plus the time spent CN 2 for group requests to N ON and answers from them, and multicasting to hubs and answers from them. For each individual request from the monitoring station 2 (Fig. 1), for example, to OB 3, the OB 3 generates a response, and the response of the OB 3 transmits only at a set time interval, immediately after receiving a request from the monitoring station 2, to the monitoring station 2 after receiving responses from ABOUT 3 process them, and when monitoring the communication line between the monitoring station 2 and OB 3 or, between any of the N OB or M concentrators, in the absence of a response from any of the N OB or M concentrator over the monitoring interval, a violation of the communication line is detected. The individual responses of the OB or concentrators (notification is the norm) contain current information about the status of sensors installed at the security facilities, the presence of the mains supply, the battery voltage of the backup power supply, etc.

In the event of occurrence of event information on any of the N OB or M concentrators having the status of immediate transmission of a notification to the monitoring station (alarm notification, notification of arming, disarming), in the time interval allotted for replies to a group request, an alarm notification, for example, figure 1 from OB 3 or hub 6, is immediately transmitted to the monitoring station 2, where after it is received in the next group request to monitoring station 2, confirmation information is received on the monitoring station 2 alarm notification from OB 3 or hub 6. AB 3 or hub 6, after P radiation in the group information request confirmation of reception station 2 alarm signal from ON concentrator 3 or 6, deletes (erases) an alarm received station 2 in the previous session exchange, from its memory, completing thus the alarm signal transmission procedure. In case if for some reason (for example, impulse noise) the monitoring station 2 did not receive an alarm notification from OB 3 or hub 6, and therefore did not erase the notification in the memory of OB 3 or hub 6, then for each subsequent group request of the monitoring station 2 ABOUT 3 or hub 6 will continue to transmit an alarm notification until it receives confirmation of its receipt.

This ensures high reliability of the transmission of alarm notifications, as well as an additional positive effect - the absence of missed alarm notifications in the event of a short interruption in the monitoring station operation, an alarm notification, after, for example, a failure and restart of the monitoring station, with a delay, but will be received.

If the alarm notification is transmitted simultaneously from two or more OBs or concentrators, for example, in FIG. 1 with OB 3, OB 4, then after a group request in the time interval allotted for replies to

a group request, monitoring station 2 will receive two messages simultaneously, from OB 3 and OB 4, but will receive, in accordance with the effect of suppressing a weak signal strong in the receiving path of Station 2, only the signal with the highest level, for example from OB 4. The notification from OB 4 is processed , in a subsequent group request to monitoring station 2, its reception is confirmed. Since the OB 3 signal during the previous exchange session was suppressed in the receiving path of the monitoring station 2 and the 3 did not receive confirmation from the monitoring station 2 about receiving its notification, the transmission from the OB 3 is repeated to the group request, which confirms the reception from the 4, as a result, the monitoring station receives the previously suppressed notification from OB 3. The situation is repeated, a confirmation of receipt is issued in the group request of the monitoring station 2, erasing the received notification from the memory of OB 3, etc. until all event notifications are completely removed and erased in the memory of all OBs or concentrators of system 1, even if there are more than two of them considered earlier.

Simultaneously with the operation of the main system 1, reception, processing of notifications in M asynchronous-address subsystems 5 with a one-way communication channel is carried out. In this case, the hub 6 of one of the M asynchronous-address subsystems is included in both subsystems 1 and 5, performs the OB function in system 1, and in subsystem 5 it plays the role of the N1 OB concentrator with a one-way communication channel. The hub's task in the subsystem is to receive test signals from N1 OB of subsystem 5, which are essentially transmitters of notifications, monitor the frequency of receipt of test signals from them, and then transmit to Station 2 in the format of a synchronous address system with a two-way communication channel only event notifications nature (alarm, arming / disarming) and messages about the loss of control over the OB subsystem 5. In normal mode, when there are no events

notifications from OB about concentrator 6, for example about OB 7, OB 8 of subsystem 5, from OB 7, OB 8 with a given frequency, test signals are emitted on the air at one or several carrier frequencies (notification is normal). The emission period of the test signals for each N1 OB subsystem 5 is individual, when at least one test signal arrives from any of the N1 OB subsystems 5 for the monitoring time known to hub 6, hub 6 decides that the communication channel of OB 5 of the subsystem 5 is a hub, as well as all OBs of subsystem 5 are operational, while hub 6 does not relay any test signals of OBsystem 5, Station 2 does not reflect any alarm notifications to station 2. In case of occurrence of event notifications on the OB subsystem 5, for example, arming occurred on OB 7, OB 7 will immediately transmit a notification, the hub 6 will receive it, restore the signal from the signal-to-noise mixture, sort the received notification and immediately, in synchronous format the address radio system of subsystem 1 with a two-way communication channel on another carrier frequency, according to a group request to the concentrators, will transmit it to the monitoring station 2. Station 2 in the next group request to the concentrators will erase the notification about Regarding the hub 7 in the memory 6, completing, transmission procedure at Station 2 notice from 7 ON.

If, according to a group request to the concentrators, the monitoring station 2 receives two messages synchronously, from two concentrators of different subsystems 5 asynchronous objects (alarm events occurred on OBs belonging to the address spaces of different concentrators), for example, from concentrator M and concentrator M-1, then it will accept monitoring station 2 , in accordance with the effect of suppressing a weak signal strong in the receiving path of monitoring station 2, only the signal from one of the concentrators with the highest level, for example, concentrator M. Subsequently

a group request to the concentrators of the monitoring station 2 confirms the reception from the concentrator M and receives the notification, suppressed earlier, from the concentrator M-1. Then the situation is repeated, in the group request of the monitoring station 2, a confirmation is received about the receipt, erasure of the received notification from the memory of the M-1 hub, etc.

A feature of the operation of subsystem 9 is the installation of OBs operating through the repeater so that the OBs must independently receive signals from the monitoring station, the OB signals do not reach the monitoring station. In normal mode, when operating in subsystem 9, the OB 10 has the status of working through the repeater after receiving of an individual request, the monitoring station 2 broadcasts the “norm” notification. The OB 10 signal only reaches the OB 4 receiving path, which has the status of a repeater, and the OB 10 notification is recorded in the OB 4 memory. For any group request, the monitoring station 2 OB 4 having the status of the repeater transmits a “normal” OB 10 notification. In the next group request The monitoring station 2 deletes the notification from the memory of the OB 10, at the same time the acknowledgment signal about the reception of the monitoring station 2 of the notification from the OB 10 receives the OB 4, which has the status of a relay, which, like the OB 10, deletes the notification from its memory. If there are several event notifications on the OB 10, the transmission cycle (a group monitoring station message - sending a notification from the OB 10 - receiving a notification from the OB 10 by the OB relay 4-group monitoring station - sending the message of the OB 10 relay OB 4 - receiving the OB 10 message - erasing the notification from the memory of OB 10 and simultaneously from the memory of OB 4) it is repeated until the memory of OB 10 is completely cleared.

The proposed structure and algorithm of the radio system allows a flexible approach to its practical construction: from the moment the system is launched, a phased implementation is possible

deployment of the system, supplementing it as needed by concentrators. From the point of view of the development of the system and its operation in various conditions, it is possible to build systems from a small capacity (several hundred OBs, which is typical for small rural settlements), to the deployment of large capacity systems (several thousand OBs), for example, for cities with a million people . The combination of a synchronous-address system with a two-way communication channel and asynchronous-address subsystems with a one-way communication channel gives an advantage in the flexibility of satisfying the requests of a wide range of potential users of the radio system and in pricing policy. The proposed structure of the radio transmission system of notifications also allows the selection of the type of device used at a controlled facility. It is known that devices with a one-way communication channel are simpler and therefore cheaper than devices with two-way communication.

The positive effect in the proposed utility model is based on a combination of physical principles of the interaction of radio signals on the nonlinearity of the receiving path of the radio receivers with the algorithm of the synchronous-address system. The allocation of group to OB and group requests to the concentrator in the monitoring station monitoring cycle, sorting of notifications when OB replies by importance level and the mechanism of suppressing a weak signal by strong signals in the receiving station of the monitoring station eliminates the order in receiving alarm notifications, thereby increasing the speed of their delivery, increasing the reliability of receiving alarm notifications in an interference environment. The redistribution of powers from the monitoring station to the concentrators to make a decision about the loss of control over the communication channel in asynchronous address subsystems and at the same time the rejection of the classical relay scheme of all notifications frees the channel

communication between the monitoring station and the OB from excessive notifications, allows you to use the time resource released in the monitoring cycle of the monitoring station to quickly work out alarm notifications by group requests without increasing the monitoring time of equipment with a two-way communication channel.

The interaction algorithm between the monitoring station and the concentrators allows the introduction of asynchronous-address subsystems in the synchronous-address system, significantly increasing the capacity of the radio system cheaper, compared with devices for a two-way communication channel, object devices, while minimizing the time of delivery of alarm notifications and the monitoring time of the communication channel in asynchronous-address subsystems due to the optimal choice between the number of OBs per one hub, the duration of transmitted t ON messages and the number of possible frequency channels for transmitting and produce optimal zoning in frequency planning asynchronously-targeted subsystems, by reusing the same nominal carrier frequency in different areas.

The efficiency of transmitting alarm OB notifications whose signals cannot reach the monitoring station on their own is based on replacing the principle of traditional relaying, which consists in receiving a signal on one carrier frequency and simultaneously transmitting it on another carrier, with a procedure for temporarily storing relayed information in an intermediate link, the role of which can perform any of the OBs with a two-way communication channel, until its further transmission in the protocol of the synchronous-address system, and we confirm the fact of reception by relay information of the monitoring station, additional

useful effect - a second carrier frequency is not required for relaying notifications.

The proposed Irtysh-3R notification transmission system with an address capacity of 4,000 objects was tested by the OVO subdivisions at the Department of Internal Affairs of Omsk. The pilot operation of the radio system showed that the delivery time of alarm notices does not exceed several seconds.

Claims (2)

1. A radio transmission system of notifications containing a central monitoring station (CMS) and object blocks (OB) connected to the monitoring station via a radio channel, configured to exchange information between the monitoring station and the OB on a carrier frequency continuously in the form of a cyclic stream of information packets, each information packet it is designed to exchange information with a given number of OBs and consists of individual (control) requests from the monitoring station to the OB and responses from the OB, and the OB is configured to transmit responses to the monitoring station only after receiving I request from the monitoring station, and the period of repetition of information packets is a multiple of the sum of the values of the time intervals of the request to one OB and receiving a response from one OB, and the monitoring station is configured to process them after receiving responses from the OB, and when monitoring communication lines between the monitoring station and the OB when there is a repeated absence of a response from the OB to the monitoring station to record a violation of the communication line, characterized in that the monitoring station is configured to transmit group requests from the monitoring station to the OB and alternate them with individual requests to the OB and the possibility of transmitting to groups om request to the OB of information confirming the OB from the monitoring station about receiving a previously transmitted OB notification, and all OBs were made with the possibility of immediately transmitting responses to the group request of the monitoring station to the OB regardless of the time of the last response to the individual request of the monitoring station, provided the event or alarm information appears on the OB (alarm notification), having the status of immediate transmission to the monitoring station, as well as with the ability to store notifications and repeat the transmission of alarm notifications until the moment when, as part of a group request from the monitoring station, It receives confirmation that the monitoring station has received an alarm notification transmitted to it, while asynchronous address subsystems OB with a one-way communication channel are introduced into the radio system, each of which is formed by a notification concentrator and OB with a one-way communication channel included in the address field of the notification concentrator configured to receive notifications on the carrier frequency of the asynchronous address subsystem from the OB with a one-way communication channel, monitoring the frequency of receipt of test signals from the OB with a one-way communication channel and immediately of transmitting to the monitoring station from the OB of the asynchronous address subsystem with a one-way communication channel to any group request to the hubs only event notifications (alarm, arming / disarming) and messages about the loss of control over the communication channel between the message concentrator and the OB of the asynchronous address subsystem on the carrier frequency of a two-way synchronous-address system, while the monitoring station is configured to transmit and alternate individual, group to OB and group to request concentrators, and the ability to transmit a group request to the concentrators of information-confirmation to the concentrators about receiving the monitoring station messages from the concentrators, and the concentrator is configured to store notifications and retransmitting the notifications until the time when the next group request from the monitoring station to the concentrators receives the confirmation of the reception of the monitoring station transmitted to them notifications. 2. The radio transmission system of notifications with a two-way communication channel according to claim 1, characterized in that any of the OBs of a synchronous-address radio system with a two-way communication channel is configured to assign them the status of a “relay” or the status of “operating through a relay directly from the monitoring station”, when On this, OBs with the status of “repeater” are configured to interact with the monitoring station and receive signals from the OBs with the status of “working through the repeater”, notifications from which, when transmitted, cannot independently reach the receiving path The monitoring station, but capable of receiving signals from the monitoring station, while OBs with the status of “repeater” are configured to receive, store, and retransmit OB notifications that have the status “working through the relay” until a confirmation is received from the monitoring station about receiving the monitoring station as part of a group request alarm notification from OBs having a status of “working through a relay”, and OBs with a status of “working through a relay” is configured to store and retransmit notifications until a monitoring station is confirmed as part of a group request I'm from the monitoring station of receiving the notice.