JPH05161184A - Remote monitor system - Google Patents

Abstract

PURPOSE:To perform quick and correct monitoring at the time of occurrence of abnormality with higher priority by selecting a monitoring channel from the priority of abnormal data. CONSTITUTION:A CPU 3 receives abnormal data via an adapter 5. Based on the address and subaddress of a transmission source slave station, corresponding priority data are obtained from a prescribed table 200. Then when TV monitors M1 and M2 are being used, priority is taken out from a table 300 and compared. When received abnormality data has high priority, the CPU 3 controls the adapter 5, closes a monitoring channel having low priority and secures applicable B channel, and an adapter 7 of the slave station couples an applicable TV camera and the B channel. The image data of the applicable TV camera is supplied to applicable TV monitoring device via the adapter 5 of a master station 1 and the image of an object of monitoring is displayed. The CPU 3 rewrites the contents of a table 3 to the current condition.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote monitoring system such as a security system.

[0002]

2. Description of the Related Art An example of a conventional security system is shown in FIG. In this system, monitoring points A, B,
..., various sensors 51 _A , 51 _B for abnormality detection with respect to C,
..., 51 _C is provided, and the corresponding slave stations 52 _A , 52 _B , ..., 52
Connected to _C. Slave stations 52 _A , 52 _B , ..., 52 _C and parent station
Each of them and 53 is always connected by a channel for transmitting abnormal data. Moreover, each slave station 52 _A , 52 _B , ..., 52
_At the monitoring points A, B, and C of C, a TV camera 5
6 _A , 56 _B , ..., 56 _C are provided, and the image data is transmitted to the slave station 52.
Have been sent to. Monitoring channels 55 _A , 55 _B , ..., 55 _C are connected between the slave stations 52 _A , 52 _B , ..., 52 _C and the master station 53, but the master station 53 has monitoring channels 55 _A , 55 _A , 55 _B , ..., 55
One channel of _C is selected as follows. That is, in the conventional security system, when an abnormality occurs in the slave station, the monitoring channels are switched by the image data in the order of occurrence. Therefore, the master station 53 is provided with the image data of one of the monitoring points, and only monitoring is possible.

[0003]

However, according to the above method, even if a more serious abnormality occurs, if the monitoring channel is blocked, there is a problem that the image data cannot be monitored. For example, even if a small amount of water leakage is detected at point B and then a large amount of gas leakage is detected at point C while monitoring point A, you must first monitor point B. For example, there is a problem in that it is impossible to monitor the point C, so that it is not possible to sufficiently monitor a more serious abnormality that occurs later.

The present invention has been made in order to solve the above-mentioned problems of the conventional remote monitoring system, and its purpose is to generate a more serious problem even if the number of monitoring channels for image data is limited. It is an object of the present invention to provide a remote monitoring system capable of sufficiently monitoring an abnormality.

[0005]

According to the present invention, a plurality of slave stations and one master station transmit a fault data indicating that a fault is detected from the slave station to the master station, and a first channel. The image data is transmitted from a number of monitoring points which are less than the number of monitoring points which are channels for transmitting image data and at the same time abnormal data are collected by the first channel.
A remote monitoring system in which a channel for collecting data is connected to a usable second channel, priority detection means for detecting a monitoring priority for abnormal data sent from the slave station,

Based on the priority detected by the priority detecting means, a distant monitoring system is provided with a monitoring channel selecting means for selecting the second channel corresponding to the abnormal data and executing the monitoring by the image data. Configured.

[0007]

According to the above construction, when abnormal data is sent from the slave station, the priority of monitoring is detected. In other words, even when abnormal data is sequentially sent, it is detected and determined which of the monitoring priorities is higher than the first-come-first-served basis. Then, on the basis of the priority thus detected, for example, the second channel corresponding to the abnormal data of high priority is selected. This second channel is a channel that collects image data from the monitoring points, and the master station obtains image data related to monitoring of the monitoring points with higher priority, for example, and performs appropriate monitoring activities by video. It becomes possible.

[0008]

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 shows an embodiment of the present invention.

In the remote monitoring system according to the embodiment of the present invention, the master station 1 and the slave stations A, B and C are ISDs of the ISDN network 2.
It is connected by N lines. The master station 1 includes a CPU 3 that controls the master station 1 as a whole, a management table 4 that is a search table for priority of abnormal data, and a television monitor device (TV).
Monitor) M _1, M _2, a terminal adapter (TA) 5 that performs starting and recovered data transmission and reception of the ISDN network 2 via the ISDN line are provided. Here, the basic interface of the ISDN line includes a D channel having one channel and a B channel having two channels. This D channel is allocated for packet transmission of abnormal data sent from each slave station A to C, and the B channel is allocated to each slave station A to C.
It is assigned to obtain the image data for monitoring from C. Specifically, the D channel is divided into a maximum of 124 packets, and the abnormal data from 124 abnormal monitoring points can be transmitted and used. On the other hand, there are two B channels, each of which is used to transmit image data from one abnormality monitoring point. Therefore, there are a maximum of two monitoring points that can be monitored by images. The terminal adapter 5 gives the abnormal data sent via the D channel to the CPU 3, while giving the image data sent via the B channel to the television monitor devices M ₁ and M ₂ .

On the other hand, the slave stations A to C are provided with C for controlling the slave stations.
PU6 _A to 6 _C, a television camera to obtain a terminal adapter 7 _A to _7-c of the same structure as the terminal adapter 5 of the main station 1, the image data of a predetermined imaging target is connected to the terminal adapter 7 _A ~7 _c (TV camera ) A-TV ₁ , B-
TV ₁ , B-TV ₂ , C-TV ₁ , CPUs 6 _{A to} 6 _C , sensors a _{1 to} a ₃ , connected to the CPUs 6 _{A to} 6 _C via ports not shown.
b _{1 to} b ₃ and c ₁ are provided. Sensors a _{1 to} a ₃ , b
_{1 to} b ₃ and c ₁ are water leak sensors, gas leak sensors, door sensors, fire sensors, etc. For example, even if the same gas leak is detected by different sensors, whether it is a large amount or a small amount. Can be detected.

When the detection signal from the sensor arrives, the CPUs 6 _{A to} 6 _C of the slave stations A to _C create abnormal data by this sensor, activate the terminal adapters 7 _{A to} 7 _c, and send them to the master station 1. A call is made and the created abnormal data is transmitted via the D channel. This abnormal data includes the address (identification information) of the corresponding sensor, and the address (identification information) of the corresponding slave stations A to C is sent as call information.

The abnormal data and the addresses of the slave stations A to C are received by the CPU 3 via the terminal adapter 5 of the master station 1. The management table 4 connected to the CPU 3 holds the priority / monitoring channel search table 200 shown in FIG. 2 and the monitoring channel and priority relating to the currently monitored target shown in FIG. A table (register) 300 to be stored is included. And C of the master station 1
The PU 3 has a program of the flowchart as shown in FIG. 4 in its main memory, and executes the program by starting up the power supply or the like.

That is, the CPU 3 monitors whether abnormal data is received via the terminal adapter 5 (401).
Here, when the reception is performed, based on the address and the sensor address of the slave station which is the source of the transmission of the abnormal data, FIG.
The table 200 is searched to obtain the corresponding priority data (402). Next, the CPU 3 refers to the table 300 to detect whether the monitor channel is blocked, that is, whether the TV monitor devices M ₁ and M ₂ are currently used for displaying an image by any TV camera ( 403). Here, when it is blocked, the priority data of the table 300 is taken out and compared with the priority corresponding to the received abnormal data (404) to see if the priority corresponding to the received abnormal data is higher. (For example, the numbers in FIGS. 2 and 3 are small) is detected (405).

As a result of this detection, if the priority corresponding to the received abnormal data is not high, the step 401 is directly executed.
If the priority corresponding to the received abnormal data is high, the address of the monitoring channel corresponding to this received abnormal data (to the corresponding TV camera is reached) B channel selection information) is detected (406). The CPU 3 controls the terminal adapter 3 to close the low priority monitoring channel,
The address of the supervisory channel is given to make a call and the corresponding B channel is secured (407). At this time, the terminal adapters 7 of the slave stations A to C on the call receiving side connect the corresponding TV camera and the corresponding B channel. Since each TV camera is normally operated all the time, when there is a connection with the B channel, the image data obtained by the TV camera reaches the terminal adapter 5 of the master station 1 via the ISDN network. Prior to this, the terminal adapter 5 connects the B channel and the corresponding TV monitor device M in response to the response from the slave station. Therefore, the incoming image data reaches the corresponding TV monitor device M, and the image to be monitored is displayed here. After the above operation, the CPU 3 rewrites the contents of the table 300 to match the current state (408), and returns to step 401 to continue the operation.

In this embodiment, the priority is detected for the first time in the master station, but the slave station has a priority table corresponding to the sensor so that the priority can be detected.
You may make it transmit this priority with abnormal data. In the embodiment, the switching is not performed when the priorities are equal, but the switching may be performed when the priorities are equal. Further, when the priority is slightly lower (or equal), the CPU 3 is provided with a timer, and the monitoring channel is switched to the sensor corresponding to the abnormal data sent for a predetermined time (or equal), and the priority is again set. May be switched to the higher monitoring channel. Further, the channel does not necessarily have to be formed using the ISDN network.

[0016]

As described above, according to the present invention, since the monitoring channel is selected based on the priority of abnormal data, it takes a long time to carry out monitoring when an abnormality of higher priority occurs. It is possible to prevent malfunctions and perform accurate monitoring.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention.

FIG. 2 is a diagram showing a memory table used in an embodiment of the present invention.

FIG. 3 is a diagram showing a memory table used in an embodiment of the present invention.

FIG. 4 is a flowchart for explaining the operation of the embodiment of the present invention.

FIG. 5 is a block diagram of a conventional remote monitoring system.

[Explanation of Codes] 1 master station 2 ISDN network 3 CPU 4 management table 5 terminal adapter 6 _{A to} 6 _C CPU 7 _{A to} 7 _C terminal adapter M ₁ , M ₂ TV monitor A-TV ₁ , B-TV ₁ , B-TV ₂ , C-TV ₁ TV camera a _{1 to} a ₃ , b _{1 to} b ₃ , c ₁ sensor 200, 300 (memory) table

Claims (1)

[Claims] 1. A first channel for transmitting anomalous data indicating that an abnormality has been detected from a plurality of child stations and one parent station to the parent station, and a channel for transmitting image data. However, at the same time, abnormal data is
In a remote monitoring system in which a channel for collecting image data from a smaller number of monitoring points than the number of monitoring points for which data is collected is connected to a usable second channel, an anomaly sent from the slave station Priority detection means for detecting the monitoring priority of the data, and monitoring for executing the monitoring by the image data by selecting the second channel corresponding to the abnormal data based on the priority detected by the priority detection means. A remote monitoring system comprising: channel selecting means.