CN113398521A - Fire fighting monitoring system and method based on Internet of things - Google Patents

Abstract

The invention provides a fire fighting monitoring system and method based on the Internet of things, which comprises the following steps: carrying out region division on a region to be monitored to obtain a plurality of sub-regions, and configuring the fire-fighting risk grade and the region number of each sub-region; binding the data acquisition module associated with each fire fighting device with the area number of the sub-area where the data acquisition module is located; aiming at each subarea, obtaining a corresponding data uploading period according to fire risk level matching, and sending the data uploading period and the area number to a corresponding area controller; the regional controller receives state data acquired by each data acquisition module with the same regional number in real time, and uploads alarm information and the state data to a fire-fighting monitoring platform in real time when the state data is abnormal so as to remind fire-fighting monitoring personnel to intervene; and uploading the state data to a fire-fighting monitoring platform for storage according to the data uploading period when no abnormity exists. The beneficial effects are that the applicability of the system is improved; the network transmission pressure is effectively reduced while the monitoring requirement is met.

Description

Fire fighting monitoring system and method based on Internet of things

Technical Field

The invention relates to the technical field of fire fighting monitoring, in particular to a fire fighting monitoring system and method based on the Internet of things.

Background

With the continuous acceleration of the urbanization process, in the urban construction process, some hidden trouble problems such as traffic jam, urban garbage, urban waterlogging and the like gradually emerge, wherein the urban fire control which causes the spread of fire due to the dispersed fire control management and untimely discovery of dangerous cases caused by the geographical isolation of various buildings also has various concerns. In recent years, technologies such as the internet of things and cloud computing are rapidly developed and widely applied to various industries, the internet of things is based on material identification, information of various materials can be collected, the information is transmitted to a service center through various networks, and then relevant information is extracted through the service center as required to be used by users. The existing fire fighting monitoring system based on the Internet of things can monitor the running state data of each fire fighting device and give early warning information in time, but the running state data uploading period is not controlled, and unnecessary occupation of network resources is further caused.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a fire fighting monitoring system based on the Internet of things, which comprises:

the system comprises a plurality of fire fighting devices, a monitoring center and a monitoring center, wherein the fire fighting devices are arranged in a region to be monitored, and each fire fighting device is associated with at least one data acquisition module so as to acquire state data of the corresponding fire fighting device;

fire control monitoring platform, fire control monitoring platform includes:

the area division module is used for carrying out area division on the area to be monitored by fire-fighting monitoring personnel to obtain a plurality of sub-areas and configuring fire-fighting risk levels and area numbers of the sub-areas;

the equipment binding module is connected with the area dividing module and used for binding the data acquisition module associated with each fire fighting equipment with the area number of the sub area;

the data storage module is used for storing a plurality of pre-generated fire-fighting risk grades, and each fire-fighting risk grade is associated with a data uploading period;

at least one zone controller configured in each of the sub-zones, the zone controller being connected to the fire monitoring platform, the fire monitoring platform further comprising:

the automatic issuing module is respectively connected with the region dividing module and the data storage module and is used for obtaining the corresponding data uploading period according to the fire risk level matching aiming at each sub-region and issuing the data uploading period and the region number to the corresponding region controller;

each zone controller is also in communication connection with each data acquisition module with the same zone number so as to receive the state data in real time, generate corresponding alarm information when the state data is abnormal, upload the alarm information and the state data to the fire fighting monitoring platform in real time so as to remind the fire fighting monitoring personnel to intervene, and upload the state data to the fire fighting monitoring platform according to the data uploading period when the state data is not abnormal so as to store.

Preferably, the area dividing module includes:

the map acquisition unit is used for acquiring an electronic map of the area to be monitored, and the electronic map comprises distribution position information of each fire fighting device;

the data configuration unit is connected with the map acquisition unit and used for the fire fighting monitoring personnel to perform area division according to the electronic map to obtain a plurality of sub-areas and configure the fire fighting risk level and the area number of each sub-area;

the equipment binding module binds the data acquisition module associated with each fire fighting equipment to the area number of the sub-area according to the limited position range of each sub-area and the distribution position information.

Preferably, the fire monitoring platform further includes an update detection module, respectively connected to the area division module and the automatic issuing module, and the update detection module includes:

the data detection unit is used for continuously detecting the fire-fighting risk level of each subarea according to a preset detection period;

the data comparison unit is connected with the data detection unit and used for outputting an updating signal containing the area number of the sub-area and the currently acquired fire-fighting risk level when the currently detected fire-fighting risk level is different from the last detected fire-fighting risk level for each sub-area;

and the automatic issuing module obtains the corresponding data uploading period according to the updating signal matching, and issues the data uploading period to the zone controller corresponding to the zone number so as to update the data uploading period of the state data.

Preferably, the fire monitoring platform further includes a period configuration module, connected to the update detection module, and configured to allow the fire manager to manually configure and issue the data upload period associated with the sub-area and the effective time of the manual configuration;

the update detection module further includes a control unit, connected to the data detection unit, for controlling the data detection unit to stop detecting the fire risk level of the corresponding sub-area within the valid time.

The invention also provides a fire fighting monitoring method based on the Internet of things, which is applied to the fire fighting monitoring system based on the Internet of things, wherein a to-be-monitored area of the fire fighting monitoring system is provided with a plurality of fire fighting devices, and each fire fighting device is associated with at least one data acquisition module;

the fire fighting monitoring method includes a pre-configuration process including:

step A1, the fire-fighting monitoring system is used for fire-fighting monitoring personnel to perform area division on the area to be monitored to obtain a plurality of sub-areas, and the fire-fighting risk level and the area number of each sub-area are configured;

step A2, the fire fighting monitoring system binds the data acquisition module associated with each fire fighting device to the area number of the sub-area where the data acquisition module is located;

step A3, the fire fighting monitoring system matches the fire fighting risk level in the pre-generated corresponding relationship between the fire fighting risk level and the data uploading period according to the fire fighting risk level to obtain the corresponding data uploading period, and issues the data uploading period and the area number to the corresponding area controller;

the fire fighting monitoring method further comprises:

step S1, the fire fighting monitoring system collects the state data of each fire fighting device through each data collection module;

step S2, the region controller receives the status data acquired by each data acquisition module having the same region number in real time, and determines whether the status data is abnormal:

if so, generating corresponding alarm information, and uploading the alarm information and the state data to the fire-fighting monitoring platform in real time to remind the fire-fighting monitoring personnel of intervening;

and if not, uploading the state data to the fire fighting monitoring platform for storage according to the data uploading period.

Preferably, the step a1 includes:

step A11, the fire fighting monitoring system obtains an electronic map of the area to be monitored, wherein the electronic map comprises distribution position information of each fire fighting device;

step A12, the fire fighting monitoring system is used for the fire fighting monitoring personnel to perform area division according to the electronic map to obtain a plurality of sub-areas, and the fire fighting risk level and the area number of each sub-area are configured;

in step a2, the fire fighting monitoring system binds the data acquisition module associated with each fire fighting device to the area number of the sub-area according to the limited location range and the distribution location information of each sub-area.

Preferably, an automatic update detection process is further included, comprising:

step B1, the fire-fighting monitoring system continuously detects the fire-fighting risk level of each sub-area according to a preset detection period;

step B2, the fire fighting monitoring system judges whether the currently detected fire fighting risk level is the same as the last detected fire fighting risk level for each sub-area:

if yes, returning to the step B1;

if not, outputting an updating signal containing the area number of the sub-area and the currently acquired fire-fighting risk level;

and step B3, the fire fighting monitoring system obtains the corresponding data uploading period according to the updating signal matching, and sends the data uploading period to the zone controller corresponding to the zone number so as to update the data uploading period of the state data, and then returns to the step B1.

Preferably, a period configuration module is provided, which is used for the fire manager to manually configure and issue the data upload period associated with the sub-area and the effective time of the manual configuration;

the automatic update detection process further includes the fire monitoring system controlling to stop detecting the fire risk level of the corresponding sub-area within the valid time.

The technical scheme has the following advantages or beneficial effects:

1) a data configuration port is provided for a fire protection manager, so that the fire protection manager can divide sub-areas and configure fire protection risk levels and area numbers according to the monitoring requirements of the area to be monitored, and can adjust in time when the monitoring requirements change, thereby improving the applicability of the system;

2) different data uploading periods are configured according to different fire risk levels, so that the monitoring requirement is met, and the network transmission pressure is effectively reduced;

3) the manual cycle configuration port is provided, so that fire managers can configure the data uploading cycle and the effective time of any sub-area, the manually configured data uploading cycle is executed in the effective time, the fire fighting risk level of the sub-area is not changed, the cycle adjustment can be carried out, and the specific monitoring requirement is met.

Drawings

Fig. 1 is a schematic structural diagram of a fire monitoring system based on the internet of things according to a preferred embodiment of the present invention;

FIG. 2 is a flow chart illustrating a pre-configuration process according to a preferred embodiment of the present invention;

fig. 3 is a schematic flow chart of a fire fighting monitoring method based on the internet of things according to a preferred embodiment of the present invention;

FIG. 4 is a flow chart illustrating a region partition process according to a preferred embodiment of the present invention;

FIG. 5 is a flow chart illustrating an automatic update detection process according to a preferred embodiment of the present invention.

Detailed Description

The invention is described in detail below with reference to the figures and specific embodiments. The present invention is not limited to the embodiment, and other embodiments may be included in the scope of the present invention as long as the gist of the present invention is satisfied.

In a preferred embodiment of the present invention, based on the above problems in the prior art, there is provided an internet of things-based fire monitoring system, as shown in fig. 1, including:

the system comprises a plurality of fire fighting devices 1, a monitoring center and a monitoring center, wherein each fire fighting device 1 is associated with at least one data acquisition module 2 so as to acquire state data of the corresponding fire fighting device 1;

fire control monitor platform 3, fire control monitor platform 3 includes:

the area division module 31 is used for the fire monitoring personnel to perform area division on the area to be monitored to obtain a plurality of sub-areas and configure the fire risk level and the area number of each sub-area;

the equipment binding module 32 is connected with the area dividing module 31 and used for binding the data acquisition modules associated with the fire fighting equipment with the area numbers of the sub-areas where the data acquisition modules are located;

the data storage module 33 is used for storing a plurality of fire-fighting risk levels generated in advance, and each fire-fighting risk level is associated with a data uploading period;

at least one area controller 4, dispose in every subregion, area controller 4 connects fire control monitoring platform 3, and fire control monitoring platform 3 still includes:

the automatic issuing module 34 is respectively connected with the region dividing module 31 and the data storage module 33, and is used for obtaining a corresponding data uploading period according to the fire risk level matching for each sub-region and issuing the data uploading period and the region number to a corresponding region controller;

each zone controller 4 is also in communication connection with each data acquisition module 2 with the same zone number to receive the state data in real time, generate corresponding alarm information when the state data is abnormal, upload the alarm information and the state data to the fire-fighting monitoring platform in real time to remind fire-fighting monitoring personnel to intervene, and upload the state data to the fire-fighting monitoring platform according to a data uploading period to store when the state data is not abnormal.

Specifically, in this embodiment, in each sub-area, a plurality of the area controllers 4 may be set as redundant configurations, so as to improve the reliability of the system. After the sub-area division is completed and the fire fighting class configuration is completed, the data uploading period and the area number are only required to be issued once, and subsequently, in the fire fighting monitoring process, the area controller 4 uploads the state data according to the data uploading period. If the fire protection management personnel subdivide the sub-areas in the fire protection monitoring process, the binding of the area numbers and the issuing of the data uploading period need to be carried out again, and if the fire protection management personnel reconfigure the fire protection risk level, the corresponding data uploading period needs to be matched again and the corresponding data uploading period needs to be issued. The fire-fighting risk level can be obtained by collecting the combustible and explosive material inventory, the environmental data, the building data and the like of the sub-area through big data analysis, and can also be evaluated by a fire-fighting expert, which is not the invention point of the technical scheme, and the specific implementation mode is not repeated.

Further, the data acquisition module includes, but is not limited to, a pressure sensor, a smoke sensor, a flame detector, an environmental data acquisition device, and the like, wherein the environmental data acquisition device includes, but is not limited to, an environmental temperature acquisition state, an environmental humidity acquisition device, and the like. After receiving the state data acquired by the data acquisition module, the region controller first preprocesses the state data before uploading the data to judge whether the state data is abnormal, wherein the abnormality can be overlarge pressure, smoke concentration overrun and the like. And when the state data is abnormal, uploading the corresponding alarm information and the corresponding state data in real time so that a fire manager can acquire the alarm information and the corresponding state data at the first time, and then timely performing intervention processing. After the data uploading is completed, if data abnormity occurs again in one data uploading period, the data is uploaded in real time, and if the data abnormity does not occur, the data is uploaded again when one data uploading period is reached, so that the monitoring requirement is met, and meanwhile, the network transmission pressure is effectively reduced.

In a preferred embodiment of the present invention, the area dividing module 31 includes:

the map acquiring unit 311 is configured to acquire an electronic map of an area to be monitored, where the electronic map includes distribution location information of each fire fighting device;

the data configuration unit 312 is connected to the map acquisition unit 311, and is used for fire monitoring personnel to perform area division according to the electronic map to obtain a plurality of sub-areas and configure fire protection risk levels and area numbers of the sub-areas;

the device binding module 32 binds the data acquisition module associated with each fire fighting device to the area number of the sub-area according to the limited position range and the distribution position information of each sub-area.

Specifically, in this embodiment, above-mentioned electronic map can be the GIS map, makes things convenient for the fire control managers to carry out regional division.

In a preferred embodiment of the present invention, the fire monitoring platform 3 further includes an update detection module 35, which is respectively connected to the area dividing module 31 and the automatic issuing module 34, and the update detection module 35 includes:

the data detection unit 351 is used for continuously detecting the fire-fighting risk level of each sub-area according to a preset detection period;

the data comparison unit 352 is connected to the data detection unit 351, and is configured to, for each sub-area, output an update signal including the area number of the sub-area and the currently obtained fire risk level when the currently detected fire risk level is different from the last detected fire risk level;

the automatic issuing module 34 obtains a corresponding data uploading period according to the update signal matching, and issues the data uploading period to the zone controller corresponding to the zone number, so as to update the data uploading period of the state data.

Specifically, in this embodiment, in the fire control monitoring process, whether the fire protection risk level of each sub-area changes can be detected according to a preset detection period, and when the fire protection risk level changes, the associated data uploading period is updated and automatically issued in time, so that the adaptability adjustment of the data uploading period is realized.

In a preferred embodiment of the present invention, the fire monitoring platform 3 further includes a period configuration module 36, connected to the update detection module 35, for the fire manager to manually configure and issue a data upload period associated with the sub-area and an effective time of this manual configuration;

the update detection module 35 further includes a control unit 353 connected to the data detection unit 351 for controlling the data detection unit 351 to stop detecting the fire-fighting risk level of the corresponding sub-area within the valid time.

Specifically, in this embodiment, the period configuration module 36 serves as a manual configuration port, and can meet specific monitoring requirements, that is, the data uploading period of a certain sub-area is changed within a predetermined time without changing the fire risk level thereof, and the predetermined time, that is, the effective time, can be configured by itself. In terms of distance, if the data uploading period of a certain time period in a day of a certain sub-area needs to be different from the data uploading periods of other time periods, the data uploading period can be configured by the period configuration module 36, so that the manually configured data uploading period is executed within the effective time, and the data uploading period adapted to the fire fighting risk level of the sub-area is executed outside the effective time.

The invention also provides a fire fighting monitoring method based on the Internet of things, which is applied to the fire fighting monitoring system based on the Internet of things, wherein a to-be-monitored area of the fire fighting monitoring system is provided with a plurality of fire fighting devices, and each fire fighting device is associated with at least one data acquisition module;

the fire monitoring method includes a pre-configuration process, as shown in fig. 2, including:

step A1, the fire-fighting monitoring system is used for fire-fighting monitoring personnel to perform area division on an area to be monitored to obtain a plurality of sub-areas, and the fire-fighting risk level and the area number of each sub-area are configured;

step A2, the fire-fighting monitoring system binds the data acquisition modules associated with the fire-fighting equipment with the area numbers of the sub-areas where the data acquisition modules are located;

step A3, the fire protection monitoring system matches each sub-area in the corresponding relationship between the pre-generated fire protection risk level and the data uploading period according to the fire protection risk level to obtain the corresponding data uploading period, and sends the data uploading period and the area number to the corresponding area controller;

as shown in fig. 3, the fire fighting monitoring method further includes:

step S1, the fire-fighting monitoring system collects the state data of each fire-fighting equipment through each data collection module;

step S2, the zone controller receives the status data collected by the data collection modules with the same zone numbers in real time, and judges whether the status data is abnormal:

if so, generating corresponding alarm information, and uploading the alarm information and the state data to a fire-fighting monitoring platform in real time to remind fire-fighting monitoring personnel to intervene;

and if not, uploading the state data to a fire-fighting monitoring platform according to the data uploading period for storage.

In the preferred embodiment of the present invention, as shown in fig. 4, step a1 includes:

step A11, a fire-fighting monitoring system acquires an electronic map of an area to be monitored, wherein the electronic map comprises distribution position information of fire-fighting equipment;

step A12, the fire-fighting monitoring system is used for fire-fighting monitoring personnel to divide areas according to the electronic map to obtain a plurality of sub-areas, and the fire-fighting risk level and the area number of each sub-area are configured;

in step a2, the fire monitoring system binds the data acquisition modules associated with the fire fighting devices to the area numbers of the sub-areas according to the limited location range and the distributed location information of each sub-area.

In a preferred embodiment of the present invention, an automatic update detection process is further included, as shown in fig. 5, including:

step B1, the fire-fighting monitoring system continuously detects the fire-fighting risk level of each sub-area according to a preset detection period;

step B2, the fire protection monitoring system judges whether the currently detected fire protection risk level is the same as the last detected fire protection risk level for each sub-area:

if yes, returning to the step B1;

if not, outputting an updating signal containing the area number of the sub-area and the currently acquired fire-fighting risk level;

and step B3, the fire fighting monitoring system obtains a corresponding data uploading period according to the updating signal matching, and sends the data uploading period to the zone controller corresponding to the zone number so as to update the data uploading period of the state data, and then returns to the step B1.

In a preferred embodiment of the present invention, a period configuration module is provided for a fire manager to manually configure and issue a data upload period associated with a sub-area and an effective time of this manual configuration;

the automatically updating the detection process further includes the fire monitoring system controlling to stop detecting the fire risk level of the corresponding sub-area for a valid time.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.

Claims (8)

1. A fire control monitored control system based on thing networking, includes:

the system comprises a plurality of fire fighting devices, a monitoring center and a monitoring center, wherein the fire fighting devices are arranged in a region to be monitored, and each fire fighting device is associated with at least one data acquisition module so as to acquire state data of the corresponding fire fighting device;

fire control monitoring platform, fire control monitoring platform includes:

the area division module is used for carrying out area division on the area to be monitored by fire-fighting monitoring personnel to obtain a plurality of sub-areas and configuring fire-fighting risk levels and area numbers of the sub-areas;

the equipment binding module is connected with the area dividing module and used for binding the data acquisition module associated with each fire fighting equipment with the area number of the sub area;

the data storage module is used for storing a plurality of pre-generated fire-fighting risk grades, and each fire-fighting risk grade is associated with a data uploading period;

at least one zone controller configured in each of the sub-zones, the zone controller being connected to the fire monitoring platform, the fire monitoring platform further comprising:

the automatic issuing module is respectively connected with the region dividing module and the data storage module and is used for obtaining the corresponding data uploading period according to the fire risk level matching aiming at each sub-region and issuing the data uploading period and the region number to the corresponding region controller;

each zone controller is also in communication connection with each data acquisition module with the same zone number so as to receive the state data in real time, generate corresponding alarm information when the state data is abnormal, upload the alarm information and the state data to the fire fighting monitoring platform in real time so as to remind the fire fighting monitoring personnel to intervene, and upload the state data to the fire fighting monitoring platform according to the data uploading period when the state data is not abnormal so as to store.

2. A fire monitoring system based on internet of things as recited in claim 1, wherein the area division module comprises:

the map acquisition unit is used for acquiring an electronic map of the area to be monitored, and the electronic map comprises distribution position information of each fire fighting device;

the data configuration unit is connected with the map acquisition unit and used for the fire fighting monitoring personnel to perform area division according to the electronic map to obtain a plurality of sub-areas and configure the fire fighting risk level and the area number of each sub-area;

the equipment binding module binds the data acquisition module associated with each fire fighting equipment to the area number of the sub-area according to the limited position range of each sub-area and the distribution position information.

3. A fire monitoring system based on internet of things as defined in claim 1, wherein the fire monitoring platform further comprises an update detection module respectively connected to the area division module and the automatic issuing module, the update detection module comprising:

the data detection unit is used for continuously detecting the fire-fighting risk level of each subarea according to a preset detection period;

the data comparison unit is connected with the data detection unit and used for outputting an updating signal containing the area number of the sub-area and the currently acquired fire-fighting risk level when the currently detected fire-fighting risk level is different from the last detected fire-fighting risk level for each sub-area;

and the automatic issuing module obtains the corresponding data uploading period according to the updating signal matching, and issues the data uploading period to the zone controller corresponding to the zone number so as to update the data uploading period of the state data.

4. The Internet of things-based fire monitoring system according to claim 3, wherein the fire monitoring platform further comprises a period configuration module, connected to the update detection module, for the fire manager to manually configure and issue the data upload period associated with the sub-region and the effective time of this manual configuration;

the update detection module further includes a control unit, connected to the data detection unit, for controlling the data detection unit to stop detecting the fire risk level of the corresponding sub-area within the valid time.

5. A fire fighting monitoring method based on the Internet of things is applied to the fire fighting monitoring system based on the Internet of things as claimed in any one of claims 1 to 4, a region to be monitored of the fire fighting monitoring system is provided with a plurality of fire fighting devices, and each fire fighting device is associated with at least one data acquisition module;

the fire fighting monitoring method includes a pre-configuration process including:

step A1, the fire-fighting monitoring system is used for fire-fighting monitoring personnel to perform area division on the area to be monitored to obtain a plurality of sub-areas, and the fire-fighting risk level and the area number of each sub-area are configured;

step A2, the fire fighting monitoring system binds the data acquisition module associated with each fire fighting device to the area number of the sub-area where the data acquisition module is located;

step A3, the fire fighting monitoring system matches the fire fighting risk level in the pre-generated corresponding relationship between the fire fighting risk level and the data uploading period according to the fire fighting risk level to obtain the corresponding data uploading period, and issues the data uploading period and the area number to the corresponding area controller;

the fire fighting monitoring method further comprises:

step S1, the fire fighting monitoring system collects the state data of each fire fighting device through each data collection module;

step S2, the region controller receives the status data acquired by each data acquisition module having the same region number in real time, and determines whether the status data is abnormal:

if so, generating corresponding alarm information, and uploading the alarm information and the state data to the fire-fighting monitoring platform in real time to remind the fire-fighting monitoring personnel of intervening;

and if not, uploading the state data to the fire fighting monitoring platform for storage according to the data uploading period.

6. A fire fighting monitoring method based on the Internet of things as claimed in claim 5, wherein the step A1 includes:

step A11, the fire fighting monitoring system obtains an electronic map of the area to be monitored, wherein the electronic map comprises distribution position information of each fire fighting device;

step A12, the fire fighting monitoring system is used for the fire fighting monitoring personnel to perform area division according to the electronic map to obtain a plurality of sub-areas, and the fire fighting risk level and the area number of each sub-area are configured;

in step a2, the fire fighting monitoring system binds the data acquisition module associated with each fire fighting device to the area number of the sub-area according to the limited location range and the distribution location information of each sub-area.

7. A fire monitoring method based on internet of things as recited in claim 5, further comprising an automatic update detection process comprising:

step B1, the fire-fighting monitoring system continuously detects the fire-fighting risk level of each sub-area according to a preset detection period;

step B2, the fire fighting monitoring system judges whether the currently detected fire fighting risk level is the same as the last detected fire fighting risk level for each sub-area:

if yes, returning to the step B1;

if not, outputting an updating signal containing the area number of the sub-area and the currently acquired fire-fighting risk level;

and step B3, the fire fighting monitoring system obtains the corresponding data uploading period according to the updating signal matching, and sends the data uploading period to the zone controller corresponding to the zone number so as to update the data uploading period of the state data, and then returns to the step B1.

8. The Internet of things-based fire monitoring method according to claim 7, wherein a period configuration module is provided for the fire manager to manually configure and issue the data upload period associated with the sub-area and the effective time of the manual configuration;

the automatic update detection process further includes the fire monitoring system controlling to stop detecting the fire risk level of the corresponding sub-area within the valid time.

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