KR102599210B1 - System for room management - Google Patents

Abstract

The present invention includes a first terminal that identifies people entering the target area and generates occupant identification information, a second terminal that identifies people leaving the target area and generates exit identification information, and is provided at the entrance of the target area. , a third terminal outputting information, and receiving occupant identification information and exiting occupant identification information from the first and second terminals, respectively, and providing information on the target area based on the received occupant identification information and exiting occupant identification information. It is characterized by including a server that calculates occupancy status information and outputs the calculated occupancy status information and the number of people restricted from entering the target area through a third terminal.

Description

Occupancy management system {SYSTEM FOR ROOM MANAGEMENT}

The present invention relates to an occupancy management system, and more specifically, to an occupancy management system that checks and displays the number of occupants and the limited number of occupants in a multi-use facility.

Recently, to prevent the spread of infectious diseases such as coronavirus, quarantine rules are being strengthened by wearing masks, creating a list of visitors, measuring body temperature when entering multi-use facilities, and enforcing social distancing. In addition, in accordance with the strengthening of quarantine rules, the number of people available for use is posted and provided at the entrance of multi-use facilities.

However, there is a problem with this method that it can only guide the number of people who can use the multi-use facility, but does not sufficiently provide information on the occupancy status of the multi-use facility. In addition, since the posting and guidance of the number of people who can use a multi-use facility is done manually by the manager of the multi-use facility, there is a problem that it does not sufficiently reflect the changing status of infected people in real time.

The background technology of the present invention is disclosed in 'Real-time occupancy counting device' in Korean Patent Publication No. 10-2013-0004424 (January 10, 2013).

The present invention was created to solve the above-mentioned problems, and the purpose of one aspect of the present invention is to provide an occupancy management system that can check and display the number of occupants and the limited number of occupants in a multi-use facility.

An occupancy management system according to an aspect of the present invention includes a first terminal that identifies a person entering a target area and generates occupant identification information; a second terminal that identifies a person leaving the target area and generates exit identification information; a third terminal provided at the entrance of the target area to output information; and receiving the occupant identification information and the occupant identification information from the first terminal and the second terminal, respectively, and providing occupancy status information for the target area based on the received occupant identification information and the occupant identification information. and a server that calculates and outputs the calculated occupancy status information and the restricted number of people entering the target area through the third terminal.

In the present invention, the occupant identification information includes a facial image and an entry time of the person entering the room, and the exiting person identification information includes a facial image and an exit time of the person leaving the room.

In the present invention, when the occupant identification information is received, the server stores the facial image included in the received occupant identification information in a database, and when the occupant identification information is received, the server: A facial image corresponding to the facial image included in the received identification information of the person leaving the room is detected in the database, and it is determined that the person corresponding to the detected facial image has left the room.

In the present invention, the server determines that people other than those determined to have left the room among the people corresponding to the facial image stored in the database are present, calculates the number of people determined to be present, and calculates the number of people determined to be present. The number of is used as the occupancy status information.

In the present invention, when it is determined that the number of people determined to be present is greater than or equal to the number of access restrictions set in the target area, the server calculates the average occupancy time of the people determined to have left the target area, and The entry time is calculated based on the calculated average occupancy time, and the calculated entry time is output through the third terminal.

In the present invention, the server calculates the occupancy time of each person who exited the target area based on the exit time included in the occupancy identification information and the entry time included in the occupancy identification information, and The average occupancy time is calculated by averaging the calculated occupancy times.

In the present invention, the server detects the entry time of the person who entered first among the people determined to be in the target area, and adds the calculated average occupancy time to the detected entry time to determine the entry time. It is characterized by calculating.

In the present invention, the server receives infectious disease infection status information and area information of the target area, and sets the restricted number of people based on the input infectious disease infection status information and area information of the target area. .

In the present invention, the server determines the infectious disease spread level based on the real-time number of infectious disease patients included in the input infectious disease infection status information, determines the restricted number of people per unit area based on the determined infectious disease spread level, and The restricted access number is set based on the determined number of restricted people per unit area and the input area information of the target area.

According to one aspect of the present invention, the number of occupants of a multi-use facility can be determined in real time, and the identified number of occupants can be displayed at the entrance of the multi-use facility to guide users of the multi-use facility.

According to another aspect of the present invention, a limited number of people in a multi-use facility can be set based on the real-time infectious disease infection status, and the set limit can be displayed at the entrance of the multi-use facility to guide users of the multi-use facility.

According to another aspect of the present invention, the spread of infectious diseases can be prevented by displaying the number of occupants and the limited number of occupants of the multi-use facility at the entrance of the multi-use facility so that the number of occupants of the multi-use facility is maintained at an appropriate level.

1 is a block diagram for explaining an occupancy management system according to an embodiment of the present invention.
Figure 2 is an exemplary diagram for explaining an occupancy management system according to an embodiment of the present invention.
Figure 3 is an exemplary diagram for explaining the first and second terminals of the occupancy management system according to an embodiment of the present invention.
Figure 4 is an exemplary diagram for explaining a third terminal of an occupancy management system according to an embodiment of the present invention.
Figure 5 is an example diagram to explain a process in which the server of the occupancy management system calculates the room entry time according to an embodiment of the present invention.
Figure 6 is an example diagram for explaining a user interface provided through a server of an occupancy management system according to an embodiment of the present invention.
Figure 7 is a flow chart to explain the process of outputting occupancy status information by the occupancy management system according to an embodiment of the present invention.
Figure 8 is a flow chart to explain the process by which the occupancy management system calculates occupancy status information according to an embodiment of the present invention.
Figure 9 is a flowchart illustrating a process by which the occupancy management system according to an embodiment of the present invention determines whether a person who has entered the target area has left the room.
Figure 10 is a flowchart for explaining a process in which the occupancy management system outputs the restricted number of people in accordance with an embodiment of the present invention.
Figure 11 is a flowchart to explain the process of outputting the entry time by the occupancy management system according to an embodiment of the present invention.

Hereinafter, the occupancy management system according to an embodiment of the present invention will be described in detail with reference to the attached drawings. In this process, the thickness of lines or sizes of components shown in the drawing may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a block diagram for explaining an occupancy management system according to an embodiment of the present invention, FIG. 2 is an exemplary diagram for explaining an occupancy management system according to an embodiment of the present invention, and FIG. 3 is a block diagram for explaining an occupancy management system according to an embodiment of the present invention. Figure 4 is an exemplary diagram for explaining the first and second terminals of the occupancy management system according to an embodiment of the present invention, and Figure 4 is an exemplary diagram for explaining the third terminal of the occupancy management system according to an embodiment of the present invention. Figure 5 is an example diagram illustrating the process by which the server of the occupancy management system calculates the room availability time according to an embodiment of the present invention, and Figure 6 is provided through the server of the occupancy management system according to an embodiment of the present invention. This is an example to explain the user interface.

Referring to Figures 1 and 2, the presence management system according to an embodiment of the present invention may include a first terminal 100, a second terminal 200, a third terminal 300, and a server 400. .

The first terminal 100 may identify a person entering the target area and generate occupant identification information. For example, the first terminal 100 is installed at the entrance of the target area, identifies people entering the target area, generates occupant identification information, and sends the generated occupant identification information to the server 400, which will be described later. Can be transmitted. According to one embodiment, the occupant identification information may include a facial image and entrance time of the person entering the target area. The first terminal 100 may include a camera, and may capture a facial image of a person entering the target area through the camera. The first terminal 100 may detect the time at which a person entering the target area is identified and use the detected time as the entry time.

Additionally, the occupant identification information may include whether the person entering the target area is wearing a mask and their body temperature. The first terminal 100 may determine whether the person entering the target area is wearing a mask based on the facial image. The first terminal 100 may include a temperature sensor and measure the body temperature of the person entering the room through the temperature sensor.

The first terminal 100 may be provided at each entrance of the target area. Here, the target area may be a multi-use facility such as an event hall or exhibition hall. Figure 3 shows an example of the first terminal 100. Meanwhile, when the target area is divided into a plurality of detailed spaces (eg, booths), the first terminal 100 may be provided at the entrance of each detailed space.

The second terminal 200 may identify a person leaving the target area and generate exiting person identification information. For example, the second terminal 200 may be installed at the exit of the target area, identify a person leaving the target area, generate exit identification information, and transmit the generated exit identification information to the server 400. there is. According to one embodiment, the exiting person identification information may include a facial image and exit time of the person exiting the target area. The second terminal 200 may include a camera, and may capture a facial image of a person leaving the target area through the camera. The second terminal 200 may detect the time at which a person exiting the target area is identified and use the detected time as the exit time.

Additionally, the identification information of the person leaving the target area may include whether the person leaving the target area is wearing a mask and their body temperature. The second terminal 200 may determine whether the person leaving the target area is wearing a mask based on the facial image. The second terminal 200 may include a temperature sensor and can measure the body temperature of a person leaving the room through the temperature sensor. The second terminal 200 may be provided at each exit of the target area. When the target area is divided into a plurality of detailed spaces (eg, booths), the second terminal 200 may be provided at the exit of each detailed space.

The third terminal 300 can output information transmitted from the server 400. For example, the third terminal 300 may be a display and may be installed at the entrance and exit of the target area. Meanwhile, when the first and second terminals 200 are equipped with displays, the displays provided in the first and second terminals 200 may be used as the third terminal 300. Meanwhile, when the target area is divided into a plurality of detailed spaces (eg, booths), the third terminal 300 may be provided at the entrance and exit of each detailed space. The display size of the third terminal 300 can be changed as needed. Figure 4 shows an example of a screen output through the third terminal 300.

The server 400 receives the entering and exiting person identification information from the first terminal 100 and the second terminal 200, respectively, and sends information to the target area based on the received entering and exiting person identification information. Occupancy status information can be calculated, and the calculated occupancy status information and the restricted number of people entering the target area can be output through the third terminal 300.

Here, the occupancy status information may include the number of occupants, which is the number of people present in the target area. In addition, the occupancy status information may further include the number of occupants, which is the number of people who entered the target area, and the number of people who left the target area, which is the number of people who left the target area.

Below, we will look at the operation process of the server 400 when occupant identification information is received.

When the occupant identification information is received, the server 400 may match the facial image and room entry time included in the occupant identification information and store them in the database. If the occupant identification information includes whether a mask is worn and body temperature, the server 400 may match whether a mask is worn and body temperature with the facial image and store it in the database.

If there are multiple entrances to the target area, the location information of the first terminal 100 provided at each entrance may be stored in advance in the server 400, and the server 400 may be configured to transmit the first terminal 100 that transmits the occupant identification information. The location information of the terminal 100 may be detected, the detected location information (i.e., entry location) may be matched with the facial image and stored in a database.

Meanwhile, for various reasons, there may be a case where a person entering the target area is repeatedly identified through the first terminal 100. In this case, only one person actually enters the target area, but the occupant identification information is stored multiple times. Reception problems may occur. To prevent this, if multiple resident identification information for the same person is received within a preset time, the server 400 may discard all but one of the duplicated resident identification information. The server 400 may use a facial recognition algorithm to determine whether the received occupant identification information is for the same person. The setting time can be changed as needed.

Below, we will look at the operation process of the server 400 when the identification information of the person leaving the room is received.

When the exiting person identification information is received, the server 400 detects a facial image corresponding to the facial image included in the exiting person identification information among the facial images stored in the database, and determines whether the person corresponding to the detected facial image has left the room. It can be judged that The server 400 compares the facial image stored in the database with the facial image included in the exiting person identification information using a facial recognition algorithm to select a facial image corresponding to the facial image included in the exiting person identification information among the facial images stored in the database. It can be detected. The server 400 may match the check-out time included in the check-out person identification information with the detected facial image and store it in a database.

If there are multiple exits of the target area, the location information of the second terminal 200 provided at each exit may be stored in advance in the server 400, and the server 400 may be configured to send the second terminal 200 that transmits the exiting person identification information. The location information of the terminal 200 may be detected, the detected location information (i.e., exit location) may be matched with the facial image and stored in a database.

Below, we will look at the process by which the server 400 calculates occupancy status information.

First, the server 400 may determine that among the people corresponding to the facial image stored in the database (i.e., people who entered the target area), excluding those determined to have left the room, are present.

Next, the server 400 can calculate the number of people determined to be occupancy (i.e., the number of occupants) and use the calculated number of people as occupancy status information. Meanwhile, the server 400 includes the number of people determined to have left the target area (i.e., the number of people leaving) and the number of people who entered the target area (i.e., the number of people admitted) into the occupancy status information. It may be possible. The server 400 calculates the number of occupants by adding the number of people determined to have left the target area (i.e., the number of occupants) and the number of people determined to be present in the target area (i.e., the number of occupants). You can.

Meanwhile, the server 400 may receive information on the infectious disease infection status and area information of the target area, and set the number of people restricted from entering based on the received infectious disease infection status information and area information.

Below, we will look at the process by which the server 400 sets the number of people accessing the restricted access.

First, the server 400 can receive infectious disease infection status information and area information of the target area from the outside. Here, the infectious disease infection status information may include information on the number of infectious disease patients currently occurring in the country (or a certain region), and the area information may include the facility area of the target area.

Next, the server 400 may determine the infectious disease spread level based on the number of infectious disease patients included in the input infectious disease infection status information. The infectious disease spread level according to the number of infectious disease patients may be stored in advance in the server 400 in the form of a lookup table, and the server 400 refers to the stored lookup table and detects the infectious disease spread level corresponding to the input number of infectious disease patients. By doing so, the level of infectious disease spread can be determined.

Subsequently, the server 400 may determine the number of people restricted from entering per unit area based on the determined infectious disease spread level. The number of people restricted from entering per unit area according to the infectious disease spread level may be stored in advance in the server 400 in the form of a lookup table, and the server 400 refers to the stored lookup table and restricts access per unit area corresponding to the determined infectious disease spread level. You can decide the number of people.

Subsequently, the server 400 may set the number of restricted persons based on the determined number of restricted persons per unit area and the input area information of the target area. The server 400 may multiply the number of people restricted from entering per unit area by the facility area included in the area information of the input target area, and set the calculated value as the number of people restricted from entering.

According to another embodiment, the server 400 receives information corresponding to the level of spread of an infectious disease (for example, information about the social distancing level) from the outside, and determines the number of people restricted from entering per unit area according to the input information. , the number of restricted people can be set based on the determined number of restricted people per unit area and the input area information of the target area.

Meanwhile, the server 400 determines whether the number of people determined to be present in the target area is greater than or equal to the access limit set in the target area, and if it is determined that the number of people determined to be present is greater than or equal to the set access limit, The average occupancy time of people determined to have left the target area can be calculated, the entry time can be calculated based on the calculated average occupancy time, and the calculated entry time can be output through the third terminal 300. .

When the number of people determined to be in the target area is greater than or equal to the number of access restrictions set in the target area, and there are people waiting to enter, the server 400 determines the time available for admission (i.e., the time for the people waiting to enter) to enter. The waiting time) can be calculated, and the calculated entry time can be output through the third terminal 300.

The server 400 may generate a warning message if the number of people determined to be present in the target area is greater than or equal to the access limit set for the target area, and may transmit the generated warning message to the outside. For example, the server 400 may transmit the generated warning message to the third terminal 300 or to a pre-registered administrator terminal.

Below, we will look at the process by which the server 400 calculates the entry time.

First, the server 400 may determine whether the number of people determined to be present in the target area is greater than or equal to the number of access restrictions set for the target area.

If the number of people determined to be present is determined to be greater than the set access limit number, the server 400 may calculate the occupied time of each person determined to have left the target area. The server 400 may calculate the occupancy time of each person determined to have vacated the target area based on the exit time stored in the database and the entry time matched to the corresponding exit time.

Subsequently, the server 400 may average the calculated presence times to calculate the average presence time of the target area.

Subsequently, the server 400 may detect the entry time of the person who entered the room first among those determined to be present in the target area. The server 400 may detect the entry time of the person who entered the room first among the people determined to be in the target area by comparing the entry times stored in the database.

Subsequently, the server 400 may calculate the entry time by adding the average occupancy time calculated in advance to the detected entry time. Figure 5 shows an example to explain the process of calculating the room entry time.

The server 400 may calculate an expected exit time for each person determined to be present in the target area by adding the calculated average occupancy time to the entrance time of each person determined to be present in the target area.

Meanwhile, the server 400 may provide a user interface for user registration, search, and management. The user can register an administrator who can use the server 400, set the administrator's authority, search for a registered administrator, or delete a registered administrator through the user interface. Figure 6a shows an example of a user interface for registering, searching, and managing users.

The server 400 may provide a user interface for registration, search, and management of the first to third terminals 300. The server 400 registers the first to third terminals 300, searches for the registered first to third terminals 300, or searches for the registered first to third terminals 300 through the user interface. A function that allows deletion can be provided. When registering the first to third terminals 300, the name of the target area equipped with the terminal (e.g., event name), the location of the entrance or exit where the terminal is installed, the serial number of the terminal, the model name of the terminal, and the name of the terminal. Device information such as firmware version can be matched and stored, and the user can search for a registered terminal using at least one of the device information. FIGS. 6B and 6C show an example of a user interface for registering, searching, and managing the first to third terminals 300.

The server 400 may provide a user interface for registration, search, and management of the target area. The server 400 may provide a function to register a target area, search a registered target area, or delete a registered target area through a user interface. When registering a target area, the user must provide the name of the target area (e.g., event name), the schedule of the target area (e.g., event start time and event end time), and the person in charge of the target area (e.g., event organizer). ), target area information, such as the progress status of the target area and the registration date of the target area, can be matched and stored, and the user can search for the registered target area using at least one of the target area information. Figures 6D and 6E show an example of a user interface for registering, searching, and managing a target area.

The server 400 may provide a user interface for managing visitors. As described above, in the database, the entry time, entry location, whether a mask is worn, body temperature, and exit time and location are matched to the facial image of the person entering the target area, and the server 400 refers to the database. For each person who entered the target area, an access list is created that records the entry time, entry location, whether or not a mask is worn, body temperature, and if the person leaves the room, the exit time and location are recorded, and the generated entry list can be output through the user interface. You can. Figure 6f shows an example of the visitor list.

The server 400 can output the calculated occupancy status information and the set access limit number through the user interface. Figure 6g shows an example of a user interface that outputs occupancy status information and the number of restricted people.

On the other hand, when a person entering the target area is not identified by the first terminal 100 or a person leaving the target area is not identified by the second terminal 200, the actual number of people entering, occupancy, or There may be cases where the number of people checking out is different from the number of people entering, staying, or checking out. To prepare for this, the server 400 may provide a user interface for modifying the calculated number of occupants, number of occupants, and number of occupants. Figure 6h shows an example of a user interface for modifying the number of occupants, the number of occupants, and the number of occupants.

Additionally, the server 400 may provide a user interface for changing the setting time required to determine whether resident identification information has been received in duplicate. Figure 6i shows an example of a user interface for changing the setting time.

Data received by the server 400 and data calculated by the server 400 may be stored in a database, and data stored in the database may be destroyed in preset time units (eg, 1 day).

As described above, the present invention can identify the number of occupants of a multi-use facility in real time and display the identified occupants at the entrance of the multi-use facility to guide users of the multi-use facility. In addition, the present invention sets a limited number of people in a multi-use facility based on the real-time infectious disease infection status, and displays the set limit at the entrance of the multi-use facility to guide users of the multi-use facility. In addition, the present invention can prevent the spread of infectious diseases by displaying the number of occupants and the limited number of people in the multi-use facility at the entrance of the multi-use facility to maintain the number of occupants in the multi-use facility at an appropriate level.

Figure 7 is a flowchart for explaining the process by which the occupancy management system outputs occupancy status information according to an embodiment of the present invention, and Figure 8 is a flowchart showing how the occupancy management system according to an embodiment of the present invention calculates occupancy status information. This is a flowchart for explaining the process, and Figure 9 is a flowchart for explaining the process by which the occupancy management system according to an embodiment of the present invention determines whether a person entering a target area has left the room.

Hereinafter, with reference to FIGS. 7 to 9, we will look at the process in which the occupancy management system outputs occupancy status information and the number of restricted people.

First, referring to FIG. 7, the server 400 can receive identification information of the person leaving the room and identification information of the person entering the room (step S100).

Subsequently, the server 400 may calculate occupancy status information for the target area based on the received identification information of the occupant and the identification information of the exiting occupant (step S200). Referring to FIG. 8, it is determined whether the person entering the target area has left the target area based on the occupant identification information and the exiting occupant identification information (step S210), and based on the determination result, the person staying in the target area is determined. The number of people can be calculated (step S220), and the calculated number of people can be used as occupancy status information (step S230). Referring to FIG. 9, when the exiting person identification information is received, the server 400 detects a facial image corresponding to the facial image included in the received exiting person identification information among the facial images stored in the database (step S211), It can be determined that the person corresponding to the detected facial image has left the room (step S212).

Referring again to FIG. 7, the server 400 may output the calculated occupancy status information through the third terminal 300 (step S300).

Figure 10 is a flowchart for explaining the process by which the server 400 outputs the number of people restricted from entering.

Hereinafter, with reference to FIG. 10, we will look at the process in which the occupancy management system according to an embodiment of the present invention outputs the number of people restricted from entering.

First, the server 400 can receive infectious disease infection status information and area information of the target area (step S400).

Next, the server 400 may determine the infectious disease spread level based on the number of infectious disease patients included in the input infectious disease infection status information (step S500).

Next, the server 400 may determine the number of people restricted from entering per unit area based on the determined infectious disease spread level (step S600).

Subsequently, the server 400 may set the restricted number of people based on the determined number of restricted people per unit area and the input area information of the target area (step S700).

Subsequently, the server 400 may output the set number of access restrictions along with occupancy status information (step S800).

Steps S400 to S800 may be performed before steps S100 to S300 or may be performed in parallel.

Figure 11 is a flowchart for explaining the process by which the occupancy management system outputs the available entry time according to an embodiment of the present invention.

Below, with reference to FIG. 11, we will look at the process by which the occupancy management system outputs the admission time.

First, the server 400 may determine whether the number of people determined to be present in the target area is greater than or equal to the number of access restrictions set for the target area (step S900).

If the number of people determined to be in the room is determined to be greater than the set access limit, the server 400 may calculate the occupancy time for each person determined to have left the target area (step S1000).

Next, the server 400 may average the calculated presence times to calculate the average presence time of the target area (step S1100).

Next, the server 400 may detect the entry time of the person who entered first among the people determined to be in the target area (step S1200).

Subsequently, the server 400 may calculate the entry time by adding the average occupancy time calculated in advance to the detected entry time (step S1300).

Subsequently, the server 400 may output the calculated entry time through the third terminal 300 (step S1400).

As described above, the occupancy management system according to an embodiment of the present invention determines the number of occupants of a multi-use facility in real time and displays the identified number of occupants at the entrance of the multi-use facility to guide users of the multi-use facility. You can. In addition, the present invention sets a limited number of people in a multi-use facility based on the real-time infectious disease infection status, and displays the set limit at the entrance of the multi-use facility to guide users of the multi-use facility. In addition, the present invention can prevent the spread of infectious diseases by displaying the number of occupants and the limited number of people in the multi-use facility at the entrance of the multi-use facility to maintain the number of occupants in the multi-use facility at an appropriate level.

Implementations described herein may be implemented, for example, as a method or process, device, software program, data stream, or signal. Although discussed only in the context of a single form of implementation (eg, only as a method), implementations of the features discussed may also be implemented in other forms (eg, devices or programs). The device may be implemented with appropriate hardware, software, firmware, etc. The method may be implemented in a device such as a processor, which generally refers to a processing device that includes a computer, microprocessor, integrated circuit, or programmable logic device. Processors also include communication devices such as computers, cell phones, portable/personal digital assistants (“PDAs”) and other devices that facilitate communication of information between end-users.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely illustrative, and those skilled in the art will recognize that various modifications and other equivalent embodiments can be made therefrom. You will understand. Therefore, the true technical protection scope of the present invention should be determined by the scope of the patent claims below.

100: first terminal
200: second terminal
300: Third terminal
400: server

Claims (9)

A first terminal that identifies a person entering the target area and generates occupant identification information;
a second terminal that identifies a person leaving the target area and generates exit identification information;
a third terminal provided at the entrance of the target area to output information; and
Receiving the occupant identification information and the occupant identification information from the first terminal and the second terminal, respectively, and calculating occupancy status information for the target area based on the received occupant identification information and the occupant identification information. And a server that outputs the calculated occupancy status information and the restricted number of people set in the target area through the third terminal,
The server determines the number of people residing in the target area and uses it as the occupancy status information,
The server calculates the average occupancy time of people determined to have left the target area when it is determined that the number of people determined to be occupancy is greater than the number of access restrictions set in the target area, and the calculated average occupancy time Calculate the entry time based on and output the calculated entry time through the third terminal,
The server detects the entry time of the person who entered first among the people determined to be in the target area, and calculates the available entry time by adding the calculated average occupancy time to the detected entry time. occupancy management system.
According to clause 1,
The occupant identification information includes a facial image and an entry time of the person entering the room, and the exiting occupant identification information includes a facial image and an exit time of the person leaving the room.
According to clause 2,
When the occupant identification information is received, the server stores the facial image included in the received occupant identification information in a database, and when the exiting occupant identification information is received, the server stores the received occupant identification information. An occupancy management system characterized by detecting a facial image corresponding to a facial image included in person identification information from the database and determining that the person corresponding to the detected facial image has left the room.
According to clause 3,
The server is an occupancy management system characterized in that the server determines that people who correspond to facial images stored in the database, excluding those who are determined to have left the room, are in the room.
delete According to clause 2,
The server calculates the occupancy time of each person who has checked out of the target area based on the check-out time included in the check-out person identification information and the check-in time included in the check-out person identification information, and the calculated occupancy time for each person An occupancy management system characterized in that the average occupancy time is calculated by averaging.
delete According to clause 1,
The server receives infectious disease infection status information and area information of the target area, and sets the restricted number of people based on the input infectious disease infection status information and area information of the target area.
According to clause 8,
The server determines the infectious disease spread level based on the real-time number of infectious disease patients included in the inputted infectious disease infection status information, determines the number of people restricted from entering per unit area based on the determined infectious disease spread level, and enters per unit area determined. An occupancy management system that sets the restricted number of people based on the limited number of people and the input area information of the target area.

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