JP2011070642A - Room-staying status decision server, room-staying status decision system, program, and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a room-staying status decision server capable of determining a room-staying status of a user more variously; and to provide a room-staying status decision system, a program and a recording medium. <P>SOLUTION: In the room-staying status decision system, a wireless tag reader is installed in a predetermined area, and outputs information indicating whether or not the wireless tag owned by the user is detected. A terminal device is installed in the area, has communication capability, and is employed by the user. A wireless tag management unit 12 of the room-staying status decision server 3 receives information outputted from the wireless tag reader, and determines whether or not the wireless tag is detected in the area on the basis of the information. A room-staying status decision unit 14 determines whether or not the room-staying status decision server 3 is communicable with the terminal device, and also determines the room-staying status of the user in the area based on both the result of this decision and the result of the decision by the wireless tag management unit 12. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an occupancy status determination server that determines the occupancy status of a user, an occupancy status determination system, a program, and a recording medium.

  In recent years, development of wireless tags for individually identifying articles has been activated. Originally, the wireless tag has been developed as a new product identification and management technology that replaces the barcode, but now it is not limited to this and is applied to various technical fields. Management targets are not limited to articles, but are also targeted at people. For example, in public transportation, the use of an entrance management card with a built-in wireless tag is rapidly progressing instead of a conventional ticket (commuter pass).

  As one of technologies for managing people using a wireless tag, development of a system for grasping on a computer where a person carrying the wireless tag is located is also underway. Using this system, for example, the location of employees in the company can be managed on a computer. It is also possible to grasp the status of users entering and leaving each room in the building. Patent Documents 1 to 6 disclose examples of such techniques.

  In particular, in the group information management system of Patent Document 1, when each terminal device on an in-house network receives and detects RFID transmitted from an RF-ID card held by each employee, the terminal device detects the detected RFID. The own terminal ID is notified to the theme information management server. Then, based on the data file stored and managed on the file server, the theme information management server displays the group-specific index screen in which each employee's name and location are arranged as a virtual desk for each employee. Display on the terminal device inside. The data file associates the RFID, the employee, the employee name, the affiliation group name, the notified employee current location terminal ID, and the location name for each terminal ID.

JP 2007-94988 A (publication date: April 12, 2007) JP 2006-339881 A (publication date: December 14, 2006) JP 2007-86922 A (publication date: April 5, 2007) JP 2006-283296 A (Publication date: October 19, 2006) JP 2007-107194 A (publication date: April 25, 2007) JP 2009-77354 A (publication date: April 9, 2009)

  However, the above-described prior art of Patent Document 1 has a problem that the occupancy status of each employee can be determined only by the choice of occupancy or absence. That is, when an RFID is detected, it is determined that the user is in the room, and when the RFID is not detected, it is merely determined that the user is absent.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an occupancy status determination server, an occupancy status determination system, a program, and a recording medium that can determine the occupancy status of a user in various ways. It is to provide.

In order to solve the above problems, the occupancy status determination server according to the present invention provides:
A wireless tag reader that is installed in a predetermined area and outputs information indicating whether or not a wireless tag possessed by the user has been detected, and a terminal that is installed in the area and has a communication function and is used by the user An occupancy status determination server provided with an occupancy status determination system including an apparatus for determining the occupancy status of the user in the area,
Detection determination means for receiving information output from the wireless tag reader and determining whether the wireless tag is detected in the area based on the information;
Communication determining means for determining whether or not the occupancy status determining server and the terminal device can communicate;
Based on a determination result by the detection determination unit and a determination result by the communication determination unit, an occupancy status determination unit that determines the occupancy status of the user in the area is provided.

  According to the above configuration, the occupancy status determination server uses the detection result in the area of the wireless tag possessed by the user when determining the occupancy status in the user's area. Furthermore, the result of determining whether or not the terminal device used by the user can communicate with the occupancy status determination server is also used. That is, the presence state in the user's area is determined by combining both. Thereby, the occupancy status determination server can further determine the occupancy status other than these in addition to the occupancy status such as whether the user is present or absent in the area.

  In the conventional system, only presence or absence can be determined. On the other hand, as described above, the occupancy status determination system of the present invention has an effect that the occupancy status in the user's area can be determined more variously.

In order to solve the above problems, the occupancy status determination system according to the present invention
An occupancy status determination system for determining a user's occupancy status in a predetermined area,
A wireless tag reader that is installed in the area and outputs information indicating whether or not the wireless tag possessed by the user has been detected;
A terminal device installed in the area, having a communication function, and used by the user;
An occupancy status determination server for determining the occupancy status of the user in the area;
The occupancy status determination server
Detection determination means for receiving information output from the wireless tag reader and determining whether the wireless tag is detected in the area based on the information;
Communication determining means for determining whether or not the occupancy status determining server and the terminal device can communicate;
Based on a determination result by the detection determination unit and a determination result by the communication determination unit, an occupancy status determination unit that determines the occupancy status of the user in the area is provided.

  According to said structure, there exists an effect similar to the occupancy status determination server mentioned above.

  The occupancy status determining means determines that the user is not in the area when the detection determining means determines that the wireless tag is not detected, and the communication determining means determines that communication with the terminal device is possible. It is preferable to determine that the person is away from.

  According to the above configuration, the wireless tag possessed by the user is not detected in the area, but the terminal device used by the user can communicate with the occupancy status determination server (that is, in operation). However, it is assumed that the terminal device is returned to the area to operate the terminal device again. Therefore, the occupancy status determination server determines that the user is temporarily away from the office on the assumption that the user will not be completely absent from the area but will return again after a certain period of time. To do.

  The occupancy status determination unit determines that the wireless tag is not detected by the detection determination unit, and the communication is performed when a time during which the terminal device and the occupancy status determination server cannot communicate exceeds a reference value. When determined by the determining means, it is preferable to determine that the user is absent from the area.

  According to said structure, since a user's radio | wireless tag is not detected in an area, it is guessed that a user is not in the said area first. Furthermore, when the time when the user's terminal device cannot communicate with the occupancy status determination server exceeds the reference value, the user can be regarded as not returning to the room again. For example, if the user shuts down the terminal device and returns home, the terminal device cannot communicate with the occupancy status determination server from then on, so the occupancy status determination server and the terminal device inevitably communicate with each other. The time when it cannot be exceeded the reference value. Therefore, the occupancy status determination server determines that the user has left the area.

  The occupancy status determination server determines that the wireless tag is not detected by the detection determination unit after the detection determination unit determines that the user is absent from the area, and When the communication determination means determines that the terminal device and the occupancy status determination server can communicate with each other, the information processing apparatus further includes notification means for notifying the user that the wireless tag has not been detected. preferable.

  According to the above configuration, when the user leaves the area for a long time with the terminal device activated and then returns, the user can be encouraged to carry the wireless tag. As a result, it is possible to prevent the user from being determined to be absent despite being in the area.

  Moreover, it is preferable that the notification means notifies the user that the wireless tag has not been detected when the current time is within a predetermined specific period.

  According to the above configuration, the user is not notified that the wireless tag has not been detected except for the predetermined specific period. Therefore, when the time other than the specific period is not an appropriate timing for notifying that the wireless tag is not detected, it is possible to prevent the user from being given unnecessary trouble.

  The occupancy status determination unit preferably determines that the user is in the area when the detection determination unit determines that the wireless tag is detected.

  According to the above configuration, regardless of whether or not the user terminal device communicates with the occupancy status determination server, since the wireless tag possessed by the user is detected in the area, the user is present in the area. It is determined that

  In addition, the communication determination unit transmits a response request signal to the terminal device, and whether or not the occupancy status determination server and the terminal device can communicate according to the presence or absence of a response signal to the response request signal. It is preferable to determine whether or not.

  According to said structure, it can be easily known whether an occupancy status determination server and a terminal device can communicate.

In addition, there are a plurality of users possessing the wireless tag,
It is preferable that the detection determination unit records a detection result in the area of the wireless tag held by the user for each user in a predetermined database.

  According to the above configuration, the occupancy status determination unit can use the database instead of the detection determination unit when acquiring the determination result by the detection determination unit. That is, the determination process by the occupancy status determination unit does not depend on the detection determination unit. Therefore, when another means for using the detection result of the wireless tag is additionally mounted on the occupancy status determination server, it is not necessary to separately provide a unique detection determination means, so that the other means can be easily additionally mounted. become.

  The occupancy status determination means preferably determines that the user is absent from the area when the detection result of the user is not recorded in the database within a predetermined specific period.

  According to said structure, it can prevent determining a user's occupancy condition accidentally with reference to the detection result produced | generated in the period which deviates from a predetermined specific period. For example, if the specific period is from 5:00 am on that day, the detection result of yesterday is not referred to. Therefore, if the user leaves the area with the terminal device activated yesterday and is not in the area the next day, the user is not in the area. It can be judged correctly.

In addition, there are a plurality of users possessing the wireless tag,
The occupancy status determination server preferably further includes display data transmission means for generating display data indicating the occupancy status in the area for each user and transmitting the data to a predetermined display terminal.

  According to said structure, the owner of the display terminal can grasp | ascertain each user's occupancy status by making a list on a screen.

The display data transmission means
When the occupancy status determination unit determines that the occupancy status in the area of any one of the plurality of users has changed from a status other than the occupancy status to an occupancy status, It is preferable to generate display data indicating that the process has returned to and transmit it to the display terminal.

  According to the above configuration, the owner of the display terminal can surely know that the user's occupancy status has changed to being present.

The wireless tag has a vibration detection function,
The wireless tag reader further outputs information indicating whether the wireless tag has detected vibration;
Preferably, the detection determination unit determines whether or not the wireless tag is detected, and also determines whether or not the wireless tag has detected the vibration.

  According to the above configuration, the occupancy status determination server further uses the vibration detection result by the wireless tag when determining the occupancy status of the user. Thereby, when determining that the user is present in the area, it is possible to distinguish and determine whether the user is present in a normal state or in an abnormal state.

  Further, the occupancy status determination means determines the number of times determined by the detection determination means when the wireless tag is detected and determined by the communication determination means that communication with the terminal device is possible within a specified time. If the user falls outside the prescribed range, it is preferable to determine that the user is in the area but is in an abnormal state.

  According to said structure, when a user does not operate normally in an area and the terminal device does not operate | move at all for a fixed time as a result, it can determine correctly that a user is in an abnormal state.

  The wireless tag is preferably an active type.

  According to the above configuration, the user who possesses the wireless tag does not need to bother to approach the wireless tag reader in a predetermined area.

  The occupancy status determination server may be realized by a computer. In this case, a program for realizing the occupancy status determination server in the computer by operating the computer as each of the above means and a computer-readable recording medium recording the program also fall within the scope of the present invention.

  As described above, the occupancy status determination server according to the present invention is installed in a predetermined area and outputs a wireless tag reader that outputs information indicating whether or not a wireless tag possessed by a user has been detected. An occupancy status determination server that is installed in an occupancy status determination system that has a communication function and is used by the user and that determines the occupancy status of the user in the area. , Receiving information output from the wireless tag reader and detecting whether or not the wireless tag is detected in the area based on the information, and the presence status determination server and the terminal device communicate with each other A communication determination unit that determines whether or not it is possible, the determination result by the detection determination unit, and the determination result by the communication determination unit; Because and a occupancy status determining means for determining occupancy status, an effect which can determine the occupancy status of the user more colorfully.

It is a figure which shows the whole structure of the occupancy status determination system which concerns on the 1st Embodiment of this invention. It is a block diagram which shows the principal part structure of the occupancy status determination server which concerns on the 1st Embodiment of this invention. (A) is a figure which shows a tag management table, (b) is a figure which shows a tag reader management table, (c) is a figure which shows a tag detection log | history management table. It is a flowchart which shows the flow of the occupancy status determination process which concerns on the 1st Embodiment of this invention. It is a figure which shows an apparatus management table. It is a figure which shows a Ping response log | history table. It is a state transition diagram which shows the transition of a user's occupancy status determined by an occupancy status determination part. It is a figure which shows an example of the screen showing a user's occupancy condition which a web client displays. It is the figure which showed notionally the structure of the occupancy status determination system. It is a figure which shows the whole structure of the occupancy status determination system which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows the flow of the process which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows the flow of a user's occupancy status determination process which concerns on the 3rd Embodiment of this invention. It is a figure which shows the final notification management table. It is a flowchart which shows the flow of a user's occupancy status determination process which concerns on the 4th Embodiment of this invention. It is a flowchart which shows the flow of a tag non-detection notification process. It is a figure which shows an example of the email which notifies that a wireless tag is undetected with respect to a user.

[Embodiment 1]
A first embodiment according to the present invention will be described below with reference to FIGS.

  The occupancy status determination system according to the present embodiment is used in an organization having at least one predetermined area, and manages the occupancy status of the user in the area. In the present embodiment, an example in which the organization corresponds to a company and the area corresponds to a room existing in the company building will be described. The occupancy status determination system 1 according to the present embodiment determines whether an employee (user) is present, absent, or temporarily away from a room in the company. As described above, if the occupancy status determination system is used, the occupancy status of the employee (user) in each room can be determined more variously than the conventional system.

(Configuration of occupancy status determination system 1)
FIG. 1 shows the overall configuration of a occupancy status determination system 1 according to the present invention. FIG. 1 is a diagram showing an overall configuration of an occupancy status determination system 1 according to a first embodiment of the present invention.

  As shown in this figure, the occupancy status determination system 1 includes an occupancy status determination server 3, a web client 4 (display terminal), a PC 6 (terminal device, display terminal), a hub 7, and a wireless tag reader 10. ing. The occupancy status determination server 3 and the web client 4 are arranged at an arbitrary place in the company that operates the occupancy status determination system 1. The web client 4 is mainly used by an administrator of the occupancy status determination system 1. On the other hand, the necessary number of PCs 6, hubs 7, and wireless tag readers 10 are arranged for each room 5.

  The user 8 according to the present embodiment corresponds to an employee of the company, and works in his / her own computer (PC 6) in a predetermined room 5. A PC 6 is prepared for each user 8, and the PC 6 used by each user 8 is determined in advance. Each room 5 has a seat for the user 8, and each user 8 sits in his / her seat and uses his / her PC 6. In this embodiment, the PC 6 is a so-called stationary desktop personal computer, but may be a notebook personal computer as long as it is a computer that can work on a desktop.

  The area is not limited to the room 5 shown in FIG. 1, and may be, for example, the entire company building (head office, branch office, or branch), a floor inside the company, and an in-house facility (dining room or coffee room) inside the company. The area may be a basement room. In other words, it may be an area that occupies a certain space, is accessible to the user 8, and is distinguished from other areas. The distinction between the areas is realized by the wireless tag reader 10 described later. For example, in FIG. 1, the physical range in which the wireless tag 9 can be detected by one wireless tag reader 10 corresponds to one area. However, a configuration in which a plurality of wireless tag readers 10 are installed in one area may be used.

  In each area 5, a PC 6, a hub 7 and a wireless tag reader 10 are arranged as necessary. The PCs 6 are not necessarily arranged in all the areas 5. For example, the PC 6 is not necessarily arranged in the area 5 where the PC 6 does not need to be arranged, such as a cafeteria. When the user 8 is not an employee but a visitor from the outside, the PC 6 of the user 8 is not arranged in the area 5.

  The occupancy status determination server 3 according to the present embodiment selects a determination method for the presence status of the user 8 in the area 5 according to the arrangement status of the PC 6 in each area 5. First, in the area 5 in which the PC 6 is arranged, the occupancy status of the user 8 is determined more variously than in the prior art as compared with the prior art. On the other hand, in the area 5 where the PC 6 is not arranged, the occupancy status of the user 8 is determined to the same extent as in the prior art. As described above, the occupancy status determination system 1a of the present invention can be mixed with the prior art.

  In the present embodiment, as shown in FIG. 1, an example in which the occupancy status determination system 1 is used in a company having three rooms 5 will be described. However, the number of rooms 5 is not limited to this, and may be arbitrary. Further, the number of PCs 6 in the room 5 is not limited to the example in FIG. In the present embodiment, since there are a plurality of rooms 5, there are also a plurality of PCs 6, hubs 7, and wireless tag readers 10. Further, there are a plurality of users 8 having the wireless tags 9.

  The occupancy status determination server 3, the web client 4, the hub 7, and the wireless tag reader 10 are all connected to the network 2. Further, all the PCs 6 arranged in a certain room 5 are respectively connected to a hub 7 arranged in the certain room 5 and can be connected to the network 2 via the hub 7. That is, each PC 6 can communicate with the occupancy status determination server 3 through the network 2.

  The PC 6 is a so-called business computer, has a communication function, and can communicate with the occupancy status determination server 3 while the power is on. Each PC 6 is assigned a unique IP address. The occupancy status determination server 3 identifies the communication partner PC 6 by the IP address assigned to the PC 6. As will be described in detail later, the occupancy status determination server 3 determines whether the PC 6 is in an operating state by detecting whether the PC 6 can communicate with the occupancy status determination server 3.

  In the occupancy status determination system 1 according to the present embodiment, the occupancy status of a plurality of users 8 is determined and managed for each user 8. All the users 8 always carry (carry) the wireless tag 9. Therefore, when the user moves, the wireless tag 9 moves accordingly. Each of the wireless tags 9 of the present embodiment is an active wireless tag. That is, the wireless tag 9 periodically transmits a wireless signal, and at this time, identification information (tag ID) for identifying itself is included in the wireless signal. The wireless tag reader 10 detects the wireless tag 9 by receiving the wireless signal transmitted from the wireless tag 9.

  Each wireless tag 9 transmits a wireless signal having sufficient strength to reach the wireless tag reader 10 in the room 5 regardless of where the user 8 is in the room 5. Accordingly, the user 8 does not have to approach the wireless tag reader 10 in order to cause the wireless tag reader 10 to detect the wireless tag 9 possessed by the user 8. That is, the user 8 can detect the wireless tag 9 possessed by the user 8 only by naturally acting in the room 5 without being aware of the presence of the wireless tag reader 10. The wireless tag 9 may be a passive type.

  In each room 5, the wireless tag 9 transmits the above-described wireless signal at regular time intervals. Thereby, the wireless tag reader 10 receives the wireless signal from the wireless tag 9 with a certain time interval. The detection range of the wireless signal by the wireless tag reader 10 is set in advance so as to roughly match the size of the room 5 in which the wireless tag reader 10 is installed. This prevents the wireless signal transmitted from the wireless tag 9 in the other room 5 from being erroneously detected by the other wireless tag reader 10 in the other room 5.

  The wireless tag reader 10 transmits information on the wireless tag 9 detected in the room 5 to the occupancy status determination server 3 through the network 2 at regular time intervals. An individual IP address is assigned to the wireless tag reader 10. As described above, the wireless signal transmitted from the wireless tag 9 includes identification information for specifying the wireless tag 9. Therefore, the wireless tag reader 10 associates its own IP address with the identification information for identifying the wireless tag 9 detected at a certain time, and transmits it to the occupancy status determination server 3.

(Configuration of occupancy status determination server 3)
The configuration of the occupancy status determination server 3 is shown in FIG. FIG. 2 is a block diagram showing a main configuration of the occupancy status determination server 3 according to the first embodiment of the present invention. As shown in this figure, the occupancy status determination server 3 includes a communication unit 11, a wireless tag management unit 12 (detection determination unit), a database 13, an occupancy status determination unit 14 (communication determination unit, occupancy status determination unit, Notification means) and a web page generation unit 15 (display data transmission means).

  An outline of each block provided in the occupancy status determination server 3 will be described. The communication unit 11 communicates with other devices connected to the occupancy status determination server 3 through the network 2. The wireless tag management unit 12 manages the detection result of the wireless tag 9 in each room 5. The database 13 stores various types of data in a table format. The occupancy status determination unit 14 determines the occupancy status of the user 8 in each room 5. The web page generation unit 15 generates a web page displayed by the web client 4. Details of these blocks will be described later.

(Example of table in database 13)
The occupancy status determination server 3 utilizes data in the table format in the database 13 when executing various processes to be described later. An example of a table stored in the database 13 is shown in FIG. 3A is a diagram showing a tag management table, FIG. 3B is a diagram showing a tag reader management table, and FIG. 3C is a diagram showing a tag detection history management table. As shown in FIG. 3, the database 13 mainly stores a table related to the detection result of the wireless tag 9. However, not only these tables but also the database 13 can store various tables required when each block in the occupancy status determination system 1 executes a predetermined process.

(Tag management table)
The tag management table shown in FIG. 3A stores identification information (tag ID) of the wireless tag 9 and name information of the user 8 who owns the wireless tag 9 in association with each other. The tag ID is identification information (an integer in this embodiment) uniquely assigned to each wireless tag 9. That is, each user 8 possesses a wireless tag 9 to which a unique tag ID is assigned. Accordingly, the occupancy status determination server 3 detects which radio tag 9 of the user 8 by referring to the tag management table using the value of the identification information (tag ID) included in the radio signal transmitted from the radio tag reader 10. You can know what was done.

(Tag reader management table)
The tag reader management table shown in FIG. 3B stores an IP address assigned to the wireless tag reader 10 and information indicating the installation location (room 5) of the wireless tag reader 10 in association with each other. This IP address takes a unique value among all the devices included in the occupancy status determination system 1. Further, as described above, when the wireless tag reader 10 of each room 5 transmits a signal including the detection result of the wireless tag 9 in the room 5, the unique IP address assigned to itself is included in the signal. . That is, in the signal output from the wireless tag reader 10, the detected tag ID of the wireless tag 9 and the IP address of the wireless tag reader 10 are associated with each other. Accordingly, the occupancy status determination server 3 refers to the tag reader management table using the value of the IP address in the signal transmitted from the wireless tag reader 10, and the tag detection result included in the transmitted signal indicates which room You can find out if it's in 5.

(Tag detection history management table)
The tag detection history management table shown in FIG. 3C includes identification information (tag ID) of the wireless tag 9, the IP address of the wireless tag reader 10 that has detected the wireless tag 9, the detection start time of the wireless tag 9, The detection end time of the wireless tag 9 and information indicating the detection state of the wireless tag 9 are stored in association with each other.

  As described above, each wireless tag reader 10 sends a signal including the detection result of the wireless tag 9 in the room 5 in which the wireless tag reader 10 is located through the network 2 to the occupancy status determination system 1. Send to. In the occupancy status determination system 1, the wireless tag management unit 12 receives the signal transmitted from the wireless tag reader 10 through the communication unit 11. The wireless tag management unit 12 analyzes the received signal, generates record information indicating whether or not the wireless tag 9 is detected by the wireless tag reader 10 at a certain time, and stores the record information in the database 13 as raw data. Therefore, the database 13 indicates whether or not each wireless tag 9 has been detected at a certain time for all the wireless tags 9 used in the occupancy status determination system 1 every time a certain time has elapsed. Raw data is accumulated.

  In the present embodiment, each wireless tag reader 10 counts itself and starts detection processing of the wireless tag 9 when a specified time has elapsed. Then, after the detection process is completed, a radio signal including the detection result of the wireless tag 9 is transmitted to the occupancy status determination server 3. On the other hand, the occupancy status determination server 3 passively processes a signal sent from the wireless tag reader 10 to accumulate raw data every time the specified time elapses.

  On the contrary, the wireless tag management unit 12 of the occupancy status determination server 3 actively counts the time by itself, and instructs the wireless tag reader 10 in each room 5 to detect the wireless tag 9 when a predetermined time has elapsed. A signal may be transmitted. In this case, each wireless tag reader 10 starts detection processing of the wireless tag 9 immediately after receiving the instruction signal.

(Data accumulation in the tag detection history management table)
The wireless tag management unit 12 analyzes the raw data accumulated in the database 13 to accumulate the detection history of the wireless tag 9 in the tag detection history management table shown in FIG. Specifically, if the wireless tag 9 is detected when the wireless tag 9 is in the non-detection state in the tag detection history management table, one record indicating the detection history of the wireless tag 9 is generated. , It is stored in the tag detection history management table.

  In the present embodiment, the wireless tag management unit 12 performs detection history accumulation processing every time new raw data is stored in the database 13. It should be noted that detection history accumulation processing can also be performed at the time when the storage of a certain number of raw data is completed.

  With reference to FIG. 3C as an example, a flow in which records are accumulated in the tag detection history management table will be described. First, since no record is stored in the tag detection history management table in the initial state, the detection state of any wireless tag 9 is “non-detection”. Here, the wireless tag management unit 12 is assigned the tag ID “0001” from the wireless tag reader 10 to which the IP address “xxx.xxx.xxx.xxx” is assigned at the time “11:11:10”. Assume that raw data indicating that the wireless tag 9 has been detected is stored.

  At this time, the wireless tag management unit 12 determines that the wireless tag 9 has changed from the non-detection state to the detection state by processing the raw data. As a result, the record in the first row is generated in the tag detection history management table. Specifically, the tag ID of the detected wireless tag 9, the IP address of the wireless tag reader 10 that detected the wireless tag 9, the time when the wireless tag 9 was detected (tag detection start time), and the detection state are shown. A record in which information (here “detection”) is associated with each other is generated. Since the detection of the wireless tag 9 has not been completed yet, the tag detection end time is blank (no data).

  Thereafter, the wireless tag management unit 12 is assigned a signal indicating that the wireless tag 9 to which the tag ID “0001” is assigned is detected, and the IP address “xxx.xxx.xxx.xxx” is assigned. It is periodically received from the wireless tag reader 10. That is, the detection of the wireless tag 9 is continued without ending. Therefore, the record in the first row of the tag detection history management table is not changed as it is.

  Here, the wireless tag management unit 12 is assigned the tag ID “0002” from the wireless tag reader 10 to which the IP address “yyy.yyy.yyy.yyy” is assigned at the time “01:01:00”. Assume that raw data indicating that the wireless tag 9 has been detected is stored. The wireless tag management unit 12 determines that the wireless tag 9 has changed from the non-detected state to the detected state by processing the raw data. As a result, the record in the second row is generated in the tag detection history management table. At this time, the tag ID of the detected wireless tag 9, the IP address of the wireless tag reader 10 that detected the wireless tag 9, the time when the wireless tag 9 was detected (tag detection start time), and information indicating the detection state ( Here, a record in which “detection”) is associated with each other is generated. Since the detection of the wireless tag 9 has not been completed yet, the tag detection end time is blank (no data).

  The wireless tag management unit 12 transmits a signal indicating that the wireless tag 9 to which the tag ID “0001” is assigned is detected as a wireless to which the IP address “xxx.xxx.xxx.xxx” is assigned. Still receiving from the tag reader 10 periodically. That is, the detection of the wireless tag 9 is continued without ending. Therefore, the record in the first row of the tag detection history management table is not changed as it is.

  Next, at the time “01:01:01”, the wireless tag management unit 12 is assigned the tag ID “0002” from the wireless tag reader 10 to which the IP address “yyy.yyy.yyy.yyy” is assigned. It is assumed that a signal indicating that the wireless tag 9 has been detected has not been received. At this time, the wireless tag management unit 12 stores raw data indicating that the wireless tag 9 has not been detected at the time in the database 13. The wireless tag management unit 12 determines that the detection of the wireless tag 9 is finished by processing the raw data, and in the record of the second row, the time “01:01: "01" is written, and the detection status column of the same record is changed from "detected" to "non-detected". By these processes, data (record) indicating the detection history of the wireless tag 9 is closed. That is, the record in the second row remains as a history in the tag detection history management table, and the content does not change any more.

  Next, at the time “01:01:10”, the wireless tag management unit 12 is assigned the tag ID “0002” from the wireless tag reader 10 to which the IP address “yyy.yyy.yyy.yyy” is assigned. Assume that raw data indicating that the wireless tag 9 has been detected is recorded in the database 13. At this time, the wireless tag management unit 12 specifies the tag ID of the detected wireless tag 9 by processing the raw data. Then, the latest record in which the identified tag ID “0002” is stored is retrieved from the records recorded in the tag detection history management table. Then, the value of the detection state column in the retrieved record is acquired.

  In the example of FIG. 3C, at this time, the wireless tag management unit 12 detects the record in the second row, and acquires “non-detection” as the value in the detection state column. Therefore, the wireless tag management unit 12 determines that the wireless tag 9 to which the tag ID “0002” is assigned has newly changed from the non-detected state to the detected state. Thereby, the record in the third row is generated as a new record in the tag detection history management table. Specifically, the tag ID of the detected wireless tag 9, the IP address of the wireless tag reader 10 that detected the wireless tag 9, the time when the wireless tag 9 was detected (tag detection start time), and the detection state are shown. A record in which information (here “detection”) is associated with each other is generated. Since the detection of the wireless tag 9 has not been completed yet, the tag detection end time is blank (no data).

  By repeating the above procedure, the wireless tag management unit 12 accumulates records in the tag detection history management table. In the example of FIG. 3C, records up to the fourth line are accumulated, and each record indicates a detection history of one of the wireless tags 9. That is, in the example of FIG. 3C, the wireless tag 9 assigned the tag ID “0001” and the wireless tag 9 assigned the tag ID “0002” Until the present time (the latest point in time when the wireless tag management unit 12 refers to the tag detection history management table), the detection continues. The wireless tag 9 to which the tag ID “0002” has been assigned has already been detected once, and its history remains in the tag detection history management table (record in the second row). On the other hand, according to the record in the fourth row, detection of the wireless tag 9 to which the tag ID “0003” is assigned is started at time “01:50:05” and at time “01:51:20”. It can be seen that the detection has ended.

  As will be described later, the occupancy status determination unit 14 refers to the tag detection history management table stored in the database 13, and obtains the detection result of the wireless tag 9 at a specific time (time) as the wireless tag 9. You can know every one.

(Flow of presence determination processing)
FIG. 4 shows a flow of processing for determining the occupancy status of the user 8 in the present embodiment. FIG. 4 is a flowchart showing the flow of the occupancy status determination process of the user 8 according to the first embodiment of the present invention. The occupancy status determination server 3 executes the process shown in FIG. 4 for each user 8 for all users 8 managed in the occupancy status determination system 1.

  As shown in FIG. 4, the occupancy status determination unit 14 first refers to the detection result of the wireless tag 9 possessed by the determination target user 8 from the tag detection history management table in the database 13 (step S1). At this time, the tag ID of the wireless tag 9 possessed by the determination target user 8 is specified by referring to the tag management table based on the name information of the user 8. Next, the value in the detection state column included in the latest record in which the identified tag ID is stored among the plurality of records accumulated in the tag detection history management table is referred to. Thereby, the detection result of the wireless tag 9 at a certain time (time) can be acquired.

  Next, the occupancy status determination unit 14 determines whether or not the wireless tag 9 is detected based on the value in the detection state column acquired from the tag detection history management table (step S2). Here, when the determination result in step S2 is “true” (Yes), that is, when the value of the detection state of the wireless tag 9 acquired from the tag detection history management table is “detection”, the occupancy status determination The unit 14 determines that the user 8 is present in the room 5 (step S3). At this time, it is determined that the user 8 is present in the room 5 because the wireless tag 9 that the user 8 always holds is detected in the room 5 regardless of the operating state of the PC 6 of the user 8.

  In the occupancy status determination system 1, “attended” and “occupied” are treated synonymously. That is, if the wireless tag 9 of the user 8 is detected in the room 5, the user 8 is regarded as being present or present in the room 5.

  Moreover, in this embodiment, when the occupancy status determination unit 14 can determine that the wireless tag 9 has been detected in any of the plurality of rooms 5, the user 8 is present in any of the rooms 5. judge. That is, when the wireless tag 9 of the user 8 is detected in the room 5 where the PC 6 used by the user 8 is not arranged, the user 8 is determined to be present.

  The occupancy status determination unit 14 is present in the room 5 only when the wireless tag 9 of the user 8 is detected in the room 5 in which the PC 6 used by the user 8 is arranged. May be determined. When making such a determination, the occupancy status determination unit 14 uses a predetermined device management table prepared in advance in the database 13. The device management table includes identification information (tag ID) that identifies each wireless tag 9, an IP address that identifies the PC 6 used by the user 8 who owns the wireless tag 9 identified by the tag ID, and the user 8 And the IP address of the wireless tag reader 10 placed in the same room 5 as the PC 6 used by is stored in association with each other. FIG. 5 is a diagram illustrating a device management table.

  The determination procedure is as follows. The occupancy status determination unit 14 acquires the tag ID of the wireless tag 9 and the IP address of the wireless tag reader 10 that detected the wireless tag 9 from the tag detection history management table. Then, it is confirmed whether or not both are associated with each other in the device management table shown in FIG. When the wireless tag 9 is associated, the wireless tag 9 has been detected by the wireless tag reader 10 disposed in the same room 5 as the PC 6 used by the user 8 who has the wireless tag 9. Accordingly, at this time, the occupancy status determination unit 14 can determine that the wireless tag 9 of the user 8 has been detected in the room 5 in which the PC 6 used by the user 8 is arranged among the plurality of rooms 5. 8 is determined to be present in the room 5.

  On the other hand, when the occupancy status determination unit 14 acquires from the tag detection history management table the tag ID of the wireless tag 9 and the IP address of the wireless tag reader 10 are not associated with each other in the device management table shown in FIG. The wireless tag 9 is detected in the room 5 where the PC 6 of the user 8 is not arranged. At this time, the occupancy status determination unit 14 can determine that the wireless tag 9 of the user 8 has not been detected in the room 5 in which the PC 6 used by the user 8 is arranged. Judge that it is not.

  Returning to FIG. 4, when the determination result in step S <b> 2 is “false” (No), that is, when the value of the detection state of the wireless tag 9 acquired from the tag detection history management table is “non-detection”. The wireless tag management unit 12 refers to the Ping response result for the PC 6 used by the user 8 (step S4).

(Role of Ping)
Here, the role of Ping (response request signal) in the occupancy status determination system 1 will be described below. The occupancy status determination unit 14 periodically transmits Ping to each PC 6 in each room 5 through the communication unit 11. As an example, 32-byte data (not including a header) is transmitted by specifying an IP address. Thereby, Ping is transmitted to the PC 6 to which the IP address is assigned.

  When each PC 6 receives the Ping transmitted from the occupancy status determination server 3 when the power is turned on and operates normally, the PC 6 immediately returns a response signal to the Ping. As a result, the occupancy status determination unit 14 receives a response to the transmitted Ping from the transmission destination PC 6.

  The occupancy status determination unit 14 stores the Ping response reception result transmitted for each PC 6 in one internal table in association with the IP address assigned to each PC 6. Hereinafter, this table is referred to as a Ping response history table. FIG. 6 is a diagram illustrating an example of the Ping response history table. As shown in this figure, the Ping response history table of this embodiment stores the IP address of the PC 6, the result of the response to Ping, and the transmission time of Ping in association with each other. The occupancy status determination unit 14 can determine whether or not there is a response to Ping at a certain time from the PC 6 to which the IP address is assigned by referring to the Ping response history table based on the IP address.

  In step S4, the occupancy status determination unit 14 refers to a Ping response result to the PC 6 of the user 8 who possesses the wireless tag 9 for which the presence or absence of detection has been determined (step S5). Here, the occupancy status determination unit 14 determines which of the PCs 6 (terminal devices) used by the user 8 who possesses a certain wireless tag 9 based on the tag ID of the wireless tag 9 as shown in FIG. It can be specified by referring to the management table. Therefore, by referring to the device management table shown in FIG. 5 and the Ping response history table shown in FIG. 6, the occupancy status determination unit 14 determines which PC 6 is used by the user 8 who owns the wireless tag 9. It is possible to determine whether or not the specified PC 6 has responded to Ping.

  When the result of the determination in step S5 is “true” (Yes), the occupancy status determination unit 14 determines that the user 8 is temporarily away from the room 5 (step S6). That is, the wireless tag 9 possessed by the user 8 is not detected in the room 5, but the PC 6 used by the user 8 responds to Ping (that is, is in operation). It is assumed that the user returns to the room 5 to operate again. Therefore, the occupancy status determination unit 14 is temporarily away from the office on the assumption that the user 8 is not completely absent from the room 5 but returns again after a certain time. Judge that.

  On the other hand, when the result of determination in step S5 is “false” (No), the occupancy status determination unit 14 refers to the time when the PC 6 did not respond to Ping (step S7). This no-response time can also be accurately determined from the above-described Ping response history table. Based on the value thus referred, the occupancy status determination unit 14 determines whether or not the time when the PC 6 has not responded to Ping exceeds a predetermined reference value (step S8).

  When the result of the determination in step S8 is “false” (No), the occupancy status determination unit 14 determines that the user 8 is temporarily away from the room 5 (step S6). That is, if the time when the PC 6 of the user 8 does not respond to Ping is equal to or less than a certain reference value, it is considered that the user 8 returns to the room 5 again. For example, it is assumed that the user 8 puts the PC 6 in the sleep mode and leaves the room 5 for a short rest, so even if the PC 6 does not respond to Ping, the non-response time is higher than the reference value. If it is too short, it is not determined that the user 8 has left the room 5.

  The reference value described above is appropriately set according to the type of the PC 6 and the usage pattern of the occupancy status determination system 1. For example, when the PC 6 is a notebook personal computer, the user 8 may take the PC 6 out of the room 5 and move toward another room 5 different from the room 5. During this movement, there occurs a time when the wireless tag 9 of the user 8 is not detected by any of the wireless tag readers 10 and the PC 6 of the user 8 does not respond to Ping. Therefore, it is desirable to consider such time when setting the reference value described above.

  On the other hand, when the result of the determination in step S8 is “true” (Yes), that is, when the time during which the PC 6 of the user 8 does not respond to Ping exceeds the reference value, the occupancy status determination unit 14 determines that the user 8 It is determined that the user has been absent from the room 5 (step S9). That is, when the time when the PC 6 of the user 8 does not respond to Ping exceeds a certain reference value, it is considered that the user 8 does not return to the room 5 again. For example, when the user 8 shuts down the PC 6 and returns home, the PC 6 does not respond to Ping from then on, and the ping non-response time inevitably exceeds the reference value. Therefore, the occupancy status determination unit 14 determines that the user 8 has left the room 5.

(State transition)
Further, the occupancy status determination unit 14 may determine the occupancy status of the user 8 according to the state transition diagram shown in FIG. FIG. 7 is a state transition diagram showing the transition of the occupancy status of the user 8 as determined by the occupancy status determination unit 14.

  As shown in this figure, when the presence status of the user 8 is “absent” and the wireless tag 9 possessed by the user 8 is detected in any of the rooms 5, the presence status of the user 8 is Transition to “Attendance”.

  Further, when the wireless tag 9 possessed by the user 8 is not detected in any room 5 when the user 8 is present in the room, the user 8 is present in the room. ”.

  Further, when the wireless tag 9 possessed by the user 8 is detected in any room 5 when the user 8's occupancy status is “seated”, the occupancy status of the user 8 is “present”. Transition to. When the wireless tag 9 of the user 8 is detected in the room 5 in which the PC 6 used by the user 8 is arranged among the plurality of rooms 5 instead of any one of the rooms 5, the state changes to “attended”. You may make it do.

  In addition, when the occupancy status of the user 8 is “separate” and the ping to the PC 6 used by the user 8 is interrupted for a certain period of time, the occupancy status of the user 8 transitions to “absence”. .

(Save judgment result)
The occupancy status determination unit 14 of the present embodiment stores the result of the occupancy status determined for each user 8 in the database 13 in association with information (name information) that identifies the user 8. For example, the name of the user 8, the occupancy status of the user 8 (present, absent, or away) and information indicating the room 5 in which the user 8 is present (name of the room 5) are stored in association with each other. To do. Here, the occupancy status determination unit 14 specifies the room 5 in which the user 8 is present as follows. First, the tag ID of the wireless tag 9 and the IP address of the wireless tag reader 10 stored in association with the tag ID are acquired from the tag detection history management table. The installation location of the wireless tag reader 10 is specified by referring to the tag reader management table based on the IP address. The installation location thus identified is the room 5 in which the user 8 having the wireless tag 9 detected by the wireless tag reader 10 is present.

(Operational effect of this embodiment)
As described above, in the occupancy status determination system 1 of the present embodiment, when determining the occupancy status of each user 8 in the room 5, the detection result of the wireless tag 9 possessed by the user 8 and the user 8 use it. It is used in combination with the Ping response result of PC6. Therefore, it can be determined that the user 8 is present, absent, or temporarily away from the room 5. Since the conventional system can only determine whether the user is present or absent, the occupancy status determination system 1 of the present embodiment has an effect that the occupancy status in the room 5 of the user 8 can be determined more variously. It is done.

(Display of occupancy status for each user 8)
As described above, the occupancy status determination server 3 determines the occupancy status of each user 8. By using this determination result, the administrator of the web client 4 can check the occupancy status of each user 8 in a list on the screen of the web client 4.

  Specifically, the web page generation unit 15 of the occupancy status determination server 3 generates a web page indicating the occupancy status in the room 5 for each user 8 and transmits the web page to the web client 4. The web client 4 is equipped with a web browser, and the web browser acquires the web page from the occupancy status determination server 3 and processes it.

  The web browser of the web client 4 periodically requests the occupancy status determination server 3 to provide the web page during startup. Such regular provision request processing is realized by a web browser processing a script described in a web page sent from the occupancy status determination server 3. Specifically, the web browser of the web client 4 transmits a request signal for the latest data of the web page to the occupancy status determination server 3 every time defined in the script in the web page elapses. The web page generation unit 15 of the occupancy status determination server 3 receives the request signal transmitted from the web client 4 through the communication unit 11. Then, every time the request signal is received, the occupancy status determination unit 14 is requested to provide the latest occupancy status determination result for each user 8.

  When the occupancy status determination unit 14 receives a request for providing the occupancy status determination result of each user 8 from the web page generation unit 15, the occupancy status determination unit 14 collectively acquires the occupancy status determination result for each user 8 stored in the database 13. To the web page generation unit 15. The web page generation unit 15 generates display data (web page) using the occupancy status determination result provided from the web page generation unit 15.

  In the present embodiment, the web page generation unit 15 generates a web page in HTML (Hyper Text Markup Language) format as display data, and transmits the web page to the web client 4 through the communication unit 11. The web client 4 receives the transmitted web page and displays a screen as shown in FIG. 8, for example. FIG. 8 is a diagram illustrating an example of a screen representing the occupancy status of each user 8 displayed by the web client 4.

  In the example of FIG. 8, the web client 4 displays a screen 81 indicating the occupancy status of each user 8. On the screen 81, the presence status of the user 8, the name of the user 8, the location where the user 8 is currently present (room), the contact information for the location (extension number), and the user 8 are away In the case of the user 8, the time (time) when the user is away, the group to which the user 8 belongs, the type of assignment in the work that the user 8 is working on, and the tag information related to the wireless tag 9 that the user 8 possesses, Each of them is displayed as a list. By visually recognizing such a screen 81, the administrator of the web client 4 can efficiently grasp the occupancy status of each user 8 in the company in real time.

  The format of the display data is not limited to the HTML format, and any format may be used as long as it is a format (for example, an image format) describing data for displaying some information.

(Notification of messages due to changes in occupancy status)
In the occupancy status determination server 3, the occupancy status determination unit 14 periodically determines the occupancy status of each user 8 and changes it to the latest value. Here, it is assumed that the occupancy status determination unit 14 determines that the occupancy status in the room 5 of any one of the plurality of users 8 has changed from a status other than the occupancy status to an occupancy status. At this time, the web page generation unit 15 generates display data indicating that the user 8 has returned to the room 5 and transmits the display data to the web client 4.

  In the present embodiment, the web browser of the web client 4 receives the display data and displays, for example, the screen 82 in FIG. The screen 82 includes a message indicating that the occupancy status of “Mr. F” among the plurality of users 8 has returned from being unattended to being present. Furthermore, the contact information (extension number) for contacting “Mr. F” is also included. Therefore, the administrator of the web client 4 can contact “Mr. F” immediately after viewing the screen 82.

  The web page generation unit 15 may transmit the above-described web page to each PC 6. In this case, each PC 6 also has the function of the web client 4. Therefore, the user 8 of the PC 6 can grasp the occupancy status of other employees (user 8) in the company as a list through the screen of the PC 6.

(Use of platform process)
FIG. 9 conceptually shows the configuration of the occupancy status determination system 1. FIG. 9 is a diagram conceptually showing the configuration of the occupancy status determination system 1.

  FIG. 9 shows n application processes, databases, platform processes, and RFID systems. The RFID system corresponds to a hardware part related to the wireless tag constituting the occupancy status determination system 1, and specifically corresponds to the wireless tag reader 10 and the wireless tag 9.

  Among the elements shown in FIG. 9, those excluding the RFID system constitute the occupancy status determination server 3. Specifically, the platform process corresponds to the wireless tag management unit 12. The database corresponds to the database 13. One of the n platform processes corresponds to the occupancy status determination unit 14.

  The platform process terminates the hardware part of the RFID system. That is, all data collected from the RFID system is input to the platform process. The platform process organizes the input data and stores it in the database as tag detection information. When an application process needs tag detection information, it acquires it from a database. Thus, there is no need for direct access to the RFID system.

  With the configuration as shown in FIG. 9, in the occupancy status determination server 3, the application process and the platform process operate completely independently. Therefore, when another application process using the tag detection information is additionally mounted on the occupancy status determination server 3 in which a certain application process is already mounted, another platform process specialized for the other application process is mounted. There is no need to add. That is, n application processes can share one platform process. Therefore, a new platform process can be easily added to the occupancy status determination server 3.

[Embodiment 2]
A second embodiment according to the present invention will be described below with reference to FIGS. 10 and 11. In addition, the same code | symbol is attached | subjected to each member which is common in 1st Embodiment mentioned above, and detailed description is abbreviate | omitted.

(Configuration of occupancy status determination system 1a)
FIG. 10 is a diagram showing an overall configuration of an occupancy status determination system 1a according to the second embodiment of the present invention. As shown in this figure, the components of the occupancy status determination system 1a are the same as those of the occupancy status determination system 1 according to the first embodiment. However, unlike the first embodiment, the occupancy status determination system 1a according to the present embodiment manages the occupancy status of the elderly in a predetermined living environment (for example, a house or a nursing home) instead of a company. . In this embodiment, an example applied to a nursing home will be described as an example.

  That is, the occupancy status determination system 1a of the present embodiment is applied to a nursing home 101 having two rooms 5, and manages the occupancy status of the user 8 (old man) in the room 5. The occupancy status determination server 3 is disposed in a predetermined management center away from the nursing home 101. The web client 4 is arranged in a house 102 away from the nursing home 101. In the house 102, there is a house member 104 of the user 8 (for example, a couple of elderly sons), and the occupancy status of the user 8 in the nursing home 101 is confirmed through the screen of the web client 4.

  The network 2 in the nursing home 101 is connected to the external Internet 103. The occupancy status determination server 3 and the web client 4 are also connected to the Internet 103. Accordingly, the occupancy status determination server 3 communicates with devices (PC 6, hub 7, wireless tag reader 10) in each room 5 in the nursing home 101 through the Internet 103 and the network 2. The web client 4 communicates with the occupancy status determination server 3 through the Internet 103.

  Moreover, the terminal device of this embodiment is various household appliances provided with the communication function. That is, in this embodiment, the home appliance 6 is arranged in the room 5 as a terminal device corresponding to the PC 6. As the home appliance 6, for example, a television device, a microwave oven, lighting, a fan, a stove, or the like can be used. Each of these devices has a so-called network communication function, like the PC 6. That is, any home appliance is connected to the network 2 and can receive a Ping transmitted from the occupancy status determination server 3 and send back a response signal to the Ping.

  In the present embodiment, the wireless tag 9 possessed by the user 8 (elderly person) has a vibration detection function. That is, the wireless tag 9 transmits a signal indicating whether vibration has been detected to the wireless tag reader 10. In addition to the information indicating whether or not the wireless tag 9 has been detected in the room 5, the wireless tag reader 10 in each room 5 further includes a signal including information indicating whether or not vibration has been detected. Is transmitted to the occupancy status determination server 3. In the database 13, the wireless tag management unit 12 further stores information indicating whether or not vibration is detected in association with information indicating whether or not each wireless tag 9 is detected. Thus, the occupancy status determination unit 14 further uses information indicating whether or not the wireless tag 9 has detected vibration when determining the occupancy status of the user 8. As a result, when the user 8 is present in the room 5, it can be further determined whether the state (physical condition or the like) of the user 8 is normal or abnormal.

  The occupancy status determination unit 14 periodically transmits Ping to the home appliance 6 through the communication unit 11. Thereby, the history of the presence or absence of a reply from the home appliance 6 with respect to the transmitted Ping is calculated and stored in the internal Ping response history table. Therefore, the occupancy status determination unit 14 can know how many times the home appliance 6 has replied to the transmitted Ping within a specified time.

  For example, it is determined that the wireless tag 9 of the user 8 is detected and vibration is also detected by the wireless tag 9. At this time, it is further assumed that there are a number of Ping replies within the specified range within the specified time. The specified time and the specified range described above are appropriately set according to the type of home appliance 6 and the operation mode of the occupancy status determination system 1a. For example, it is assumed that the specified time is one day and the number of times within the specified range is 3 to 5. Then, it is assumed that the number of ping replies of the home appliance 6 (assumed to be a television) detected by the occupancy status determination unit 14 is three times a day. In this case, it can be considered that the user 8 turned on the television three times in one day and watched the television program. Therefore, the occupancy status determination unit 14 determines that the user 8 is in the room 5 and is operating normally.

  Conversely, if the number of Ping replies deviates from the specified range within a specified time, the occupancy status determination unit 14 determines that the state of the user 8 is abnormal. In the above-described example, when the number of Ping replies is 0 or 10 in one day, the number of ping replies deviates from the prescribed range within the prescribed time. In the former case, it can be seen that although the user 8 is in the room 5, the TV is not turned on at all. On the other hand, in the latter case, the user 8 knows that the TV is turned on all day. Therefore, in any case, the occupancy status determination unit 14 can determine that the user 8 is in the room 5 but is in an abnormal state.

(Flow of presence determination processing)
FIG. 11 shows a flow of processing for determining the occupancy status of the user 8 in the present embodiment. FIG. 11 is a flowchart showing a flow of processing according to the second embodiment of the present invention.

  As shown in this figure, first, the occupancy status determination unit 14 refers to the tag detection result of the user 8 from the tag detection history management table in the database 13 (step S11). Next, it is determined whether or not the wireless tag 9 of the user 8 is detected in the room 5 (step S12). Here, when the result of the determination in step S12 is “false” (No), the occupancy status determination unit 14 determines that the user 8 is absent from the room 5 (step S13).

  On the other hand, when the result of the determination in step S12 is “true” (Yes), the occupancy status determination unit 14 determines whether or not the wireless tag 9 is a vibration detection type (step S14). In the present embodiment, information indicating whether or not the wireless tag 9 is a vibration detection type is included in the tag management table in the database 13, and therefore determination is made by referring to this information.

  When the result of the determination in step S14 is “false” (No), the occupancy status determination unit 14 skips the determination of step S15 and executes the process of step S17. On the other hand, when the result of the determination in step S14 is “true” (Yes), the occupancy status determination unit 14 determines whether or not the wireless tag 9 detects vibration (step S15).

  When the determination result in step S15 is “false” (No), the occupancy status determination unit 14 determines that the user 8 is in the room 5 and is in an abnormal state (step S16). . When the user 8 is performing some activity in the room 5, the movement of the user 8 is transmitted as vibration to the wireless tag 9, so the wireless tag 9 should detect the vibration. Therefore, when the presence of the wireless tag 9 is detected but the vibration is not detected, the occupancy status determination unit 14 is in the room 5 but is in a normal activity. It can be determined that there is no abnormal condition.

  On the other hand, when the result of the determination in step S15 is “true” (Yes), the occupancy status determination unit 14 refers to the Ping response result of the user 8 to the home appliance 6 (step S17). Since this result is recorded in advance in the internal table of the occupancy status determination unit 14, the table is referred to. Next, based on this reference result, the occupancy status determination unit 14 determines whether or not the home appliance 6 has responded to Ping within a specified time (step S18).

When the result of the determination in step S18 is “false” (No), that is, when it is determined that the home appliance 6 has not responded to Ping within the specified time, the occupancy status determination unit 14 determines whether the user 8 Is present in the room 5 but is in an abnormal state (step S16).
On the other hand, when the result of the determination in step S18 is “true” (Yes), the occupancy status determination unit 14 calculates the number of times that the home appliance 6 of the user 8 responds to Ping within a specified time from the internal table. Reference is made (step S19). Next, it is determined whether or not the number of Ping responses referred to in this way is a number within a specified range within a specified time (step S20).

  When the result of the determination in step S20 is “false” (No), the occupancy status determination unit 14 determines that the user 8 is in the room 5 but is in an abnormal state (step S16). On the other hand, when the result of the determination in step S20 is “true” (Yes), the occupancy status determination unit 14 determines that the user 8 is in the room 5 and is in a normal state (step) S21).

  As described above, in the occupancy status determination system 1a according to the present embodiment, when it is determined that the user 8 is occupying the room 5, the occupancy status can be determined in more detail. Therefore, the occupancy status can be determined more variously than the conventional system.

[Embodiment 3]
A third embodiment according to the present invention will be described below with reference to FIG. In addition, the same code | symbol is attached | subjected to each member which is common in 1st Embodiment mentioned above, and detailed description is abbreviate | omitted.

(Outline of this embodiment)
In the present embodiment, the configuration of the system is the same as the configuration of the occupancy status determination system 1 according to the first embodiment. However, the occupancy status determination system 1 of the present embodiment executes the processing shown in FIG. As a result, even if the user 8 returns home with the PC 6 activated, if the user 8 is absent on the next day, it can be determined that the user 8 is not absent, rather than erroneously determined to be away.

  FIG. 12 shows a flow of processing for determining the occupancy status of the user 8 in the present embodiment. FIG. 12 is a flowchart showing the flow of the occupancy status determination process of the user 8 according to the third embodiment of the present invention. The occupancy status determination server 3 executes the process shown in FIG. 12 for each user 8 for all users 8 managed in the occupancy status determination system 1.

  In FIG. 12, the process from step S1 to S9 is the same as the process from step S1 to S9 shown in FIG. However, in the present embodiment, the occupancy status determination unit 14 executes the process of step S31 before executing the process of step S1. Specifically, it is determined whether or not a record indicating the detection history of the wireless tag 9 of the user 8 generated in a predetermined specific period exists in the tag detection history management table in the database 13.

  When the result of the determination in step S31 is “true” (Yes), the occupancy status determination server 3 next executes the process of step S1. On the other hand, when the result of the determination in step S31 is “false” (No), next, the process of step S9 is executed. That is, it is determined that the user 8 is absent from the room 5.

(About a specific period)
Here, the predetermined specific period is a period for checking whether or not the record (information indicating the detection result of the wireless tag 9) of the user 8 for which the occupancy status is determined is generated in the tag detection history management table. That is. In the occupancy status determination server 3 of the present embodiment, a value indicating a specific period is stored in advance in a predetermined memory, and this value is read from the memory and used.

  The specific period can be arbitrarily determined by the designer of the occupancy status determination system 1. Alternatively, the manager of the occupancy status determination server 3 can appropriately set according to the status during the operation of the occupancy status determination system 1. It may be set so that both the start time and end time of a specific period are fixed values, or the initial time is a fixed value, but the end time is a dynamic value (for example, the current time) It may be set.

  In the present embodiment, the specific period is a period from 5:00 am or later on that day until the current time (the time when the occupancy status of the user 8 is determined). For example, if the current time is 10 am, 5 hours from 5 am to 10 am is the specific period.

(Details of effects)
The reason why the effect of this embodiment can be obtained will be described in more detail below.

  The user 8 has been working yesterday, but has forgotten to shut down the PC 6 or has intentionally continuously operated to return home with the PC 6 running. And the next day is not working. At this time, since the PC 6 continues to be activated until the next day, it continues to send Ping to the occupancy status determination server 3 at regular intervals. On the other hand, since the user 8 is working yesterday (assuming that the wireless tag 9 is correctly carried), a record indicating the detection history of the wireless tag 9 is always generated in the tag detection history management table at a certain point in time yesterday. ing. Further, near the time when the user 8 returns home, a value is written in the “tag detection end time” in the record, and the detection result is “non-detection”.

  Therefore, the record of the user 8 has not been generated in the tag detection history management table from the specific time, that is, from 5 am on that day to the present time. Thereby, since the determination result of step S31 of FIG. 12 becomes “false”, the occupancy status determination unit 14 determines that the user 8 is not in the room 5 in step S9.

  If the determination in step S1 is made suddenly without making the determination in step S31, the following problem may occur. That is, the occupancy status determination unit 14 determines that the wireless tag 9 of the user 8 has not been detected with reference to the record of the user 8 generated in the tag detection history management table yesterday. Further, since it is determined in step S5 that the PC 6 of the user 8 is responding to Ping, the user 8 leaves the room 5 in step S6 even though the user 8 is not at work. If you are doing it, you will make a mistake. In the present embodiment, such a problem is prevented in advance by executing the process of step S31.

[Embodiment 4]
A fourth embodiment according to the present invention will be described below with reference to FIGS. In addition, the same code | symbol is attached | subjected to each member which is common in 1st Embodiment mentioned above, and detailed description is abbreviate | omitted.

(Outline of this embodiment)
In the present embodiment, the configuration of the system is the same as the configuration of the occupancy status determination system 1 according to the first embodiment. However, when the user 8 does not carry the wireless tag 9 after coming to the office, the occupancy status determination system 1 of the present embodiment can notify the user 8 of the fact and prompt the user to carry the wireless tag 9. Such a process is realized by the occupancy status determination server 3 using the final notification management table shown in FIG. FIG. 13 is a diagram showing a final notification management table.

  The final notification management table includes identification information (tag ID) of the wireless tag 9 and information indicating the date when the wireless tag 9 was last detected to the user 8 who owns the wireless tag 9. This is a table stored for each wireless tag 9.

  The occupancy status determination server 3 uses this final notification management table to execute processing for determining the occupancy status of the user 8 shown in FIG. FIG. 14 is a flowchart showing the flow of the occupancy status determination process of the user 8 according to the fourth embodiment of the present invention. The occupancy status determination server 3 executes the process shown in FIG. 14 for every user 8 for all users 8 managed in the occupancy status determination system 1.

  In FIG. 14, the processes from Steps S1 to S4 and S6 to S9 are the same as the processes from Steps S1 to S4 and S6 to S9 shown in FIG. However, in this embodiment, when the occupancy status determination unit 14 determines in step S5 that the PC 6 of the user 8 is responding to Ping (Yes), the user 8 is immediately away from the room 5. Instead of determining, a tag non-detection notification process shown in step S41 is executed.

(Tag non-detection notification process)
FIG. 15 is a flowchart showing the flow of the tag non-detection notification process. As shown in this figure, the occupancy status determination unit 14 first determines whether or not the status of the occupancy status of the user 8 is absent (step S51). When the result of the determination in step S51 is “false” (No), the occupancy status determination unit 14 determines that the user 8 is away (step S52).

  On the other hand, when the result of the determination in step S51 is “true” (Yes), the occupancy status determination server 3 determines whether or not the current time is within a predetermined specific period (step S52).

(About a specific period)
The specific period in the present embodiment is an appropriate period for notifying the user 8 that the wireless tag 9 has not been detected. In the occupancy status determination server 3 of the present embodiment, a value indicating a specific period is stored in advance in a predetermined memory, and this value is read from the memory and used. The specific period can be arbitrarily determined by the designer of the occupancy status determination system 1. Alternatively, the user of the occupancy status determination server 3 can appropriately set according to the situation while the occupancy status determination system 1 is operating.

  In the present embodiment, the specific period is a period from 9 am to 10 am. This period is determined on the assumption that the user 8 works by using the flextime system.

  When the result of the determination in step S52 is “false” (No), the processing shown in FIG. 15 ends. This is because the current time is not an appropriate time zone for notifying the user 8 that the wireless tag 9 has not been detected.

  On the other hand, when the result of the determination in step S is “true” (Yes), the occupancy status determination server 3 refers to the final notification management table and sets the tag possessed by the user 8 who is the occupancy status determination target. The date of the last notification that the wireless tag 9 has not been detected for the user 8 is recorded (step S54). Then, it is determined whether or not the date confirmed at this time (that is, the last notification date) is different from the current date (step S55).

  When the result of the determination in step S55 is “false” (No), the processing shown in FIG. 15 ends. Thereby, when the last date which notified the user 8 that the wireless tag 9 has not been detected is equal to the current date, the same notification can be prevented from being issued twice on the same day.

  On the other hand, when the result of the determination in step S56 is “true” (Yes), the occupancy status determination unit 14 informs the user 8 that the wireless tag 9 has not been detected, and thereby the wireless tag 9 Is not detected (step S56).

  At this time, the user 8 may be notified in some form. For example, notification may be made by transmitting an e-mail to the PC 6 of the user 8 through the communication unit 11 (FIG. 16). FIG. 16 is a diagram illustrating an example of an e-mail that notifies the user 8 that the wireless tag 9 has not been detected. Alternatively, the web page generation unit 15 may generate a web page including a message notifying that the wireless tag 9 has not been detected and transmit the web page to the PC 6 of the user 8. How to notify can be set in advance by the designer of the occupancy status determination system 1 or the administrator of the occupancy status determination server 3.

  After the notification process, the occupancy status determination unit 14 records the final date of notification that the wireless tag 9 has not been detected, which is recorded for the wireless tag 9 possessed by the user 8 in the final notification management table. The current date is updated (step S57). This process makes it possible to issue the notification only once a day. As a result, it is not necessary to give the user 8 the trouble of receiving the same notification many times on the same day.

(Details of effects)
The reason why the effect of this embodiment can be obtained will be described in more detail below.

  Since the user 8 returned home yesterday, the occupancy status determination server 3 determines that the occupancy status of the user 8 is absent at that time. This condition continues until the next morning. The user 8 works today and activates the PC 6 to work, but forgets to carry the wireless tag 9. At this time, the determination result of the occupancy status of the user 8 is still absent.

  Here, the occupancy status determination server 3 can notify the user 8 that the wireless tag 9 has not been detected through the process of FIG. 15 and prompt the user 8 to carry the wireless tag 9. As a result, if the user 8 carries the wireless tag 9, the wireless tag 9 of the user 8 is detected in the process of FIG. 14 after a certain period of time. Can be determined. As a result, it is possible to prevent the user 8 from continuing to erroneously determine that he / she is absent despite going to work.

(Advantages of setting a specific period)
The phenomenon that can occur when the specific period is not set as described above and the advantages that can be obtained when the specific period is set are described in detail below.

  Assume a situation in which the occupancy status determination system 1 is constructed at both a head office and a branch office of a company. The user 8 carries a portable computer (such as a notebook computer) as the PC 6.

  The user 8 belongs to a branch office and usually works at the branch office. In the morning of one day, carry the wireless tag 9 and go to the branch office as usual. Therefore, the branch office does not notify the branch office occupancy status determination server 3 that the wireless tag 9 has not been detected.

  On the afternoon of that day, the user 8 moves with the PC 6 for a meeting at the head office while carrying the wireless tag 9. While moving to the head office, the wireless tag 9 is not detected, and the PC 6 does not respond to Ping. Therefore, if the moving time exceeds a certain time and, as a result, the non-response time of Ping exceeds the reference value, it is determined that the user 8 is absent. The same applies to both the branch office and the head office.

  The user 8 arrives at the head office and uses the PC 6 connected to the in-house LAN of the head office for a meeting. As a result, the PC 6 of the user 8 responds to the Ping transmitted from the occupancy status determination server 3 in the head office. On the other hand, it is assumed that the wireless tag 9 of the user 8 can be detected correctly by the wireless tag reader 10 of the branch office, but cannot be detected correctly because the wireless tag reader 10 of the head office does not conform to the specification. In this case, the wireless tag 9 of the user 8 is not detected at the head office.

  In the above situation, the occupancy status determination server 3 at the head office determines “No” in step S2 of FIG. 14 and determines “Yes” in step S5 of FIG. As a result, the tag non-detection notification process of FIG. 15 is executed. Since there is no specific period setting, the process of step S55 is skipped, and the process of step S56 is always executed. As a result, the user 8 who is in a meeting is notified that the wireless tag 9 has not been detected.

  In the above example, the user 8 is notified that the wireless tag 9 has not been detected in the afternoon even though the wireless tag 9 was carried at least in the morning. Therefore, the user 8 feels such a notification bothersome.

  In view of the above phenomenon, the significance of setting the specific period is understood. That is, if a tag non-detection notification to the user 8 is performed when the current time is within a certain period (9 am to 10 am in the present embodiment), the tag is given to the user 8 outside the certain period. There is no notification of non-detection. Therefore, as in the above-described example, when the time other than the specific period is not an appropriate timing for notifying the user 8 that the wireless tag 9 has not been detected, an unnecessary trouble is caused to the user 8. Can be prevented. In addition, when the occupancy status determination system 1 is operated by a company organization, if a specific period is set as a work time zone and notification is made immediately after the user 8 works, the user 8 is encouraged to carry the wireless tag 9. The maximum effect is obtained.

  Even with such a device, the following minor problems can occur. For example, it is assumed that the user 8 goes to the head office at 9:00 in the morning, correctly carries the wireless tag 9, and immediately connects the PC 6 to the in-house LAN. In this case, the wireless tag 9 of the user 8 is not detected by the wireless tag reader 10 at the head office, while the PC 6 responds to the Ping transmitted from the occupancy status determination server 3 at the head office. Therefore, the occupancy status determination server 3 at the head office notifies the user 8 that the wireless tag 9 has not been detected. However, since the original work location of the user 8 is a branch office, he can be convinced that he can't help receiving notification because he is at the head office today. Moreover, since there is a possibility that such notification is received only within a specific period (1 hour in the present embodiment), the extent to which the user 8 feels troublesome is relatively small. It will not be a big problem.

(Additional notes)
The present invention is not limited to the above-described embodiments. Those skilled in the art can make various modifications to the present invention within the scope of the claims. That is, a new embodiment can be obtained by combining appropriately changed technical means within the scope of the claims.

  For example, the occupancy status determination system 1 can be used not only in the above-described company and home but also in a certain scale organization (for example, a hospital and a school) having a certain number of personnel.

  The occupancy status determination unit 14 may use another method instead of the above-described ping transmission when determining whether the occupancy status determination server 3 and the PC 6 can communicate with each other. For example, a predetermined response request signal other than Ping may be transmitted to the PC 6.

  Further, in the occupancy status determination system 1, in addition to the determination of the occupancy status of the user 8 as an employee described above, the occupancy status of the visitor can also be determined. For example, when the organization that uses the occupancy status determination system 1 is a factory, in addition to managing the occupancy status of employees in a building on the site, the presence / absence of visitors outside the building on the site (for example, the ground) is managed. This is the case. In this case, since no employee is present on the ground, the PC 6 is not arranged, but the wireless tag reader 10 is arranged. The visitor carries the wireless tag 9 with him / her. As a result, the presence status of the user 8 in the room 5 is not determined in various ways, but the presence / absence of a visitor can be determined even in the ground.

  Further, the occupancy status determination system 1 manages the Ping response history of each PC 6 arranged in each room 5 in the internal table of the occupancy status determination unit 14. Therefore, the operating status of each PC 6 in each room 5 can be calculated using the Ping response history. Therefore, by disclosing the operation status calculated in this way to the user 8 of the PC 6, the user 8 can increase the awareness of energy saving, for example, by the user 8 considering whether there is any unnecessary operation time. The effect can be obtained.

  Further, the occupancy status determination system 1 can know the detection history of the wireless tag 9 possessed by each user 8 by using the tag detection history management table shown in FIG. Therefore, the daily presence time of each user 8 can be calculated by using the tag detection history for each user 8. Thereby, the occupancy status determination system 1 can also manage the physical condition of each user 8 based on the calculated occupancy time. The calculated attendance time for each user 8 can also be used as a guideline at which timing each user 8 should have a health checkup.

(Program and recording medium)
Finally, each block included in the occupancy status determination server 3 may be configured by hardware logic. Alternatively, it may be realized by software using a CPU (Central Processing Unit) as follows.

  That is, the occupancy status determination server 3 includes a CPU that executes instructions of a program that realizes each function, a ROM (Read Only Memory) that stores the program, and a RAM (Random Access Memory) that expands the program into an executable format. And a storage device (recording medium) such as a memory for storing the program and various data. With this configuration, the object of the present invention can be achieved by a predetermined recording medium.

  The recording medium only needs to record the program code (execution format program, intermediate code program, source program) of the program of the occupancy status determination server 3 which is software for realizing the above-described functions so as to be readable by the computer. This recording medium is supplied to the occupancy status determination server 3. Thus, the occupancy status determination server 3 (or CPU or MPU) as a computer may read and execute the program code recorded on the supplied recording medium.

  The recording medium that supplies the program code to the occupancy status determination server 3 is not limited to a specific structure or type. That is, the recording medium includes, for example, a tape system such as a magnetic tape and a cassette tape, a magnetic disk such as a floppy (registered trademark) disk / hard disk, and an optical disk such as a CD-ROM / MO / MD / DVD / CD-R. System, a card system such as an IC card (including a memory card) / optical card, or a semiconductor memory system such as a mask ROM / EPROM / EEPROM / flash ROM.

  Further, even if the occupancy status determination server 3 is configured to be connectable to a communication network, the object of the present invention can be achieved. In this case, the program code is supplied to the occupancy status determination server 3 via the communication network. This communication network is not limited to a specific type or form as long as it can supply the program code to the occupancy status determination server 3. For example, it may be the Internet, intranet, extranet, LAN, ISDN, VAN, CATV communication network, virtual private network, telephone line network, mobile communication network, satellite communication network, and the like.

  The transmission medium constituting the communication network may be any medium that can transmit the program code, and is not limited to a specific configuration or type. For example, wired communication such as IEEE 1394, USB (Universal Serial Bus), power line carrier, cable TV line, telephone line, ADSL (Asymmetric Digital Subscriber Line) line, infrared rays such as IrDA and remote control, Bluetooth (registered trademark), 802.11 It can also be used by radio such as radio, HDR, mobile phone network, satellite line, terrestrial digital network. The present invention can also be realized in the form of a computer data signal embedded in a carrier wave in which the program code is embodied by electronic transmission.

  INDUSTRIAL APPLICABILITY The present invention can be widely used as a system for managing the location (in-room situation) of employees in the company.

1, 1a Occupancy status determination system 2 Network 3 Occupancy status determination server 4 Web client (display terminal)
5 rooms 6 PCs, home appliances (terminal devices, display terminals)
7 hub 8 user 9 wireless tag 10 wireless tag reader 11 communication unit 12 wireless tag management unit (detection determination means)
13 database 14 occupancy status determination unit (communication determination means, occupancy status determination means, notification means)
15 Web page generator (display data transmission means)
101 retirement home 102 home 103 internet 104 home

Claims (17)

A wireless tag reader that is installed in a predetermined area and outputs information indicating whether or not a wireless tag possessed by the user has been detected, and a terminal that is installed in the area and has a communication function and is used by the user An occupancy status determination server provided with an occupancy status determination system including an apparatus for determining the occupancy status of the user in the area,
Detection determination means for receiving information output from the wireless tag reader and determining whether the wireless tag is detected in the area based on the information;
Communication determining means for determining whether or not the occupancy status determining server and the terminal device can communicate;
An occupancy status determination server comprising: an occupancy status determination unit that determines the occupancy status of the user in the area based on a determination result by the detection determination unit and a determination result by the communication determination unit. .   When the presence determination unit determines that the wireless tag is not detected by the detection determination unit, and determines that the communication determination unit determines that communication with the terminal device is possible, the user determines from the area 2. The occupancy status determination server according to claim 1, wherein it is determined that the user is away.   The presence determination unit determines that the wireless tag is not detected by the detection determination unit, and the communication determination is performed when a time during which the terminal device and the presence determination server cannot communicate exceeds a reference value. 3. The occupancy status determination server according to claim 1, wherein, when determined by means, it is determined that the user is absent from the area.   After the detection determination unit determines that the user is absent from the area, the detection determination unit determines that the wireless tag is not detected, and the terminal device and the occupancy status determination server The apparatus further comprises notification means for notifying the user that the wireless tag has not been detected when it is determined by the communication determination means that communication is possible. The occupancy status determination server according to any one of the above.   The occupancy status according to claim 4, wherein the notification means notifies the user that the wireless tag has not been detected when the current time is within a predetermined specific period. Decision server.   6. The occupancy status determination unit determines that the user is occupying the area when the detection determination unit determines that the wireless tag has been detected. The occupancy status determination server according to claim 1.   The communication determination means transmits a response request signal to the terminal device, and determines whether the occupancy status determination server and the terminal device are communicable according to the presence / absence of a response signal to the response request signal. It determines, The occupancy status determination server of any one of Claims 1-6 characterized by the above-mentioned. There are a plurality of users possessing the wireless tag,
8. The detection determination unit according to any one of claims 1 to 7, wherein the detection determination unit records a detection result in the area of the RFID tag held by the user for each user in a predetermined database. The occupancy status determination server described.   The occupancy status determination means determines that the user is absent from the area when the detection result of the user is not recorded in the database within a predetermined specific period. 8. The occupancy status determination server according to 8. There are a plurality of users possessing the wireless tag,
The occupancy status determination server further includes display data transmission means for generating display data indicating the occupancy status in the area for each user and transmitting the generated data to a predetermined display terminal. Item 10. The occupancy status determination server according to any one of items 1 to 9.   The display data transmission means is determined by the occupancy status determination means that the occupancy status in the area of any one of the plurality of users has changed from a non-occupancy status to an occupancy status. 11. The occupancy status determination server according to claim 10, wherein display data indicating that the user has returned to the area is generated and transmitted to the display terminal. The wireless tag has a vibration detection function,
The wireless tag reader further outputs information indicating whether the wireless tag has detected vibration;
The determination unit according to any one of claims 1 to 11, wherein the detection determination unit determines whether the wireless tag is detected and also determines whether the wireless tag has detected the vibration. The occupancy status determination server described.   The occupancy status determining means determines the number of times determined by the detection determining means when the wireless tag is detected and determined by the communication determining means to be able to communicate with the terminal device within a specified time. 13. The occupancy status determination server according to claim 1, wherein when the user is out of the range, the user is determined to be present in the area but in an abnormal state.   The occupancy status determination server according to any one of claims 1 to 13, wherein the wireless tag is of an active type. A wireless tag reader that is installed in the area and outputs information indicating whether or not the wireless tag possessed by the user has been detected;
A terminal device installed in the area, having a communication function, and used by the user;
An occupancy status determination server for determining the occupancy status of the user in the area;
The occupancy status determination server
Detection determination means for receiving information output from the wireless tag reader and determining whether the wireless tag is detected in the area based on the information;
Communication determining means for determining whether or not the occupancy status determining server and the terminal device can communicate;
An occupancy status determination system comprising: an occupancy status determination unit that determines the occupancy status of the user in the area based on the determination result by the detection determination unit and the determination result by the communication determination unit. .   A program for operating the occupancy status determination server according to any one of claims 1 to 14, wherein the program causes a computer to function as each of the means.   A computer-readable recording medium in which the program according to claim 16 is recorded.