JP6532839B2 - Monitored object management system - Google Patents

Description

  The present invention relates to a monitored object management system for managing the existing situation of moving monitored objects such as a plurality of workers.

  Conventionally, there is a need to manage the existence status of a plurality of moving monitored objects. For example, at a work site such as a plant construction site, it is necessary to perform labor management such as whether or not the planned number of workers work at a predetermined work site. Generally, when entering and leaving the gate Management of access to the work site is carried out based on information from RFID (Radio Frequency IDentification). In addition, a management system has been developed in which a plurality of workers are kept holding an RFID tag serving as a transmitter for transmitting beacon signals, and an RFID tag reader serving as a receiver for receiving beacon signals is disposed at a work place to manage labor. (For example, Unexamined-Japanese-Patent No. 2010-40038 (patent document 1)).

JP, 2010-40038, A

  However, the plant construction site naturally does not necessarily have a workpiece from the beginning, and construction will proceed gradually. Therefore, when using a beacon signal, the receiver should be located at an appropriate position in the area. Construction to be installed is required. In the case of the area where the electrical wiring is not made, it is necessary to carry out the electrical wiring work or to install a receiver incorporating a power source such as a storage battery. Electrical wiring work is very expensive, and when using a storage battery, it is necessary to periodically charge the storage battery, and it is also necessary to check whether necessary power is obtained, which takes time and effort. It is.

  As construction progresses and the work is completed, interferences of radio waves will increase. Therefore, at the position of the receiver initially installed, the radio wave from the transmitter can not be properly received, and there is also a problem that it is necessary to change the installation position of the receiver according to the progress of the construction. In addition, there are construction sites in a high temperature, high humidity, and dusty environment, and there is also a problem that mechanical equipment such as a receiver installed in advance is likely to break down.

  An object of the present invention is to provide a monitored object management system capable of managing the presence of a plurality of moving monitored objects by a simple means without having to install a receiver in advance.

  Another object of the present invention is to provide a monitored object management system capable of determining the position of a transmitter by using the radio wave intensity information of the transmitter received by the receiver.

  The monitoring target object management system of the present invention is composed of a plurality of beacon terminals, one or more management terminals, and a management server. The plurality of beacon terminals are respectively held by a plurality of monitored objects that exist in one or more areas and move, each having a unique beacon identifier, and transmit beacon signals. One or more management terminals are held by one or more mobile units moving in one or more areas, receive beacon signals, obtain beacon identifiers and beacon presence information, and obtain location information by the positioning system. Outputs the beacon identifier, the beacon presence information and the position information voluntarily or in response to a request. The management server determines the existence status of a plurality of monitoring objects in one or more areas based on beacon identifiers, beacon existence information and position information obtained from one or more management terminals.

  According to the present invention, beacon signals from a plurality of beacon terminals (transmitters) are transmitted using one or more management terminals (receivers) held by one or more mobile units moving in one or more areas. By receiving the information, it is possible to appropriately manage the existing situation in which area a plurality of monitoring objects holding beacon terminals are present without installing the receiver in the area in advance. be able to. In addition, even in an area where there are many metal structures and radio wave interference is likely to occur, the movement of the moving object facilitates receiving the beacon signal.

  For example, one or more areas are one or more work areas, a plurality of monitoring objects are a plurality of workers working in one or more work areas, and one or more moving bodies supervise a plurality of workers. If you have one or more supervisors, have each of the multiple workers hold the beacon terminal, and have one or more supervisors who are in the same room as the multiple workers hold the management terminal, at least near the manager. It is possible to grasp how many workers are present in which area (a range in which a beacon signal from a beacon terminal can be reached).

  As is apparent from the above, in the present invention, it is not always necessary to be able to grasp the exact number and position of the monitored objects present in one or more areas, and in one or more areas. It is sufficient if the number of existing monitored objects can be grasped with a certain degree of accuracy.

  The beacon terminal may be anything as long as it can transmit a beacon signal. For example, a transmitter of iBeacon (registered trademark) using Bluetooth (registered trademark) Low Energy (BLE) technology, etc. is assumed, but is limited thereto It is not a thing. The management terminal may be any terminal corresponding to the reception of the beacon signal transmitted by the beacon terminal. For example, a smartphone etc. capable of receiving radio waves emitted by iBeacon is assumed, but is not limited thereto. .

  Not only humans but also non-human animals and the like may be moved. Also, one or more moving bodies are not limited to humans, and it is a matter of course that an automatic traveling vehicle or a drone may be used.

  Although the beacon presence information may include various information, the management server is configured to include the field intensity information of the beacon signal based on the beacon identifier, the field intensity information, and the position information. The number of monitored objects present in the above area may be determined as the existing status. The separation distance between the management terminal and the beacon terminal can be estimated by the radio wave intensity information, and the presence position (area) of the monitoring target can be grasped more accurately.

  When two or more management terminals exist, it is possible to improve the determination accuracy of the location (area) of the beacon terminal. For example, when one beacon signal is received by two management terminals, the separation distance between the beacon terminal and the two management terminals is determined based on the radio wave intensity information, and the two units are determined. It is possible to determine that the beacon terminal is present in an area where there are more areas where two circles overlap, with two circles whose radius is the separation distance, with the management terminal in the center as a center. Although one management terminal can only know the separation distance between the management terminal and the beacon terminal, the approximate position of the beacon terminal in the area can be grasped by using two management terminals.

  When one beacon signal is received by three management terminals, the separation distance between the beacon terminal and the three management terminals is determined based on the radio wave intensity information, and the three managements are managed. It is also possible to draw three circles whose radius is the separation distance, centering on the terminal, and to determine that the beacon terminal is present in an area where an intersection by three circles exists. This is to determine the position of the beacon terminal by so-called triangulation, and the accuracy is higher than when two management terminals are used. When four or more management terminals receive one beacon signal, the position of the beacon terminal is based on the information from the management terminal that has received three beacon signals whose radio wave strength is stronger than the other radio wave strengths. You may decide In addition, since the radio wave intensities of two or more beacon signals may be at the same level, in that case, the beacon presence information includes reception date and time information at which one or more management terminals received the beacon signal. Among the beacon signals of the above, a beacon signal having a late reception date may be adopted.

  In addition to one or more management terminals, it is disposed in a fixed state in one or more areas, receives a beacon signal, acquires a beacon identifier and beacon presence information, and acquires position information by a positioning system, and spontaneously It may further comprise one or more fixed management terminals that output beacon identifiers, beacon presence information and location information, either in response to or upon request. In this case, based on the beacon identifier, the beacon presence information, and the position information obtained from the one or more management terminals and the one or more fixed management terminals, the management server determines a plurality of monitored objects in one or more areas. You may decide the existence situation of By including one or more fixed management terminals in addition to one or more management terminals, monitoring is performed even when there is an area where the reception environment of radio waves is bad or where there is a low frequency of mobile entry. It becomes easy to confirm the existence situation of the object.

  For example, at work sites such as plant construction sites, metal constructions increase as construction progresses, and depending on the position where workers are working, reflection and interference of radio waves may shorten the reach of beacon signals. Is expected to be Also, it is expected that there will be places where the frequency of access by supervisors is low, such as complicated places. In this case, one or more fixed management terminals are arranged in an area in which the reach of the beacon signal of the plurality of beacon terminals is shortened due to the presence of a signal reflector or in an area where the mobile object is less frequently entered. If so, it becomes easy to receive a beacon signal, and it becomes possible to accurately confirm the existence status of a worker (monitoring object).

  The management server further comprises: at least one fixed beacon terminal disposed in a fixed state in one or more areas, each having a unique beacon identifier, and transmitting a reference beacon signal respectively; The position information regarding the arrangement position of is stored, and when one or more management terminals receives the reference beacon signal together with the beacon signal, the management server transmits the beacon signal to one or more beacon terminals. May be determined to exist in the same area as the fixed beacon terminal that has transmitted the reference beacon signal. With this configuration, the existence status of a plurality of monitored objects in one or more areas is determined even in a place where one or more management terminals can not acquire position information because radio waves from satellites can not be acquired. It becomes possible. It is also possible to combine one or more fixed beacon terminals and one or more fixed management terminals.

It is a conceptual diagram which applied a monitored object management system of this embodiment to a labor management system at a plant construction site. It is a block diagram of the monitoring object management system of this embodiment. It is a conceptual diagram showing the surveillance subject management system of this embodiment. It is a conceptual diagram which shows the image in the case of calculating the position of a beacon terminal based on the beacon information from one management terminal. It is a conceptual diagram which shows the image in the case of calculating the position of a beacon terminal based on the beacon information from two management terminals. It is a conceptual diagram which shows the image in the case of calculating the position of a beacon terminal based on the beacon information from three management terminals. It is the figure which arrange | positioned one or more terminals for fixed management in the area. (A) And (B) is a conceptual diagram which shows the image in the case of pinpointing a position of a beacon terminal using a fixed beacon terminal. (A) thru | or (C) are conceptual diagrams which show the image in the case of pinpointing the position of a beacon terminal using the terminal for fixed management, and a fixed beacon terminal.

  Hereinafter, embodiments of a monitored object management system of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a conceptual diagram in which the monitored object management system is applied to a labor management system at a plant construction site, FIG. 2 is a block diagram of the monitored object management system, and FIG. 3 (A) is one or more It is a figure which shows the several beacon terminal which exists in an area, and one or more management terminals, and illustration of the person who hold | maintains each terminal is abbreviate | omitted for convenience of explanation. FIG. 3B is an example showing an output result of the arithmetic unit in the case of the example shown in FIG.

  At the plant construction site, multiple groups of supervisor SF and multiple workers FL are formed, and they move and work group by group. The monitored object management system according to the present embodiment is for grasping how many workers FL exist around one or more supervisors SF moving in the plant construction site and in what area. is there.

  As shown in FIG. 1, the monitored object management system 1 of the present embodiment is configured of a plurality of beacon terminals 3, one or more management terminals 5, and a management server 7. A plurality of beacon terminals 3 (beacon terminals 3a, 3b, 3c,...) Are respectively held by a plurality of workers FL (monitoring objects) existing at a plant construction site and moving, and each has a unique beacon identifier. And transmit beacon signals respectively. In the present embodiment, the beacon terminal 3 is an iBeacon (registered trademark) transmitter using Bluetooth (registered trademark) Low Energy (BLE) technology. Since the transmitter is small and light, for example, it can be carried by a worker by attaching it to a neck strap used when necking an ID card. The beacon terminal 3 is provided with the beacon terminal storage part 9 in which the beacon identifier was preserve | saved, and the beacon signal transmission part 11 which transmits a beacon signal.

  The one or more management terminals 5 (management terminals 5a, 5b, 5c,...) Are held by one or more supervisors SF (mobiles) moving in the plant construction site. The one or more management terminals 5 receive the beacon signal to obtain the beacon identifier and the beacon presence information, and obtain the position information by the positioning system (GPS), and the beacon identifier voluntarily or in response to the request, Output beacon presence information and position information. The beacon presence information includes field intensity information of the received beacon signal and reception date and time information when the beacon signal is received. In the present embodiment, the management terminal 5 is a smartphone that can receive radio waves emitted by the iBeacon. The management terminal 5 receives the beacon signal from the beacon terminal 3 and obtains the beacon identifier and the beacon presence information from the beacon signal, and the position of the management terminal 5 by the positioning system (GPS) It comprises a positioning unit 15 for positioning, and a management terminal storage unit 17 for storing a beacon identifier, beacon presence information and position information (hereinafter sometimes collectively referred to as "beacon information"). The control unit 19 reads the beacon identifier, the beacon presence information, and the position information from the management terminal storage unit 17 and outputs the beacon identifier, the communication unit 21 and the communication unit 21. The communication unit 21 is connected to the Internet.

  The management server 7 determines the existence status of a plurality of monitoring objects at the plant construction site based on the beacon identifier, the beacon presence information and the position information obtained from the one or more management terminals 5. The management server 7 includes a server storage unit 25 that stores a beacon identifier, beacon presence information, and position information received from the management terminal 5 through the communication unit 23. The management server 7 further includes an arithmetic unit 27. The arithmetic unit 27 periodically reads the beacon identifier, the beacon presence information and the position information stored in the server storage unit 25 (for example, every hour), calculates the existence status of the plurality of beacon terminals 3, and performs a plurality of labors The presence status of the person FL is stored in the server storage unit 25. Then, the result is output according to the presence status confirmation request from the external terminal PC. The arithmetic unit 27 reads the beacon identifier, the beacon presence information and the position information stored in the server storage unit 25 in response to the presence status confirmation request from the external terminal PC, calculates the presence status of the plurality of beacon terminals 3, Of course, the result may be output to the external terminal PC as the existence status of the worker FL.

  In the present embodiment, the plant construction site is divided into four areas I, II, III, and IV. For each area, latitude and longitude are measured in advance using a positioning system (GPS). In the example shown in FIG. 3A, four groups to which a plurality of workers belong are formed for the supervisor SF, and work is performed in the areas I, II, III, and IV. When the external terminal PC issues a request for confirming the existence status of a plurality of workers FL in the time zone shown in FIG. 3A, an output result as shown in FIG. 3B can be obtained. Note that the output result is not limited to this aspect, and a plot of positions of a plurality of workers may be output on a map.

<Position estimation based on beacon information from one management terminal>
FIG. 4 is a conceptual diagram showing an image in the case where the position of the beacon terminal 3a is calculated based on the beacon information from one management terminal 5a when the existence status of a plurality of workers FL is calculated by the calculation unit 27. FIG.

  The example shown in FIG. 4 is a case where the beacon signal transmitted by the beacon terminal 3a is received only by the management terminal 5a, and the worker's presence status is determined based on the beacon information received from the management terminal 5a.

  In this case, the calculation unit 27 determines that the beacon terminal 3a exists in the area where the management terminal 5a exists. Therefore, in the example shown in FIG. 4, the worker FL holding the beacon terminal 3a is determined to exist in the area I.

  In addition, when estimating the position of the beacon terminal 3 based on the beacon information from one management terminal, the output of the beacon signal of the beacon terminal 3 is lowered and detected by the management terminal 5 existing nearby. By doing this, it is possible to improve the accuracy of position determination.

<Position estimation based on beacon information from two management terminals>
FIG. 5 shows an image in the case where the position of the beacon terminal 3a is calculated based on beacon information from the two management terminals 5a and 5b when calculating the existence status of a plurality of workers FL in the calculation unit 27. It is a conceptual diagram shown.

  In the example shown in FIG. 5, the beacon signal transmitted by the beacon terminal 3a is received by the two management terminals 5a and 5b, and the worker receives the beacon signal from the two management terminals 5a and 5b. It is a case where the existence situation is decided.

  There is a proportional relationship in which the radio wave intensity is stronger as the separation distance between the management terminal 5 and the beacon terminal 3 is shorter and as the separation distance is longer. Therefore, in the present embodiment, a conversion table of the relationship between the radio wave strength and the separation distance between the management terminal 5 and the beacon terminal 3 is prepared in advance, and the calculation unit 27 determines the radio wave strength information in the beacon presence information. The separation distance between the beacon terminal 3a and the two management terminals 5a and 5b is determined. After that, two circles C1 and C2 whose radius is the separation distance are drawn centering on the two management terminals 5a and 5b, and the beacon terminal 3a is located in an area where there are more overlapping areas of the two circles C1 and C2. Confirm that exists. In the example of FIG. 5, since the area where C1 and C2 overlap is larger in area I than in area III, the worker FL holding the beacon terminal 3a is determined to exist in area I.

<Position estimation based on beacon information from three management terminals>
FIG. 6 shows the case where the position of the beacon terminal 3a is calculated based on the beacon information from the three management terminals 5a, 5b and 5c when calculating the existence status of a plurality of workers FL in the calculation unit 27. It is a conceptual diagram showing an image.

  In the example shown in FIG. 6, the beacon signal transmitted by the beacon terminal 3a is received by the three management terminals 5a and 5b, and labor is performed based on the beacon information received from the three management terminals 5a, 5b and 5c. If the existence status of the person is determined, or based on beacon information received by four or more management terminals 5 and received from three management terminals 5 (5a, 5b, 5c) with strong radio wave strength It is a case to determine the existence situation of the person. In addition, when the field intensity of two or more beacon signals is in the same level, the beacon signal with a late reception date is employ | adopted among two or more beacon signals.

  The calculation unit 27 determines the separation distance between the beacon terminal 3a and the three management terminals 5a, 5b and 5c based on the radio wave intensity information in the beacon presence information, using the above-mentioned conversion table. After that, three circles C1, C2 and C3 whose radius is the separation distance are drawn around the three management terminals 5a, 5b and 5c, and in the area where the intersection IS by the three circles C1, C2 and C3 exists It is determined that the beacon terminal 3a exists in In the example of FIG. 6, since the intersection point IS exists in the area I, the worker FL holding the beacon terminal 3 a is determined to exist in the area I.

<Terminal for fixed management>
Although the beacon signal is received by one or more management terminals 5 in the above, the monitoring target object management system 1 is fixed in one or more areas in addition to the one or more management terminals 5. Positioned, receiving beacon signals to obtain beacon identifiers and beacon presence information, and obtaining position information by a positioning system, outputting beacon identifiers, beacon presence information and position information voluntarily or in response to a request It may further comprise one or more fixed management terminals 29 (29a, 29b, 29c,...). FIG. 7 is a diagram in which one or more fixed management terminals 29 are arranged in the plant construction site. It is preferable to install one or more fixed management terminals 29 at a place where the reach of the beacon signal is shortened, a place where the communication distance is convoluted, or a place where the frequency of access by the supervisor is low. In the case of a work site at a plant construction site, as construction proceeds, the number of metal structures increases, and the number of workers who work in a convoluted area also increases. By setting up, it is possible to accurately determine the existence status of workers (monitoring objects). The fixed management terminal 29 may be a fixed installation type terminal or a smart phone. For example, in the case of using a smartphone, the installation location may be determined in advance, and the supervisor may set up before the start of the work and the supervisor may collect it after the work is completed.

<Fixed beacon terminal>
The monitoring target object management system 1 is fixedly disposed in one or more areas, and has one or more fixed beacon terminals 31 (31a, 31b, 31c,...) Each of which has a unique beacon identifier and transmits a reference beacon signal.・ ・) May be further provided. In this case, when the management server 7 stores position information on the arrangement position of the one or more fixed beacon terminals 31 and the one or more management terminals 5 receive the reference beacon signal together with the beacon signal, the beacon The one or more beacon terminals 3 that have transmitted the signal are determined to be within the same area as the fixed beacon terminal 31 that has transmitted the reference beacon signal. With this configuration, the existence status of a plurality of monitoring objects in one or more areas is determined even in a place where one or more management terminals 5 can not acquire position information because radio waves from satellites can not be acquired. It is possible to For example, in the example shown in FIG. 8A, the management terminal 5a receives the reference beacon signal from the fixed beacon terminal 31a together with the beacon signal from the beacon terminal 3a. It is determined that the worker FL holding the terminal 3a exists in the area I. In the example shown in FIG. 8B, since the management terminal 5a can not receive the reference beacon signal, the position of the worker FL is determined by the other method described above. Circles illustrated in FIGS. 8A and 8B indicate the reach distance of radio waves transmitted by the beacon terminal 3a and the fixed beacon terminal 31a.

  It is also possible to combine the fixed management terminal 29 and the fixed beacon terminal 31. In the example shown in FIG. 9A, the management terminal 5a receives the reference beacon signal from the fixed beacon terminal 31a together with the beacon signal from the beacon terminal 3a. The fixed management terminal 29a also receives the reference beacon signal from the fixed beacon terminal 31a, together with the beacon signal from the beacon terminal 3a. Therefore, the management server 7 determines that the worker FL holding the beacon terminal 3a exists in the area I based on any information. In the example shown in FIG. 9B, the management terminal 5a can not receive the reference beacon signal, but the fixed management terminal 29 receives the reference beacon signal from the fixed beacon terminal 31a together with the beacon signal from the beacon terminal 3a. Is received, the management server 7 determines that the worker FL holding the beacon terminal 3a is present in the area I. In the example shown in FIG. 9C, since neither the management terminal 5a nor the fixed management terminal 29a can receive the reference beacon signal, the position of the worker FL is determined by the other method described above. Circles illustrated in FIGS. 9A to 9C indicate the reach distance of radio waves transmitted from the beacon terminal 3a, the fixed management terminal 29a, and the fixed beacon terminal 31a.

  As mentioned above, although embodiment of this invention was described concretely, this invention is not limited to these embodiment, Of course, it can change within the range of the technical idea of this invention. It is.

  For example, in the above embodiment, although the monitored object management system 1 is used as a labor management system, in the event of an emergency, the worker uses the monitored object management system 1 to start the final communication position of the beacon terminal. It is also possible to estimate the place left behind and use it for going to rescue.

  Moreover, not only human but also animals other than human or the like may be moved. Of course, one or more moving bodies are not limited to humans, and may be an automatic traveling vehicle or a drone.

  Furthermore, it is also possible to use an event management system in which an event participant holds a beacon terminal, and a management terminal of the event manager receives a beacon signal to grasp the number and position of the event participants.

  According to the present invention, it is possible to provide a monitored object management system capable of managing the presence of a plurality of moving monitored objects by a simple means without having to install a receiver in advance.

Reference Signs List 1 monitored object management system 3 beacon terminal 5 management terminal 7 management server 9 beacon terminal storage unit 11 beacon signal transmission unit 13 beacon signal reception unit 15 position positioning unit 17 management terminal storage unit 19 control unit 21 communication unit 23 communication Unit 25 Server storage unit 27 Operation unit 29 Fixed management terminal 31 Fixed beacon terminal

Claims (11)

A plurality of beacon terminals that are respectively held by a plurality of monitored objects that exist in one or more areas and move, each having a unique beacon identifier, and transmitting beacon signals respectively;
It is held by one or more mobile units moving in the one or more areas, receives the beacon signal, acquires the beacon identifier and the beacon presence information, and acquires position information by the positioning system, and spontaneously Or at least one management terminal that outputs the beacon identifier, the beacon presence information, and the position information according to a request;
A management server for determining the existence status of the plurality of monitoring objects in the one or more areas based on the beacon identifier obtained from the one or more management terminals, the beacon presence information, and the position information Yes,
The monitored object management system, wherein the one or more mobile units are one or more supervisors who supervise the plurality of monitored objects . The beacon presence information includes radio wave intensity information of the beacon signal,
The management server is characterized in that the number of objects to be monitored in the one or more areas is determined as the presence status based on the beacon identifier, the radio wave intensity information, and the position information. The monitored object management system according to 1.   When the two management terminals receive one beacon signal, the management server separates the beacon terminal from the two management terminals based on the radio wave intensity information. If the beacon terminal exists in the area where there are more areas where the two circles overlap, centering on the two management terminals and drawing two circles whose radius is the separation distance. The monitored object management system according to claim 2, which is determined.   When the three management terminals receive one beacon signal, the management server separates the beacon terminal from the three management terminals based on the radio wave intensity information. Determine the distance, draw three circles whose radius is the separation distance, centering on the three management terminals, and determine that the beacon terminal exists in the area where the intersection by the three circles exists The monitored object management system according to claim 2.   When the four or more management terminals receive one beacon signal, the management server receives the three beacon signals whose radio wave strength is stronger than the other radio wave strengths. The monitored object management system according to claim 4, wherein the position of the beacon terminal is determined based on the information from. The beacon presence information includes reception date and time information when the one or more management terminals have received the beacon signal,
6. The monitoring according to claim 5, wherein the management server adopts the beacon signal whose reception date is late among the two or more beacon signals when the radio field strengths of the two or more beacon signals are at the same level. Object management system. It is arranged in a fixed state in the one or more areas, receives the beacon signal, acquires the beacon identifier and beacon presence information, and acquires position information by the positioning system, either spontaneously or on request. It further comprises one or more fixed management terminals for outputting the beacon identifier, the beacon presence information and the position information,
The management server is configured to receive the beacon identifier obtained from the one or more management terminals and the one or more fixed management terminals, the beacon presence information, and the position information, in the one or more areas. The monitored object management system according to claim 1, wherein the existence status of the monitored object is determined.   The one or more fixed management terminals are arranged in an area where the reach of the beacon signal of the plurality of beacon terminals is shortened due to the presence of a signal reflector or in an area where the frequency of entry of mobile objects is low. The monitored object management system according to 7. The mobile terminal further includes one or more fixed beacon terminals, which are arranged in a fixed state in the one or more areas, and each has a unique beacon identifier, and each transmits a reference beacon signal,
The management server stores position information on the arrangement position of the one or more fixed beacon terminals,
When the one or more management terminals receive the reference beacon signal together with the beacon signal, the management server transmits one or more beacon terminals that have transmitted the beacon signal. The monitored object management system according to claim 1, wherein it is determined that the terminal device is in the same area as the fixed beacon terminal. It is arranged in a fixed state in the one or more areas, receives the beacon signal, acquires the beacon identifier and beacon presence information, and acquires position information by the positioning system, either spontaneously or on request. One or more fixed management terminals that output the beacon identifier, the beacon presence information, and the position information;
And one or more fixed beacon terminals, each of which is disposed in a fixed state in the one or more areas and has a unique beacon identifier and transmits a reference beacon signal, respectively.
The management server stores position information on arrangement positions of the one or more fixed management terminals and the one or more fixed beacon terminals,
The management server is configured to receive the beacon identifier obtained from the one or more management terminals and the one or more fixed management terminals, the beacon presence information, and the position information, in the one or more areas. Determine the existence status of the monitored object,
When the one or more management terminals or the one or more fixed management terminals receive the reference beacon signal together with the beacon signal, the management server is the one or more beacons that has transmitted the beacon signal. The monitored object management system according to claim 1, wherein the terminal determines that the terminal exists in the same area as the fixed beacon terminal that has transmitted the reference beacon. The one or more areas are one or more work areas,
The plurality of monitoring objects are a plurality of workers working in the one or more work areas,
The monitored object management system according to any one of claims 1 to 10, wherein the one or more mobile units are one or more supervisors who supervise the plurality of workers.