JP2017033242A - Guide system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a guide system capable of guiding a moving route so as to realize smooth movement.SOLUTION: A disaster prevention system 1 is a system that uses multiple light alerting systems 311 to 324 provided in a building 100 to guide a moving route of a user carrying a mobile terminal. A receiver 50 of the disaster prevention system 1 comprises an abnormal place specification part, a terminal place specification part, a generation part and a guide part. The abnormal place specification part specifies an abnormality occurrence place in the building 100, the terminal place specification part specifies a place of the mobile terminal in the building 100, the generation part generates a moving route on the basis of a specification result of the abnormal place specification part and a specification result of the terminal place specification part, and the guide part uses the light alerting systems to guide the moving route generated by the generation part.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a guidance system.

  2. Description of the Related Art Conventionally, guidance systems that guide evacuation routes to evacuees when a fire occurs are known. This guidance system includes a disaster prevention receiver, and the disaster prevention receiver receives position information (for example, GPS information, beacon information, etc.) from the evacuee's mobile terminal, and based on the received position information. By identifying the optimum evacuation route, transmitting evacuation guidance information for guiding to the identified evacuation route to the portable terminal, and displaying the evacuation guidance information on the display means (for example, a liquid crystal monitor) of the portable terminal, He was guiding the evacuation route.

  However, in order to confirm the evacuation guidance information, it is necessary to pick up the mobile terminal in order to view the display means. Therefore, evacuation is required for evacuation (for example, moving the cared person's wheelchair). When the person's hands are occupied, the portable terminal cannot be picked up, and the evacuation guidance information may not be confirmed.

  Then, the warning system which guides an evacuation route using the some light alarm apparatus installed in the building is proposed (for example, refer patent document 1). For this alarm system, in the event of a fire, the light alarm device repeatedly emits light sequentially from the light alarm device on the fire occurrence side to the light alarm device on the emergency exit side, and toward the emergency exit from the fire occurrence location. The evacuation route was guided by giving an impression that the light from

JP 2014-186430 A

  However, in the alarm system of Patent Document 1, since the evacuation route that is uniformly determined based on the fire occurrence position and the installation position of the emergency exit was guided, a large number of evacuees rushed to one emergency exit, There was a possibility that the emergency exit would be crowded and the evacuation would be delayed or confused.

  The present invention has been made in view of the above, and an object of the present invention is to provide a guidance system that can guide a moving route so that the vehicle can move smoothly.

  In order to solve the above-described problems and achieve the object, the guidance system according to claim 1 uses a plurality of light alarm devices provided in a building to move a user carrying a portable terminal. A guidance system for guiding a route, the first specifying means for specifying the location of occurrence of an abnormality in the building, the second specifying means for specifying the location of the mobile terminal in the building, and the first specifying means Based on the identification result of the second identification unit and the identification result of the second identification unit, the generation unit that generates the travel route, and the guidance that guides the travel route generated by the generation unit using the plurality of light alarm devices Means.

  The guidance system according to claim 2 is the guidance system according to claim 1, wherein the plurality of light alarm devices include receiving means for receiving radio waves output from the portable terminal, and the second specifying means. Identifies the location of the portable terminal based on the reception result of the receiving means.

  The guidance system according to claim 3 is the guidance system according to claim 1 or 2, wherein the abnormality is a fire, and the movement route is an evacuation route.

  The guidance system according to claim 4 is the guidance system according to claim 3, wherein the building is provided with a plurality of evacuation ports, and each of a plurality of users carries the portable terminal, The second specifying means specifies each location of the portable terminal carried by each of a plurality of users based on the reception result of the receiving means, and the generating means is based on the specification result of the second specifying means. The degree of congestion that is the degree of congestion by the plurality of users in the predetermined area of the building is specified, and the evacuation reaching at least one of the plurality of evacuation openings based on the specified degree of congestion Generate a route.

  According to the guidance system of claim 1, the travel route generated based on the identification result of the first identification unit that identifies the location of occurrence of the abnormality and the identification result of the second identification unit that identifies the location of the mobile terminal. Therefore, it is possible to prevent a large number of evacuees from rushing into one emergency exit by, for example, guiding the moving route in consideration of the location of the mobile terminal. Therefore, it is possible to guide the moving route so that it can move smoothly.

  According to the guidance system of the second aspect, the reception unit receives the radio wave output from the mobile terminal, and specifies the location of the mobile terminal based on the reception result of the reception unit. Even if the mobile terminal is provided at a location away from the mobile phone or a plurality of mobile terminals are provided, the location of the mobile terminal can be reliably identified, and the guidance accuracy of the travel route can be improved.

  According to the guidance system of the third aspect, since the abnormality is a fire and the movement route is an evacuation route, for example, it is possible to guide the evacuation route so that evacuation can be performed smoothly.

  According to the guidance system of claim 4, since the evacuation route is generated based on the degree of congestion, for example, it is possible to avoid the congestion when evacuating and to guide the evacuation route so that evacuation can be performed smoothly. Become.

It is the schematic which shows the structure of the disaster prevention system which concerns on embodiment of this invention. It is a block diagram which shows the electrical structure of a light alarm apparatus functionally conceptually. It is a block diagram which shows the electrical structure of a receiver functionally conceptually. It is a flowchart of the disaster prevention process of a light alarm device and a receiver. It is a figure for demonstrating an example of a disaster prevention process.

  Hereinafter, embodiments of a guidance system according to the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the embodiments.

[Basic concept of the embodiment]
First, the basic concept of the embodiment will be described. In the embodiment, generally, a plurality of travel routes generated based on the identification result of the first identification unit that identifies the location of occurrence of the abnormality and the identification result of the second identification unit that identifies the location of the mobile terminal The present invention relates to a guidance system that provides guidance using a light alarm device.

  Here, the “guidance system” is a disaster prevention system for disaster prevention, which is a system for monitoring an abnormality in a monitoring area and notifying a moving route together with the abnormality using a light alarm device. The terminal includes a terminal, a receiver, an abnormal output device, and a plurality of light alarm devices. The “monitoring area” is an area to be monitored by the light alarm system, and is a concept including, for example, a building room, a hallway, a staircase, and the like. “Abnormal” means something different from normal, for example, fire or gas leak. “Movement route” is a route in which a person in the monitoring area should move. For example, an evacuation route for evacuation, a rescue route to a rescuer who needs relief, a disaster prevention worker (for example, a firefighter, etc.) ) Is a concept including a guide route for guiding the disaster prevention device to the disaster prevention device. A “portable terminal” is a terminal device that can be carried by a user, and is a device in which the position of the portable terminal itself can be specified by another device (for example, a receiver or the like). This is a concept that includes a general-purpose device such as a mobile phone that repeatedly outputs radio waves for specifying the position at predetermined time intervals (for example, 30 seconds), a dedicated device for disaster prevention, and the like. The “receiver” is a receiving means (fire receiving panel) that performs a predetermined process based on a plurality of detectors, and is installed in a management room, for example. The “abnormal output device” is a device that performs an abnormal output for notifying the occurrence of an abnormality in the monitoring area, and corresponds to, for example, a sensor or a transmitter. “Sensor” is a sensing means that senses whether there is an abnormality in the monitoring area, for example, a fire sensor that detects smoke or heat to notify a fire, a gas leak sensor that senses gas, or a human body. This corresponds to a human sensor. The “transmitter” is configured by including a push button switch, and is an activation device that performs an abnormal output when the push button switch is pressed by a user. The “light warning device” is a warning means for notifying abnormality in the monitoring area, and is a device that outputs light to notify the abnormality.

  Moreover, the connection method between each apparatus which comprises a guidance system is arbitrary, and you may connect using any of a wire communication and radio | wireless. In this embodiment, the disaster prevention system as a guidance system is configured as a so-called R-type system, and devices other than the mobile terminal among the devices constituting the guidance system are mutually connected via a communication line. Wired connection, “mobile phone” is “mobile phone”, “monitoring area” is “predetermined floor of building (eg, first floor)”, and “abnormality” is “fire” The case where the “abnormal output machine” is the “fire detector” and the “travel route” is the “evacuation route” will be described.

[Specific contents of the embodiment]
Next, specific contents of the embodiment will be described.

(Constitution)
First, the structure of the disaster prevention system which concerns on embodiment is demonstrated. FIG. 1 is a schematic diagram illustrating a configuration of a disaster prevention system according to an embodiment. Note that FIG. 1 is a plan view of a predetermined floor (for example, the first floor) in the building 100. As shown in FIG. 1, the disaster prevention system 1 is a disaster prevention means provided in a building 100 and is a guidance system for notifying a moving route, and includes detectors 211 to 216 and a light alarm device 321. 324, portable terminals 411 to 413, and a receiver 50. The disaster prevention system 1 is actually provided with a ringing device such as an emergency bell, but is omitted in FIG. In addition, the disaster prevention system 1 actually includes each sensor installed on each floor other than the first floor of the building 100 and each light alarm device. Here, the first floor of the building 100 is provided. The sensors 211 to 216 and the light alarm devices 311 to 324 provided in FIG. Further, the number of mobile terminals in the disaster prevention system 1 is determined according to the number of users holding the mobile terminal, but here, for convenience of explanation, it is assumed that the mobile terminals 411 to 413 are provided. explain. In addition, in FIG. 1, illustration of the user holding these portable terminals 411-413 is abbreviate | omitted. When the sensors 211 to 216 do not need to be distinguished from each other, they are collectively referred to as “sensor 20”. When it is not necessary to distinguish the light alarm devices 311 to 324 from each other, “light alarm device 30”. When the mobile terminals 411 to 413 do not need to be distinguished from each other, they will be collectively referred to as “mobile terminal 40” and will be described below.

(Configuration-sensor)
First, the configuration of the sensor 20 will be described. The sensor 20 is a sensing unit that senses an abnormality in the monitoring area in which the sensor 20 is installed. Specifically, the sensor 20 is a fire sensor installed at a predetermined position of the building 100. The sensor 20 can be installed at an arbitrary position in the building 100 in accordance with a predetermined law or a user's needs. Here, as shown in FIG. Among the corridors 11 to 15 of the object 100, the sensor 213 is installed in the hallway 12, the sensors 214 and 215 are installed in the hallway 13, and the sensor 216 is installed in the hallway 14. As described below, the following description will be given. The sensor 20 installed in this way is configured to transmit a notification signal including its own identification information (hereinafter referred to as ID) to the receiver 50 when a fire is detected. Here, “ID” is information for uniquely identifying a device. Based on the ID included in the notification signal, the sensor 20 that has output the notification signal can be specified.

(Configuration-Light alarm device)
Next, the configuration of the light alarm device 30 will be described. The light alarm device 30 is an alarm means for notifying abnormality of the monitoring area, and specifically, is a device installed at a predetermined position of the building 100. The light alarm device 30 can be installed at an arbitrary position in the building 100 in accordance with a predetermined law or a user's needs. Here, as shown in FIG. 1, the light alarm devices 311 to 315 are provided. Are installed in the corridor 11, the light alarm devices 316 and 317 are installed in the corridor 12, the light alarm devices 318 to 322 are installed in the corridor 13, and the light alarm devices 323 and 324 are installed in the corridor 14. It will be described below.

  FIG. 2 is a block diagram functionally conceptually showing the electrical configuration of the light alarm device 30. As shown in FIG. 2, the light alarm device 30 includes a communication unit 31, a light emitting unit 32, a light emission driving unit 33, a storage unit 34, and a control unit 35.

(Configuration-Light alarm device-Communication part)
The communication unit 31 is a communication unit that performs communication with the mobile terminals 411 to 413 and the receiver 50 in FIG. 1 and includes, for example, a communication circuit.

(Configuration-Light alarm device-Light emitting part)
Returning to FIG. 2, the light emitting unit 32 is a light emitting unit that emits light. Specifically, the light emitting unit 32 outputs light when supplied with a driving current, and includes, for example, a light emitting diode. ing.

(Configuration-Light alarm device-Light emission drive)
The light emission drive unit 33 is a light emission drive unit that drives the light emission unit 32. Specifically, the light emission drive unit 33 supplies a drive current to the light emission unit 32, and includes, for example, a drive current supply circuit. Yes. Here, the “drive current supply circuit” is a circuit for supplying drive current, and adjusts the amount of drive current to be supplied (that is, supplying drive current or stopping supply of drive current) Any circuit can be used as long as it is a circuit that can be used. For example, a circuit including an output transistor and a control operational amplifier that controls the output transistor can also be used.

(Configuration-Light alarm device-Storage unit)
The storage unit 34 is a storage unit that stores a program and various data necessary for the operation of the light alarm device 30. The storage unit 34 stores the ID of the light alarm device 30 to which the storage unit 34 belongs.

(Configuration-Light alarm device-Control unit)
The control unit 35 is a control unit that controls the light alarm device 30. Specifically, the control unit 35 includes a CPU, various programs that are interpreted and executed on the CPU (including a basic control program such as an OS and an application program that is activated on the OS and realizes a specific function), and This is a computer configured with an internal memory such as a RAM for storing programs and various data (this is the same for the control units of other devices and devices). In particular, the program according to the present embodiment is substantially installed in the light alarm device 30 via an arbitrary storage medium or network, thereby substantially configuring each unit (function) of the control unit 35. The specific processing contents by the control unit 35 will be described later.

(Configuration-mobile terminal)
Next, the configuration of the mobile terminals 411 to 413 illustrated in FIG. 1 will be described. The portable terminal 40 is a device that is carried by a user. Specifically, the portable terminal 40 repeatedly outputs a radio wave having a constant electric field strength at predetermined time intervals (for example, 10 seconds) and indicating its own ID. Mobile phone. Since this portable terminal 40 is carried by the user, it is provided at the current position of the user.

(Configuration-Receiver)
Next, the configuration of the receiver 50 will be described. FIG. 3 is a block diagram functionally conceptually showing the electrical configuration of the receiver 50. As shown in FIG. 3, the receiver 50 includes an input unit 51, an output unit 52, a communication unit 53, a storage unit 54, and a control unit 55.

(Configuration-Receiver-Input section)
The input unit 51 is an input unit that receives input of information necessary for the operation of the receiver 50, and includes, for example, a touch panel, a switch, and an external input terminal.

(Configuration-Receiver-Output section)
The output unit 52 is an output unit that outputs information necessary for the operation of the receiver 50, and includes, for example, a speaker, a display, an indicator lamp, and an external output terminal.

(Configuration-Receiver-Communication part)
The communication unit 53 is a communication unit that communicates with the sensor 20 and the light alarm device 30 and includes, for example, a communication circuit.

(Configuration-Receiver-Storage unit)
The storage unit 54 is a storage unit that stores a program and various data necessary for the operation of the receiver 50. The storage unit 54 is configured using, for example, a hard disk (not shown) as an external storage device, but instead of or together with the hard disk, a magnetic storage medium such as a magnetic disk, or a DVD or Blu-ray disk. Any other storage medium including such an optical storage medium can be used (in this regard, the storage units of other apparatuses and devices may be the same).

  The storage unit 54 stores map information 541 and installation position specifying information 542. Here, the “map information” 541 is information relating to the map, specifically, information relating to the map of the building 100 in FIG. 1, and member information (columns, walls, etc. of the building 100 in FIG. 1). Information for specifying the position, size, shape, etc. (that is, information for specifying the position, size, shape, etc. of the corridors 11-15)), and entrance information (the entrances 101, 102 of the building 100 in FIG. 1) This information includes information specifying the position of the evacuation exit). The “installation position specifying information” 542 is information for specifying the installation position of the device. Specifically, the information is for specifying the installation position of each device in the disaster prevention system 1 and is used for specifying the detector installation position. Information (information specifying the installation positions of the sensors 211 to 216 in FIG. 1 (for example, information that the sensor 211 is provided at the west end of the corridor 11)), and light alarm device installation position specifying information (FIG. Information for specifying the installation position of one light alarm device 311 to 324 (for example, the light alarm device 311 is provided at the westernmost end of the corridor 11, the light alarm device 312 is east of the light alarm device 311 in the corridor 11) The information including the information)) provided at a position separated by a predetermined distance.

(Configuration-Receiver-Controller)
The control unit 55 is a control unit that controls the receiver 50. The control unit 55 includes an abnormal place specifying unit 551, a terminal place specifying unit 552, a generation unit 553, and a guide unit 554 in terms of functional concept. This abnormal place specifying unit 551 is a first specifying means for specifying the place where an abnormality has occurred in the building 100 (that is, the place where a fire breaks out). The terminal location specifying unit 552 is a second specifying unit that specifies the location of the mobile terminal 40 in the building 100. The generation unit 553 is a generation unit that generates an evacuation route as a travel route based on the specification result of the abnormal place specification unit 551 and the specification result of the terminal place specification unit 552. The guide unit 554 is a guide unit that guides the evacuation route generated by the generation unit 553 using the light alarm device 30. The specific processing contents by each unit of the control unit 55 will be described later.

(processing)
Next, the disaster prevention process performed by the disaster prevention system 1 configured as described above will be described. This disaster prevention process is repeatedly executed by each device after the power to each device included in the disaster prevention system 1 is turned on. This disaster prevention process includes a notification process for notifying a fire by ringing a ringing device (not shown) when the sensor 20 in FIG. 1 outputs a notification signal. Since a known process can be applied, the description of the notification process is omitted. FIG. 4 is a flowchart of the disaster prevention process of the light alarm device 30 and the receiver 50. In the following, “step” is abbreviated as “S”. Moreover, FIG. 5 is a figure for demonstrating an example of a disaster prevention process. Below, it demonstrates using the example when a fire generate | occur | produces in the fire source F shown in FIG. 5 suitably.

  First, in SA1 of FIG. 4, the control unit 55 of the receiver 50 determines whether or not an alert signal has been received. Specifically, a notification signal received from the sensor 20 via the communication unit 53 is monitored, and it is determined whether or not the notification signal has been received. And when it determines with not having received the alerting | reporting signal (NO of SA1), SA1 is repeatedly performed. If it is determined that a notification signal has been received (YES in SA1), the process proceeds to SA2.

  Next, in SA2, the abnormal place identifying unit 551 of the receiver 50 identifies the place where the fire started. Specifically, by referring to the map information 541 and the installation position specifying information 542 in FIG. 3, the installation position of the sensor corresponding to the ID included in the notification signal received at SA1 is specified, and the specified Identify the area around the installation location as a fire place. Here, for example, when a fire breaks out at the fire source F shown in FIG. 5, the sensor 212 outputs an alarm signal including its own ID. Then, the abnormal location specifying unit 551 of the receiver 50 that has received the output notification signal specifies the installation position of the sensor 212, and the periphery of the specified installation position (that is, east of the center in the hallway 11). Is identified as the fire outbreak location.

  Returning to FIG. 4, on the other hand, in SB1, the control unit 35 of the light alarm device 30 determines whether or not a radio wave has been received. Specifically, the electric field strength of the radio wave received from the mobile terminal 40 via the communication unit 31 is monitored to determine whether or not the radio wave has been received. If the electric field strength is not equal to or higher than the predetermined value (that is, the electric field strength is lower than the predetermined value), it is determined that no radio wave is received (NO in SB1), and SB1 is repeatedly executed. To do. Further, when the electric field strength is equal to or greater than a predetermined value, it is determined that the radio wave has been received (YES in SB1), and the process proceeds to SB2. Here, the “predetermined value” is a value used for determining whether or not a radio wave is received, and is arbitrarily set based on the relationship with the electric field strength of the radio wave output from the mobile terminal 40. For example, when the portable terminal 40 outputs radio waves, a relatively small value is set so that at least one of the optical alarm devices 30 can determine that the radio alarm has been received. (For example, 0.5 (V / m) or the like). Note that the electric field strength of the received radio wave may be detected by using level detection means such as an RSSI (Received Signal Strength Indicator) circuit, and the detected result may be used for the determination of SB1.

  Next, in SB2, the control unit 35 of the light alarm device 30 generates an electric field strength signal. Here, the “field strength signal” is a signal regarding the field strength, and specifically, strength information for specifying the field strength of the radio wave received by the optical alarm device 30 in SB1, and the ID indicated by the received radio wave. (That is, a signal including ID 411 to ID 413) and its own ID (that is, ID 311 to ID 324). “ID411” to “ID413” are IDs of the portable terminals 411 to 413, and “ID311” to “ID324” are IDs of the light alarm devices 311 to 324. Here, for example, in SB1, it is determined that the optical alarm device 313, 320 receives the radio wave from the portable terminal 411 in FIG. 5, and the electric field strength in the optical alarm device 313 is “F1 (F1 is a real number)”. Yes, when the electric field intensity in the light alarm device 320 is “F2 (F2 is a real number smaller than F1)”, the light alarm device 313 includes the intensity information that identifies “F1”, ID411, and ID313. The light alarm device 320 generates a field strength signal (hereinafter referred to as a second field strength signal) including ID information 411 and ID320. Electric field strength signal).

  Returning to FIG. 4, in SB3, the control unit 35 of the light alarm device 30 transmits an electric field strength signal. Specifically, the electric field strength signal generated in SB <b> 2 is transmitted to the receiver 50 via the communication unit 31. Here, for example, when the first electric field strength signal and the second electric field strength signal described above are generated in SB2, these signals are transmitted in SB3.

  On the other hand, in SA3, the control unit 55 of the receiver 50 determines whether or not an electric field strength signal has been received. Specifically, the electric field strength signal received from the light alarm device 30 via the communication unit 53 is monitored to determine whether or not the electric field strength signal has been received. If it is determined that the electric field strength signal has not been received (NO in SA3), SA3 is repeatedly executed. If it is determined that an electric field strength signal has been received (YES in SA3), the process proceeds to SA4.

  Next, in SA4, the terminal location specifying unit 552 of the receiver 50 specifies the location of the mobile terminal 40. Specifically, based on the electric field strength signal received in SA3, the map information 541 and the installation position specifying information 542 in FIG. 3, the locations of the mobile terminals 411 to 413 (that is, the current position of each user) are specified.

  Here, as a method of specifying the locations of the mobile terminals 411 to 413, any method can be used, but the following method can also be used. This technique will be described with reference to the case where the location of the mobile terminal 411 is specified. Specifically, first, based on the electric field strength signal received in SA3, an optical alarm device (hereinafter referred to as a corresponding radio wave reception optical alarm device) that has received radio waves from the same mobile terminal (hereinafter referred to as a specific target mobile terminal) is specified. To do. That is, more specifically, the position of the specific portable terminal is specified according to the distance ratio based on the electric field intensity ratio specified by the electric field intensity signal. Here, for example, when the first electric field strength signal and the second electric field strength signal described above are received in SA3, since both of these signals include the common “ID411”, they are included in these signals. The light alarm devices 313 and 320 corresponding to “ID 313” and “ID 320” are identified as “corresponding radio wave reception light alarm devices”. Next, the installation position of the identified corresponding radio wave reception light alarm device is specified based on the installation position specifying information 542 in FIG. Here, for example, the installation positions of the light alarm devices 313 and 320 in FIG. 5 are specified. Next, the electric field strength of the radio wave received by the specified corresponding radio wave receiving light alarm device is specified based on the electric field strength signal. Here, for example, “F1” is specified for the light alarm device 313 and “F2” is specified for the light alarm device 320. Next, based on these identification results (that is, the installation position of the corresponding radio wave reception light alarm device and the electric field intensity of the radio wave received by the corresponding radio wave reception light alarm device), the location of the above-mentioned “specific target mobile terminal” is determined. Identify. Here, for example, the light alarm device 313 corresponding to the maximum electric field strength “F1” among the specified electric field strengths “F1” and “F2” is within the installation position of the light alarm device 30. Since it is estimated to be closest to the mobile terminal 411 that is the specific target mobile terminal, and the corresponding radio wave reception light alarm device is the light alarm device 313, 320, the specific target mobile terminal is between the light alarm devices 313, 320. Considering that it is estimated that a certain mobile terminal 411 is provided, the position of the light alarm device 313 side from the center in the hallway 15 is specified as the location of the mobile terminal 411 that is the specific target mobile terminal. . When there is only one field strength signal received at SA3 (for example, only the first field strength signal described above), only one of the light alarm devices 30 corresponding to the ID included in the field strength signal is included. The peripheral area is specified as the location of the mobile terminal 411. Here, for example, when only the first electric field strength signal is received in SA3, the peripheral area of the light alarm device 313 corresponding to “ID313” included in the first electric field strength signal is set as the location of the mobile terminal 411. Identify. Here, the “peripheral area of the light alarm device 313” is an area within a predetermined distance from the light alarm device 313. The “predetermined distance” is a distance set according to the electric field intensity specified by the intensity information of the first electric field intensity signal, for example, a distance set so as to become longer as the electric field intensity becomes weaker.

  Next, in SA5, the generation unit 553 of the receiver 50 generates an evacuation route. Specifically, an evacuation route is generated based on the fire location specified in SA2, the location of the mobile terminal 40 specified in SA4, and the like.

  Here, as a method for generating an evacuation route, any method can be used as long as it generates a route that allows each user to evacuate safely and quickly. This method can also be used.

  The “first method” is a method for specifying an evacuation route in consideration of the moving distance of the user. Specifically, each user does not pass the fire point (that is, the fire source F in FIG. 5). This is a method of specifying the shortest route among routes that can travel to the entrance and exit as an evacuation route. Here, for example, when this first method is used, the generation unit 553 identifies routes R1 to R3 as evacuation routes for the users of the mobile terminals 411 to 413 in FIG.

  The “second method” is a method for specifying an evacuation route in consideration of the congestion situation, and specifically, a method for specifying a route to an entrance / exit with a low degree of congestion as an evacuation route. Here, the “congestion degree” is a degree of congestion, in particular, a degree of congestion by a plurality of users in a predetermined area of a building (for example, the building 100), specifically, a peripheral area of an entrance / exit. This is the number of users (that is, the number of mobile terminals 40) in the (predetermined area) (for example, an area within a radius of 10 meters from the entrance). Specifically, for the second method, first, based on the location of the mobile terminal specified in SA4, the congestion degree of the peripheral area of the entrance / exit (for example, the congestion degree of the peripheral area of the entrance / exit 101 in FIG. And the degree of congestion in the surrounding area. Next, for users in the vicinity area of the entrance and exit, a route that reaches the nearest entrance and does not pass through the fire source F is specified as an evacuation route, and for users outside the entrance and exit area, A route that reaches the entrance / exit where the degree of congestion is the lowest (that is, the number of users in the surrounding area is the smallest) and does not pass through the fire source F is specified as an evacuation route. Here, for example, in the case where the location of the mobile terminal 411 in FIG. 5 is outside the peripheral area of the entrances 101 and 102 and the location of the mobile terminals 412 and 413 is in the peripheral area of the entrance 101. When the method 2 is used, the generation unit 553 identifies the routes R2 and R3 that reach the entrance 101 as the user's evacuation route of the mobile terminals 412, 413, and the entrance 102 is more than the degree of congestion in the surrounding area of the entrance 101. Therefore, the route R4 to the entrance 102 is specified as the evacuation route for the user of the portable terminal 411.

  Returning to FIG. 4, in SA6, the guide unit 554 of the receiver 50 transmits a control signal to guide the evacuation route. Here, the “control signal” is a signal for controlling the light alarm device 30, specifically, a signal including the ID of the light alarm device 30 to be controlled. Then, the control unit 35 of the light alarm device 30 in FIG. 2 that has received this control signal controls the light emission drive unit 33 so as to supply the drive current for a predetermined time (for example, 0.1 second), thereby The light emitting unit 32 emits light for a predetermined time. Specifically, for SA6 in FIG. 4, a control signal is transmitted so that the user can evacuate along the route generated in SA5. Here, for example, in FIG. 5, when the routes R4, R2, and R3 are specified as the evacuation routes of the mobile terminals 411 to 413 using the “second method” described above, the route R4 to the user of the mobile terminal 411 is identified. Are transmitted in the order of a control signal including ID 320, a control signal including ID 319, a control signal including ID 318, a control signal including ID 317, and a control signal including ID 316, to the users of the portable terminals 412 and 413. In order to guide the routes R2 and R3, the control signal including the ID 323 and the control signal including the ID 324 are repeatedly transmitted in this order.

  Returning to FIG. 4, in SA7, the control unit 55 of the receiver 50 determines whether or not to stop guidance for the evacuation route. Specifically, the determination is made based on whether or not a recovery operation for the receiver 50 has been performed. Here, the “recovery operation” is an operation for recovering the state of the disaster prevention system 1, and specifically, the guidance of the evacuation route performed by the user via the input unit 51 of the receiver 50 is stopped. This is an operation for canceling the output of light from the light alarm device 30 (that is, canceling the light output from the light alarm device 30). And when recovery operation is performed, it determines with stopping guidance of an evacuation route (YES of SA7), and complete | finishes disaster prevention processing. If the restoration operation is not performed, it is determined that the guidance for the evacuation route is not stopped (NO in SA7), and the process proceeds to SA6. That is, the above-described SA6 process is repeated until a recovery operation is performed.

  Returning to FIG. 4, on the other hand, in SB4, the portable device 30 outputs light for a predetermined time each time a control signal is received. Here, for example, in FIG. 5, the light alarm device 320, the light alarm device 319, the light alarm device 318, the light alarm device 317, and the light alarm device 316 are sequentially irradiated with light for a predetermined time until the above-described restoration operation is performed. The output is repeated, and the light alarm device 323 and the light alarm device 324 are sequentially output for a predetermined time in order. The light alarm device 320 repeatedly outputs light that gives an impression of flowing to the light alarm device 316 via the light alarm device 319, the light alarm device 318, and the light alarm device 317, and from the light alarm device 323. The light that gives the impression of flowing up to the light alarm device 324 is repeatedly output, guides the route R4 to the user of the mobile terminal 411, and routes R2 to the user of the mobile terminals 412, 413, It becomes possible to guide R3.

(Effect of embodiment)
As described above, according to the disaster prevention system 1 of the present embodiment, the result of specifying the abnormal place specifying unit 551 that specifies the place where the abnormality occurred and the result of specifying the terminal place specifying unit 552 that specifies the place of the mobile terminal 40 are used. Since the evacuation route generated based on the information is guided using the plurality of light alarm devices 30, for example, by guiding the evacuation route in consideration of the location of the mobile terminal 40, a large number of evacuees rush to one emergency exit. Thus, it is possible to guide the evacuation route so that it can move smoothly.

  Moreover, according to the disaster prevention system 1, since the communication part 53 receives the electromagnetic wave output from the portable terminal 40, and specifies the place of the portable terminal 40 based on the reception result of the communication part 53, for example, the portable terminal 40 Even if the mobile terminal 40 is provided at a location away from the receiver 50 or a plurality of mobile terminals 40 are provided, the location of the mobile terminal 40 can be reliably identified, and the guidance accuracy of the evacuation route can be improved. It becomes possible.

  Moreover, according to the disaster prevention system 1, since an evacuation route is produced | generated based on a congestion degree, for example, it becomes possible to avoid the congestion in the case of evacuating and to guide an evacuation route so that it can evacuate smoothly.

[Modifications to Embodiment]
Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention may be arbitrarily modified and improved within the scope of the technical idea of the present invention described in the claims. Can do. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above contents, and may vary depending on the implementation environment and details of the configuration of the invention. May be solved, or only some of the effects described above may be achieved. For example, even if the disaster prevention performance cannot be improved as compared with the conventional system, the disaster prevention performance equivalent to the conventional system can be achieved by the system of the present invention different from the conventional system. The problem has been solved.

(About distribution and integration)
Further, each of the electrical components described above is functionally conceptual and does not necessarily need to be physically configured as illustrated. In other words, the specific forms of distribution and integration of each unit are not limited to those shown in the drawings, and all or a part thereof may be functionally or physically distributed or integrated in arbitrary units according to various loads or usage conditions. Can be configured. For example, the light alarm device 30 and the receiver 50 may be configured to be distributed among a plurality of devices, or the devices may be integrated.

(About shape, numerical value, structure, time series)
In addition, regarding the constituent elements exemplified in the embodiment and the drawings, the shape, numerical value, or the structure of a plurality of constituent elements or the mutual relationship in time series are arbitrarily modified and improved within the scope of the technical idea of the present invention. can do.

(About disaster prevention processing)
In FIG. 4, the same processing as SA1 may be performed before SB1. In this case, the processing of SB1 to SB4 is performed only when the notification signal is received.

  In FIG. 4, SA3 to SA6 may be repeatedly performed every time the electric field strength signal in SB3 is received. In this case, when the user of the portable terminal 40 in the building 100 moves as time elapses, the evacuation route to be guided can be changed in consideration of fluctuations in the degree of congestion of the emergency exits 101 and 102 due to the movement. Become.

(About control of light alarm device)
In the embodiment, the case where the light alarm device 30 is caused to emit light using the “control signal” in SA6 of FIG. 4 is not limited to this. For example, the light alarm device 30 may be caused to emit light using a binary synchronous light emission signal indicating “high level” = “output light” and “low level” = “do not output light”.

(About route guidance)
Further, in the embodiment, the case where the route is guided by changing the light emission timing of the light alarm device 30 is described, but the present invention is not limited to this. For example, the route may be guided by changing the light amounts of the light alarm devices 30 from each other. Specifically, when the route R1 is guided to the user of the portable terminal 411 in FIG. 5, the light alarm devices 311 to 313 may be guided by outputting a higher amount of light as it is closer to the entrance / exit 101. On the contrary, in the light alarm devices 311 to 313, guidance may be performed by outputting light having a lower light amount as the distance from the entrance / exit 101 increases.

(About the number of entrances)
Moreover, in embodiment, although the case where two entrances were provided in the building 100 shown in FIG. 1 was demonstrated, it is not restricted to this. For example, the building 100 may be provided with only one doorway, or may be provided with three or more doorways. If the building 100 is provided with only one doorway, an evacuation route is generated using the above-mentioned “first method” in SA5 of FIG. If it is provided, the user may select either the “first method” or the “second method” described above, and the evacuation route may be generated using the selected method. .

(About the “second method” for generating evacuation routes)
In the embodiment, the case where the “congestion degree” is the number of users in the peripheral area of the entrance / exit in the “second method” used in SA5 of FIG. 4 is described, but the present invention is not limited to this. Absent. For example, it is assumed that the “congestion degree” is the number of users in a predetermined area (for example, a peripheral area of a building staircase, an intersection in a corridor, etc.) other than “peripheral area of an entrance / exit”, The evacuation route may be specified based on the degree of congestion of the predetermined area. Specifically, based on the location of the mobile terminal specified in SA4 of FIG. 4, the degree of congestion of the predetermined area is specified, and for the users in the peripheral area of the entrance / exit, the route to the nearest entrance / exit A route that does not pass through the fire source F is specified as an evacuation route, and for a user outside the entrance / exit area, the route passes through a predetermined area having the lowest congestion and reaches the entrance / exit, and does not pass through the fire source F. The route may be specified as an evacuation route. In addition, by combining the identification method of this modification and the identification method of the embodiment, the route passes through a predetermined area with the lowest congestion degree, the route reaches the gateway with the lowest congestion degree, and fire A route that does not pass through the source F may be specified as an evacuation route.

(Number of evacuation routes to guide)
Moreover, you may guide a several evacuation route with respect to the user who carries each portable terminal 40. FIG. Then, when guiding a plurality of evacuation routes, priority is given to the plurality of evacuation routes according to the “congestion degree” described in the embodiment or the modification, and the evacuation route and the evacuation route The evacuation route may be guided so that the user can recognize the priority assigned to the. Specifically, by giving priority so that the priority becomes higher as the degree of congestion is lower, and by guiding so that the light amount output from each light alarm device 30 becomes higher as the priority becomes higher. The evacuation route and the priority of the evacuation route may be guided.

(Appendix)
The guidance system according to Supplementary Note 1 is a guidance system that guides a moving route of a user carrying a mobile terminal using a plurality of light alarm devices provided in a building, and the occurrence of an abnormality in the building Based on the first specifying means for specifying the location, the second specifying means for specifying the location of the mobile terminal in the building, the specifying result of the first specifying means and the specifying result of the second specifying means, A generating unit configured to generate the moving route; and a guiding unit configured to guide the moving route generated by the generating unit using the plurality of light alarm devices.

  The guidance system according to supplementary note 2 is the guidance system according to supplementary note 1, wherein the plurality of light alarm devices include reception means for receiving radio waves output from the portable terminal, and the second identification means is the reception means. The location of the portable terminal is specified based on the reception result of the means.

  The guidance system according to supplementary note 3 is the guidance system according to supplementary note 1 or 2, wherein the abnormality is a fire and the movement route is an evacuation route.

  The guidance system according to supplementary note 4 is the guidance system according to supplementary note 3, wherein the building is provided with a plurality of evacuation openings, each of the plurality of users carrying the portable terminal, and the second identification The means specifies each location of the portable terminal carried by each of a plurality of users based on the reception result of the reception means, and the generation means determines the building based on the specification result of the second specification means The degree of congestion that is the degree of congestion by the plurality of users in the predetermined area is specified, and the evacuation route that reaches at least one of the plurality of evacuation openings is generated based on the specified degree of congestion .

(Additional effects)
According to the guidance system described in Supplementary Note 1, the travel route generated based on the identification result of the first identification unit that identifies the location of occurrence of the abnormality and the identification result of the second identification unit that identifies the location of the mobile terminal Since it guides using a plurality of light alarm devices, for example, by guiding the movement route in consideration of the location of the mobile terminal, it is possible to prevent a large number of evacuees from rushing into one emergency exit, It is possible to guide the travel route so that it can move smoothly.

  According to the guidance system described in the supplementary note 2, the reception unit receives the radio wave output from the mobile terminal, and specifies the location of the mobile terminal based on the reception result of the reception unit. Even if the mobile terminal is provided at a remote location or a plurality of mobile terminals are provided, the location of the mobile terminal can be reliably specified, and the guidance accuracy of the travel route can be improved.

  According to the guidance system described in Supplementary Note 3, since the abnormality is a fire and the movement route is an evacuation route, for example, it is possible to guide the evacuation route so that evacuation can be performed smoothly.

  According to the guidance system described in Supplementary Note 4, since the evacuation route is generated based on the degree of congestion, for example, it is possible to avoid the congestion when evacuating and guide the evacuation route so that the evacuation can be smoothly performed. .

DESCRIPTION OF SYMBOLS 1 Disaster prevention system 11 Corridor 12 Corridor 13 Corridor 14 Corridor 15 Corridor 20 Sensor 30 Light alarm device 31 Communication part 32 Light emission part 33 Light emission drive part 34 Memory | storage part 35 Control part 40 Portable terminal 50 Receiver 51 Input part 52 Output part 53 Communication Unit 54 storage unit 55 control unit 100 building 101 entrance 102 entrance 211 sensor 212 sensor 213 sensor 214 sensor 215 sensor 216 sensor 311 light alarm device 312 light alarm device 313 light alarm device 314 light alarm device 315 light Alarm device 316 Light alarm device 317 Light alarm device 318 Light alarm device 319 Light alarm device 320 Light alarm device 321 Light alarm device 322 Light alarm device 323 Light alarm device 324 Light alarm device 411 Mobile terminal 412 Mobile terminal 413 Mobile terminal 541 Map information 542 Installation Location specific information 551 abnormal location identification unit 552 terminal location detection part 553 generating portion 554 guide section F fire source R1 route R2 Route R3 route R4 Route

Claims (4)

A guidance system that guides a moving route of a user carrying a mobile terminal using a plurality of light alarm devices provided in a building,
First identifying means for identifying an occurrence location of an abnormality in the building;
Second specifying means for specifying the location of the mobile terminal in the building;
Generating means for generating the travel route based on the specifying result of the first specifying means and the specifying result of the second specifying means;
Guidance means for guiding the travel route generated by the generation means using the plurality of light alarm devices;
A guidance system comprising: The plurality of light alarm devices comprise receiving means for receiving radio waves output from the portable terminal,
The second specifying means specifies the location of the mobile terminal based on a reception result of the receiving means.
The guidance system according to claim 1. The abnormality is a fire,
The travel route is an evacuation route.
The guidance system according to claim 1 or 2. The building is provided with a plurality of evacuation exits,
Each of a plurality of users carries the mobile terminal,
The second specifying means specifies each location of the portable terminal carried by each of a plurality of users based on a reception result of the receiving means,
The generating means specifies the degree of congestion that is the degree of congestion by the plurality of users in the predetermined area of the building based on the specification result of the second specifying means, and based on the specified degree of congestion, Generating the evacuation route to at least one of the plurality of evacuation exits;
The guidance system according to claim 3.

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