JP2015133003A - Alarm server for pedestrian and portable terminal equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an alarm server for a pedestrian and portable terminal equipment capable of notifying a user of a danger correspondingly to a peripheral state when the user is using a smartphone while walking.SOLUTION: An alarm server for a pedestrian configured to notify an operation pedestrian as a pedestrian who is operating portable terminal equipment of peripheral information in a predetermined range where the operation pedestrian is walking to prevent an accident by the operation pedestrian includes: a mobile unit number detection part for detecting the number of mobile units as the number of mobile units in the predetermined range; a congestion detection part for comparing mobile unit density obtained from the number of the mobile units with a preliminarily set mobile unit density threshold, and for detecting whether or not the predetermined range is in a congested congestion state; and an information notification part for notifying the operation pedestrian of the peripheral information including congestion information indicating the congestion state in the predetermined range.

Description

  The present invention relates to a pedestrian alarm server that notifies a user who is operating a mobile phone or a smartphone such as an e-mail or a game during walking, and a portable terminal device that is notified of the danger from the pedestrian alarm server. It is about.

  In recent years, many people have carried portable terminal devices such as mobile phones or smartphones. On the other hand, a mobile phone or a smartphone (hereinafter referred to as a mobile terminal device) concentrates on e-mails or games while walking, so that the user may be insufficiently aware of danger in front or under his feet. Thus, as a result of insufficient recognition of danger in front of the user or under the feet, an accident that collides with another person or an obstacle or trips over a step such as a staircase is likely to occur.

  Therefore, in response to the above-described problem of so-called “walking smartphone (smartphone)” or “while smartphone”, the user's walking is detected using a sensor (for example, an acceleration sensor) of the mobile terminal device, and the mobile phone while walking A technique for calling attention to a user when using a terminal device has been proposed (see, for example, Patent Document 1).

JP 2012-253708 A

However, the technique for preventing the “walking smartphone” described above cannot sufficiently utilize the application when the user applies this technique and uses an application that is used while walking, such as pedestrian navigation.
Even if a “walking smartphone” is performed, the risk of walking is less than when there are people or obstacles in the vicinity, and it is not always necessary to prevent the “walking smartphone”.

  The present invention has been made in view of such circumstances, and a pedestrian alarm server and a portable terminal capable of notifying a user of a danger corresponding to the surrounding state when a “walking smartphone” is performed. An object is to provide an apparatus.

  The present invention has been made to solve the above-described problems, and the alarm server for pedestrians of the present invention is designed for an operation pedestrian who is a pedestrian who is operating a mobile terminal device, to which the operation pedestrian walks. The surrounding information detection is a pedestrian alarm server that notifies surrounding information in a predetermined range and prevents an accident caused by the operating pedestrian, and detects the number of moving bodies that is the number of moving bodies in the predetermined range. And a congestion detector that compares the moving body density obtained from the number of moving bodies with a preset moving body density threshold and detects whether or not the predetermined range is congested. And an information notification unit for notifying the operation pedestrian of peripheral information including congestion information indicating the congestion state in the predetermined range.

  In the pedestrian alarm server of the present invention, the information notification unit notifies the portable terminal device carried by the operation pedestrian of congestion information indicating whether or not the congestion state exists as the peripheral information. It is characterized by.

  The alarm server for pedestrians of the present invention refers to a risk map database in which presence / absence of a dangerous place in the predetermined range is stored and the risk map database, and the predetermined range where the operation pedestrian walks is It further comprises a danger judgment unit for judging whether or not it is dangerous.

  In the alarm server for pedestrians of the present invention, the information notification unit is dangerous for the portable terminal device carried by the operation pedestrian as the peripheral information, the predetermined range where the operation pedestrian walks is dangerous. It is characterized by notifying danger information indicating whether or not.

  The mobile terminal device according to the present invention is a mobile terminal device in which peripheral information in an existing predetermined range is notified from an alarm server for a pedestrian having jurisdiction over the predetermined range, and the mobile terminal device in the predetermined range included in the peripheral information A congestion determination unit that determines whether or not the congestion information indicating the congestion state indicates congestion, and a walking determination that detects whether or not an operation pedestrian who is a pedestrian carrying the mobile terminal device is walking And the congestion determination unit determine from the congestion information that the predetermined range is congested, and the walking determination unit detects that the pedestrian is walking, the portable terminal device And an information notifying unit for notifying a user of the operation pedestrian to be carried.

  According to this invention, since the alarm server for pedestrians always detects the state of the predetermined range in which the pedestrian is walking as the peripheral information, it is real-time in the state of the predetermined range in which the pedestrian is walking. Corresponding to the above, it is possible to notify the pedestrian of the danger in performing the “walking smartphone”.

It is a conceptual diagram explaining the alarm system for pedestrians using the alarm server for pedestrians by 1st Embodiment of this invention. It is a conceptual diagram explaining the alarm system for pedestrians using the alarm server for pedestrians by 2nd Embodiment of this invention. It is a conceptual diagram explaining the alarm system for pedestrians using the alarm server for pedestrians by 4th Embodiment of this invention. It is a flowchart which shows the operation example of the alarm server 5 for pedestrians in the alarm system for pedestrians by 4th Embodiment. It is a flowchart which shows the operation example of the portable terminal device 6 in the alarm system for pedestrians by 4th this embodiment. It is a conceptual diagram explaining the alarm system for pedestrians using the alarm server for pedestrians by 5th Embodiment of this invention. It is a flowchart which shows the operation example of the alarm server 7 for pedestrians in the alarm system for pedestrians by this 5th Embodiment. It is a flowchart which shows the operation example of the portable terminal device 8 in the alarm system for pedestrians by this 5th Embodiment.

<First Embodiment>
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a conceptual diagram illustrating a pedestrian alarm system using a pedestrian alarm server according to a first embodiment of the present invention.
In FIG. 1, the pedestrian alarm system includes a pedestrian alarm server 1 and an imaging device 2. The imaging device 2 is, for example, a CCD camera or the like, and is arranged above the detection range so that a predetermined detection range can be imaged. For example, if it is indoors, it is arranged on the ceiling of the room, and the imaging direction is set so that the floor portion of the entire room can be imaged. If it is outdoors, it is arranged at a position where the sidewalk part in front of the building where it is located can be imaged from above.

  Moreover, in any case of indoor and outdoor, it is arranged at a position for capturing imaged image data for detecting a moving body in a region to be imaged (the detection range). If possible, by installing the imaging device 2 so as to be in an imaging direction perpendicular to a horizontal plane such as a floor or a sidewalk, it is possible to suppress the generation of a moving body that is shadowed by an obstacle, and a highly accurate moving body Captured image data for detection can be obtained. The imaging device 2 outputs the captured image data to the pedestrian alarm server 1. The moving body indicates a moving object, such as a pedestrian, bicycle, dog or cat animal on the sidewalk.

The pedestrian alarm server 1 detects a congestion state in a detection range that is an imaging range of the imaging device 2 based on captured image data supplied from the imaging device 2. When the pedestrian alarm server 1 determines that the detection range is congested by the moving body (the density of the moving body in the detection range is high), the notification signal indicating that the pedestrian is congested. To be notified. Here, the density of the moving body indicates the number of moving bodies per unit area of the moving body in the detection range. For example, the moving object density is obtained by dividing the number of moving objects in the detection range by the area of the detection range.
The pedestrian alarm server 1 includes an imaging data input unit 11, a peripheral information detection unit 12, a congestion detection unit 13, and a congestion notification unit 14.

The imaging data input unit 11 inputs the captured image data supplied from the imaging device 2 and outputs it to the peripheral information detection unit 12. Here, the imaging data input unit 11 may have a function of converting the captured image data supplied from the imaging device 2 into a format used by the peripheral information detection unit 12.
The peripheral information detection unit 12 analyzes the captured image data and detects the number of moving objects. Here, the peripheral information detection unit 12 detects, for example, element images whose positions change periodically (for example, every 0.1 second) in the captured image data, and tracks each of the element images. Then, the surrounding information detection unit 12 sets the number of the tracked element images in the captured image data as the number of moving objects that is the number of moving objects. The peripheral information detection unit 12 outputs the detected number of moving objects to the congestion detection unit 13 for each cycle.

The congestion detection unit 13 divides the number of moving bodies supplied from the surrounding information detection unit 12 by the area of the detection range, sets the result of the division as the moving body density, and compares it with a preset moving body density threshold. This moving body density threshold is a moving body density that is set in advance as a density at which each detection range is congested with respect to each detection range. Here, when the moving body density is less than the moving body density threshold, the congestion detection unit 13 determines that the detection range is a non-congested state where there are few moving bodies and is not congested. On the other hand, when the moving body density is equal to or higher than the moving body density threshold, the congestion detection unit 13 determines that the moving state is congested with many moving bodies. The congestion detection unit 13 outputs peripheral information including congestion information indicating whether or not the detection range is congested to the congestion notification unit 14.
In the present embodiment, the congestion detection unit 13 is configured to determine the congestion state using the moving body density and the moving body density threshold. However, the number of moving bodies is used as it is for each detection range. It is good also as a structure which compares with the preset moving body number threshold value and determines a congestion state. This threshold value for the number of moving objects is the number of moving objects set in advance as the number of detection ranges that are congested with respect to each of the detection ranges.

  When the surrounding information is supplied from the congestion detecting unit 13, the congestion notifying unit 14 determines whether the congestion information in the surrounding information is in a congested state or a non-congested state. Here, when the congestion information indicates a non-congested state, the congestion notification unit 14 does not perform notification for a pedestrian or the like in the detection range. On the other hand, when the congestion information indicates a congestion state, the congestion notification unit 14 performs notification for a pedestrian or the like in the detection range. This notification is performed in particular to call attention to a pedestrian operating a mobile terminal device (for example, a mobile phone, a smartphone, a tablet terminal, etc.). That is, as the notification signal, information that interrupts the operation of the mobile terminal device while walking is notified directly or indirectly by an audio signal, an optical signal, or the like.

If it is an audio signal, it is directly “the surrounding area is congested, so please interrupt the operation of the mobile terminal device while walking”. Indirectly, play music at a loud volume, try to check which sound is heard from, stop the pedestrian or shift the line of sight from the display screen of the mobile terminal device, and observe the surroundings Let it be done. In the case of an optical signal, it is conceivable to embed a plurality of lights in a detection range such as a sidewalk if indoors and in a detection range such as a sidewalk if outdoor, and perform blinking processing to observe the entire detection range.
In the present embodiment, by using either an audio signal or an optical signal, the pedestrian is alerted to observe the surroundings, so that the operating pedestrian operating the portable terminal device in the pedestrian In contrast, it is possible to arouse observation of the entire detection range, and collision between pedestrians can be avoided.

<Second Embodiment>
The second embodiment of the present invention will be described below with reference to the drawings. FIG. 2 is a conceptual diagram illustrating a pedestrian alarm system using a pedestrian alarm server according to a second embodiment of the present invention. This second embodiment is premised on use indoors.
In FIG. 2, the pedestrian alarm system includes a pedestrian alarm server 3 and an IC (Integrated Circuit) tag reader 4 (IC card reader 4). The IC tag reader 4 is provided, for example, at a gate that reads information on an IC tag, which is an IC chip embedded in an IC card used when entering, and restricts entrance to buildings such as companies and public facilities. Yes. In addition to an IC card, an admission ticket embedded with an IC chip used when entering an art museum, a museum, an amusement park, a zoo, a competition facility, or the like can also be used. In the present embodiment, the building itself is the detection range.

The IC tag reader 4 is a card reader, and is provided in each of one or more entrance gates. Each time a person enters through the gate, the IC tag reader 4 recognizes the IC chip and enters the pedestrian alarm server 3. Output a signal. The IC tag reader 4 recognizes the IC chip and outputs an exit signal to the pedestrian alarm server 3 every time a person leaves the gate and exits.
The pedestrian alarm server 3 counts each of the entrance signal and the exit signal, manages the congestion state in the building that is the detection range, and determines that it is congested. A notification signal indicating that the pedestrian is crowded is notified.
The pedestrian alarm server 3 includes a detection data input unit 31, a surrounding information detection unit 32, a congestion detection unit 33, and a congestion notification unit 34.

The detection data input unit 31 outputs an entrance signal and an exit signal supplied from the IC tag reader 4 to the peripheral information detection unit 32. Here, the imaging data input unit 11 may have a function of converting an entrance signal and an exit signal supplied from the IC tag reader 4 into a format used by the peripheral information detection unit 32.
The surrounding information detection unit 32 detects the number of people in the detection range using each of the entrance signal and the exit signal. Here, for example, when one entrance signal is supplied, the surrounding information detection unit 32 increments the number of visitors that is the number of visitors in the detection range (add 1 to the number of visitors), When one exit signal is supplied, the number of visitors in the detection range is decremented (1 is subtracted). Then, the surrounding information detection unit 32 outputs the detected number of visitors to the congestion detection unit 33 in a predetermined cycle (for example, every minute).

  The congestion detection unit 33 compares the number of visitors supplied from the surrounding information detection unit 32 with a preset threshold for the number of visitors. Here, when the number of visitors is less than the number of visitors threshold, the congestion detection unit 33 determines that the number of visitors in the detection range is small and the congestion is not crowded. On the other hand, when the number of visitors is equal to or greater than the number of visitors threshold, the congestion detection unit 33 determines that the number of visitors is crowded in the detection range. The congestion detection unit 33 outputs peripheral information including congestion information indicating whether or not the detection range is congested to the congestion notification unit 34.

  When the peripheral information is supplied from the congestion detector 33, the congestion notification unit 34 determines whether the congestion information in the peripheral information is in a congested state or a non-congested state. Here, when the congestion information indicates a non-congested state, the congestion notification unit 34 does not perform notification for visitors or the like in the detection range. On the other hand, when the congestion information indicates a congestion state, the congestion notification unit 34 performs notification for the visitors in the detection range. This notification is performed in particular to call attention to visitors walking while operating the mobile terminal device. That is, as the notification signal, information that interrupts the operation of the mobile terminal device while walking is notified directly or indirectly by an audio signal, an optical signal, or the like.

If it is an audio signal, it is directly “the surrounding area is congested, so please interrupt the operation of the mobile terminal device while walking”. Indirectly, music is played at a low volume in museums and museums for a short time, while amusement facilities such as amusement parks try to check from which sound can be heard at a high volume, and stop the visitors. Alternatively, the line of sight is shifted to the periphery from the display screen of the mobile terminal device, and the periphery is observed. In the case of an optical signal, it is conceivable to embed a plurality of lights in a detection range such as a sidewalk if indoors and in a detection range such as a sidewalk if outdoor, and perform blinking processing to observe the entire detection range.
In this embodiment, by using either an audio signal or an optical signal, the attendant who operates the mobile terminal device in the attendee (operation) is urged to observe the surroundings. A pedestrian) can be aroused to observe the entire detection range, and a collision between pedestrians can be avoided.

<Third Embodiment>
The third embodiment of the present invention will be described below with reference to the drawings. The third embodiment has the same configuration as that of FIG. 2 of the second embodiment. Hereinafter, differences of the third embodiment from the second embodiment will be described.
In the third embodiment, the IC tag reader 4 is provided in each room of a building and detects the number of visitors in the room. That is, the IC tag reader 4 periodically transmits a confirmation signal to an IC tag mounted on an IC card or the like carried by a room attendant. When the IC tag reader 4 receives a response signal from the IC tag mounted on the IC card or the like in response to the confirmation signal, the IC tag reader 4 reads the identification number included in the response signal and detects the number of types of the identification number as the number of visitors. The data is supplied to the peripheral information detection unit 32 via the data input unit 31.

The subsequent operations of the congestion detection unit 33 and the congestion notification unit 34 are the same as those in the second embodiment.
In this embodiment, the attendee operating the portable terminal device in the attendee by using either an audio signal or an optical signal to alert the attendee in the room to observe the surroundings. It is possible to arouse the observation of the entire detection range even for the (operation pedestrian), and a collision between pedestrians can be avoided.

<Fourth Embodiment>
Hereinafter, a fourth embodiment of the present invention will be described with reference to the drawings. FIG. 3 is a conceptual diagram for explaining a pedestrian alarm system using a pedestrian alarm server according to a fourth embodiment of the present invention. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

In FIG. 3, the pedestrian alarm system includes a pedestrian alarm server 5, an imaging device 2, and a mobile terminal device 6. The imaging device 2 has the same configuration as that of the first embodiment and is arranged in the same manner as that of the first embodiment, and a description thereof will be omitted.
In the fourth embodiment, the pedestrian alarm server 5 detects the congestion state (congested state or non-congested state) of the detection range (walking or indoors) from the captured image data captured by the imaging device 2. Then, the pedestrian alarm server 5 notifies the mobile terminal device 6 of the peripheral information including the congestion information indicating the congestion status. The mobile terminal device 6 alerts a walking operator (operating pedestrian) who is operating himself / herself in response to this notification.

The pedestrian alarm server 5 includes an imaging data input unit 11, a surrounding information detection unit 12, a congestion detection unit 13, and an information notification unit 54. Here, each of the imaging data input unit 11, the surrounding information detection unit 12, and the congestion detection unit 13 is the same as each of the imaging data input unit 11, the surrounding information detection unit 12, and the congestion detection unit 13 in the first embodiment. .
The information notification unit 54 transmits the peripheral information supplied from the congestion detection unit 13 to the mobile terminal device 6. This transmission uses broadcast (broadcast) of information for calling attention to a mobile terminal device of a user registered in advance within the detection range using a wireless communication network or a wireless LAN network of a mobile phone. Is shown.

The mobile terminal device 6 is installed (implemented) with an application program corresponding to the present embodiment in addition to the functions of a normal mobile terminal device. When this application program is activated, a CPU (Central Processing Unit) in the mobile terminal device 6 starts operation of functions as the congestion determination unit 61, the walking determination unit 62, the information notification unit 63, and the application activation determination unit 64. .
When the congestion determination unit 61 receives the peripheral information transmitted by the pedestrian alarm server 5, the congestion determination unit 61 determines whether the congestion information in the peripheral information is in a congested state.

  The walking determination unit 62 drives an acceleration sensor (not shown) and acquires acceleration data of the acceleration sensor. Then, the walking determination unit 62 determines whether or not the acquired acceleration data exceeds a preset acceleration threshold value. Here, the walking determination unit 62 determines that the pedestrian carrying the mobile terminal device 6 is walking when the acquired acceleration data exceeds a preset acceleration threshold value. On the other hand, the walking determination unit 62 determines that the pedestrian carrying the mobile terminal device 6 is not walking when the acquired acceleration data is equal to or less than a preset acceleration threshold value.

  The walking determination unit 62 may determine whether or not a pedestrian is walking using the GPS function. That is, the walking determination unit 62 acquires GPS position information at a predetermined cycle, and whether or not the pedestrian is walking depending on whether or not the position for each cycle has changed beyond a preset threshold distance. You may comprise so that determination may be performed. In this configuration, the walking determination unit 62 allows the pedestrian carrying the mobile terminal device 6 to walk when the distance at which the position acquired for each period has changed exceeds a preset threshold distance. It is determined that the user is walking (walking). On the other hand, the walking determination unit 62 determines that the pedestrian carrying the mobile terminal device 6 is not walking when the distance at which the position acquired for each period has changed is equal to or less than a preset threshold distance.

The information notification unit 63 determines that the congestion determination unit 61 is in a congested state, and the walking determination unit 62 determines that the pedestrian is walking, and operates the mobile terminal device while walking against the pedestrian. Notify the alert information to urge you not to perform.
For example, the information notification unit 63 displays a character display such as “It is dangerous to operate the mobile terminal device while walking” on the display screen of the mobile terminal device 6 to alert the pedestrian.
The information notification unit 63 may display the character display on the display screen, lock the operation of the application that the pedestrian is running, and do not unlock the application unless the pedestrian stops. .

  The application activation determination unit 64 determines whether or not an application is activated on the mobile terminal device 6 (that is, the mobile terminal device 6 is operated). For example, the application activation determination unit 64 refers to a list of activated applications in the OS of the mobile terminal device 6 and determines whether there is an activated application.

Next, the operation of the pedestrian alarm system according to the present embodiment will be described with reference to the drawings. FIG. 4 is a flowchart showing an operation example of the pedestrian alarm server 5 in the pedestrian alarm system according to the present embodiment.
Step S11:
The imaging data input unit 11 reads the count time of its own counter, and determines whether or not the read count time exceeds a predetermined period (for example, 0.5 seconds).
At this time, if the count time exceeds a certain period, the imaging data input unit 11 resets the counter time of the counter to “0” and newly starts counting to the counter. The process proceeds to step S12.
On the other hand, if the count time is less than or equal to a certain period, the imaging data input unit 11 continues the count operation of the counter and advances the process to step S11.

Step S12:
The imaging data input unit 11 inputs captured image data captured by the imaging device 2. Then, the imaging data input unit 11 outputs the captured image data acquired from the imaging device 2 to the peripheral information detection unit 12.

Step S13:
The peripheral information detection unit 12 analyzes the captured image data supplied from the captured data input unit 11 and detects the number of moving objects within the detection range. Here, for example, in the captured image data, the peripheral information detection unit 12 detects a change in the position of the element pixel in the captured image data periodically supplied from the captured data input unit 11, and an element image in which this position changes. Keep track of each of them. Then, the surrounding information detection unit 12 sets the number of the tracked element images in the captured image data as the number of moving objects that is the number of moving objects. The surrounding information detection unit 12 outputs the detected number of moving objects to the congestion detection unit 13 for each cycle, and the process proceeds to step S14.

Step S14:
The congestion detection unit 13 divides the number of moving objects in the detection range supplied from the surrounding information detection unit 12 by the area of the detection range to obtain the moving object density.
Then, the congestion detection unit 13 compares the obtained moving body density with a preset moving body density threshold.
If the moving body density is less than the moving body density threshold, the congestion detection unit 13 determines that the detection range is not crowded with few moving bodies and advances the process to step S11.
On the other hand, when the moving body density is equal to or higher than the moving body density threshold, the congestion detection unit 13 determines that the moving state is congested with many moving bodies. The congestion detection unit 13 outputs peripheral information including congestion information indicating whether or not the detection range is congested to the information notification unit 54.
Then, the congestion detector 13 advances the process to step S15.

Step S15:
When the peripheral information is supplied from the congestion detector 13, the information notification unit 54 transmits the supplied peripheral information to the mobile terminal device 6. For example, the information notification unit 54 indicates that information for calling attention is distributed by broadcast (broadcast) to a user's portable terminal device registered in advance in the detection range of the pedestrian alarm system.
And the information notification part 54 advances a process to step S11.

Next, FIG. 5 is a flowchart showing an operation example of the mobile terminal device 6 in the alarm system for pedestrians according to the present embodiment.
Step S21:
The congestion determination unit 61 detects whether or not surrounding information from the pedestrian alarm server 5 has been received.
At this time, when the surrounding information from the pedestrian alarm server 5 is received, the congestion determination unit 61 advances the process to step S22.
On the other hand, when the surrounding information from the pedestrian alarm server 5 is not received, the congestion determination unit 61 advances the process to step S21.

Step S22:
When the congestion determination unit 61 receives the peripheral information transmitted by the pedestrian alarm server 5, the congestion determination unit 61 determines whether an application is activated on the mobile terminal device 6.
At this time, if the application is activated, the congestion determination unit 61 advances the process to step S23.
And the congestion determination part 61 advances a process to step S21, when the application is not started.

Step S23:
When the congestion determination unit 61 receives the peripheral information transmitted by the pedestrian alarm server 5, the congestion determination unit 61 determines whether the congestion information in the peripheral information is in a congested state.
At this time, if the congestion information is in a congestion state, the congestion determination unit 61 advances the process to step S24.
On the other hand, when the congestion information is in a non-congested state, the congestion determination unit 61 advances the process to step S21.

Step S24:
The walking determination unit 62 drives an acceleration sensor (not shown) and acquires acceleration data of the acceleration sensor. Further, after obtaining acceleration data from the acceleration sensor, the acceleration sensor is stopped. Here, the walking determination unit 62 controls whether to drive or stop depending on whether power is supplied to the acceleration sensor, for example.
And the walk determination part 62 advances a process to step S25.

Step S25:
The walking determination unit 62 determines whether or not the acquired acceleration data exceeds a preset acceleration threshold value. At this time, when the acquired acceleration data exceeds a preset acceleration threshold value, the walking determination unit 62 determines that a pedestrian carrying the mobile terminal device 6 is walking, and the process proceeds to step S26. Proceed to On the other hand, when the acquired acceleration data is equal to or less than a preset acceleration threshold, the walking determination unit 62 determines that the pedestrian carrying the mobile terminal device 6 is not walking, and advances the process to step S21.

Step S26:
The information notifying unit 63 determines that the congestion determination unit 61 is in a congested state and the walking determination unit 62 determines that the pedestrian is walking. Notify the alert information to urge not to perform the operation.

In this embodiment, using either an audio signal or an image signal, the mobile terminal device 6 is operated, and the operator who is walking is temporarily stopped and the surrounding area is observed. Therefore, it is possible to alert the operator who is walking by operating the mobile terminal device in the attendee, that it is dangerous to operate the mobile terminal device 6 in the detection range. Collisions between each other can be avoided.
In the present embodiment, the configuration for detecting congestion information has been described using the congestion detection unit 13 similar to that in the first embodiment. However, as in the second and third embodiments, the congestion is detected. The configuration of the detection unit 33 may be used.

<Fifth Embodiment>
The fifth embodiment of the present invention will be described below with reference to the drawings. FIG. 6 is a conceptual diagram for explaining a pedestrian alarm system using a pedestrian alarm server according to a fifth embodiment of the present invention. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted. In FIG. 6, the pedestrian alarm system includes a pedestrian alarm server 7, an imaging device 2, and a mobile terminal device 8. The imaging device 2 has the same configuration as that of the first embodiment and is arranged in the same manner as that of the first embodiment, and a description thereof will be omitted. Moreover, in this embodiment, the same code | symbol is attached | subjected to the structure similar to 1st Embodiment and 4th Embodiment, and the description is abbreviate | omitted.

  In the fifth embodiment, the pedestrian alarm server 7 uses the captured image data captured by the imaging device 2 to detect the congestion state (congestion state or non-congestion state) of the detection range (walking or indoors) and the detection range. Detect dangerous spots in Then, the pedestrian alarm server 7 notifies the portable terminal device 8 of the peripheral information including the congestion information indicating the congestion state and the danger information which is the information on the dangerous place. The mobile terminal device 8 alerts an operator (pedestrian) who is operating the mobile terminal device 8.

The pedestrian alarm server 7 includes an imaging data input unit 11, a surrounding information detection unit 12, a congestion detection unit 13, a dangerous place information detection unit 74, an information notification unit 75, and a risk map database 76.
The risk map database 76 indicates whether or not a dangerous place is within the detection range when the mobile terminal device 8 is operated while walking even if it is not crowded. The risk map database 76 includes, for example, stairs, the number of pillars, and the presence or absence of protrusions when indoors, and telegraph poles, sidewalk steps and protrusions when outdoors, etc. This indicates whether there is a place where an accident occurred or where there is a possibility of an accident occurring in the future.

The dangerous place information detection unit 74 refers to the risk map database 76 and detects the presence or absence of a dangerous place in the detection range of the pedestrian alarm server 7.
In addition, the dangerous place information detection unit 74 refers to the risk map database 76 and outputs dangerous information indicating that a dangerous place exists to the information notification unit 75 when there is a dangerous place in the detection range. Here, the danger information indicates the dangerous state when the dangerous part exists, and outputs the dangerous information indicating the non-dangerous state when the dangerous part does not exist to the information notification unit 75.

  The information notification unit 75 transmits peripheral information including the congestion information supplied from the congestion detection unit 13 and the danger information supplied from the dangerous place information detection unit 74 to the mobile terminal device 8. As in the fourth embodiment, this transmission uses information such as a mobile phone wireless communication network or a wireless LAN network to prompt a user's mobile terminal device registered in the detection range to call attention. It shows that it is distributed by broadcast.

The mobile terminal device 8 is installed (implemented) with an application program corresponding to the present embodiment in addition to the functions of a normal mobile terminal device. When this application program is activated, a CPU (Central Processing Unit) in the mobile terminal device 8 functions as a congestion determination unit 61, a walking determination unit 62, an information notification unit 83, an application activation determination unit 64, and a risk determination unit 85. Start the operation.
When the congestion determination unit 61 receives the peripheral information transmitted by the pedestrian alarm server 7, the congestion determination unit 61 determines whether the congestion information in the peripheral information is in a congested state.
Upon receiving the peripheral information transmitted from the pedestrian alarm server 7, the risk determination unit 85 determines whether the risk information in the peripheral information is in a dangerous state.

The information notification unit 83 is either the case where the congestion determination unit 61 determines that it is in a congested state or the case where the danger determination unit 85 determines that it is in a dangerous state, and the walking determination unit 62 is a pedestrian. When it is determined that the person is walking, notification information for alerting the pedestrian not to operate the portable terminal device while walking is notified.
For example, if the information notification unit 83 is in a crowded state and walking, “It is crowded, so there is a possibility of contact with other pedestrians, so it is dangerous to operate the mobile terminal device while walking.” Is displayed on the display screen of the mobile terminal device 8 to alert the pedestrian.

In addition, the information notifying unit 83 is in a dangerous state and walking, “It is not crowded, but there are places where attention is required for walking, so it is dangerous to operate the mobile terminal device while walking.” Is displayed on the display screen of the mobile terminal device 8 to alert the pedestrian.
Further, the information notification unit 83 may display the character display on the display screen, lock the operation of the application activated by the pedestrian, and do not unlock the application unless the pedestrian stops. .

Next, the operation of the pedestrian alarm system according to the present embodiment will be described with reference to the drawings. FIG. 7 is a flowchart showing an operation example of the pedestrian alarm server 7 in the pedestrian alarm system according to the present embodiment.
Step S31:
The imaging data input unit 11 reads the count time of its own counter, and determines whether or not the read count time exceeds a predetermined period (for example, 0.5 seconds).
At this time, if the count time exceeds a certain period, the imaging data input unit 11 resets the counter time of the counter to “0” and newly starts counting to the counter. Then, the process proceeds to step S32.
On the other hand, if the count time is less than or equal to a certain period, the imaging data input unit 11 continues the count operation of the counter and advances the process to step S31.

Step S32:
The dangerous place information detection unit 74 refers to the danger map database 76 and detects the presence or absence of a dangerous place in the detection range of the pedestrian alarm system.
And the dangerous place information detection part 74 advances a process to step S33.

Step S33:
The dangerous place information detection unit 74 describes the presence / absence of the dangerous place as dangerous information, and advances the process to step S34.
At this time, the dangerous place information detection unit 74 notifies the information notification unit 75 of dangerous information indicating a dangerous state when a return point exists in the detection range. On the other hand, when there is no return location in the detection range, the dangerous place information detection unit 74 notifies the information notification unit 75 of dangerous information indicating a non-dangerous state.

Step S34:
The imaging data input unit 11 inputs captured image data captured by the imaging device 2. Then, the imaging data input unit 11 outputs the captured image data acquired from the imaging device 2 to the peripheral information detection unit 12.
And the imaging data input part 11 advances a process to step S35.

Step S35:
The peripheral information detection unit 12 analyzes the captured image data supplied from the captured data input unit 11 and detects the number of moving objects within the detection range. Here, for example, in the captured image data, the peripheral information detection unit 12 detects a change in the position of the element pixel in the captured image data periodically supplied from the captured data input unit 11, and an element image in which this position changes. Keep track of each of them. Then, the surrounding information detection unit 12 sets the number of the tracked element images in the captured image data as the number of moving objects that is the number of moving objects. The peripheral information detection unit 12 outputs the detected number of moving objects to the congestion detection unit 13 for each cycle.

Next, the congestion detection unit 13 divides the number of moving objects in the detection range supplied from the surrounding information detection unit 12 by the area of the detection range to obtain the moving object density.
The congestion detection unit 13 compares the obtained moving body density with a preset moving body density threshold.
When the moving object density is less than the moving object density threshold, the congestion detection unit 13 determines that the detection range is a non-congested state where there are few moving objects and the object is not congested. In addition, the congestion detection unit 13 outputs congestion information indicating non-congestion information to the information notification unit 75.
On the other hand, when the moving body density is equal to or higher than the moving body density threshold, the congestion detection unit 13 determines that the moving state is congested with many moving bodies. In addition, the congestion detection unit 13 outputs congestion information indicating whether or not the detection range is congested to the information notification unit 75.
Then, the congestion detection unit 13 advances the process to step S36.

Step S36:
The information notification unit 75 determines whether the congestion information supplied from the congestion detection unit 13 is in a congested state or the danger information supplied from the dangerous place information detection unit 74 is in a dangerous state.
At this time, if the congestion information is in the congestion state or the danger information is in the danger state, the information notification unit 75 advances the process to step S37.
On the other hand, when the congestion information is neither the congestion state nor the danger information is the danger state, that is, when the congestion information is the non-congestion state and the danger information is the non-danger state, the information notification unit 75 Proceed to S31.

Step S37:
The information notification unit 75 transmits peripheral information including congestion information and danger information to the mobile terminal device 8. As in the fourth embodiment, this transmission is performed by using a wireless communication network or a wireless LAN network of a mobile phone, and peripheral information that prompts a user's mobile terminal device registered in the detection range to call attention. Is broadcast (broadcast).

Next, FIG. 8 is a flowchart showing an operation example of the mobile terminal device 8 in the pedestrian alarm system according to the present embodiment.
Step S41:
The congestion determination unit 61 detects whether or not surrounding information from the pedestrian alarm server 7 has been received.
At this time, when the surrounding information from the pedestrian alarm server 7 is received, the congestion determination unit 61 advances the process to step S42.
On the other hand, when the surrounding information from the pedestrian alarm server 7 is not received, the congestion determination unit 61 advances the process to step S41.

Step S42:
When the congestion determination unit 61 receives the peripheral information transmitted by the pedestrian alarm server 5, the congestion determination unit 61 determines whether an application is activated on the mobile terminal device 8.
At this time, when the application is activated, the congestion determination unit 61 advances the process to step S43.
And the congestion determination part 61 advances a process to step S41, when the application is not started.

Step S43:
Upon receiving the peripheral information transmitted from the pedestrian alarm server 7, the risk determination unit 85 determines whether the risk information in the peripheral information is in a dangerous state.
At this time, if the danger information is in a dangerous state, the danger determination unit 85 advances the process to step S45.
On the other hand, if the danger information is in a non-dangerous state, the danger determining unit 85 advances the process to step S44.

Step S44:
When the congestion determination unit 61 receives the peripheral information transmitted by the pedestrian alarm server 7, the congestion determination unit 61 determines whether the congestion information in the peripheral information is in a congested state.
At this time, if the congestion information is in a congestion state, the congestion determination unit 61 advances the process to step S45.
On the other hand, when the congestion information is in a non-congested state, the congestion determination unit 61 advances the process to step S41.

Step S45:
The walking determination unit 62 drives the acceleration sensor and acquires acceleration data of the acceleration sensor. Further, after obtaining acceleration data from the acceleration sensor, the acceleration sensor is stopped. Here, the walking determination unit 62 controls whether to drive or stop depending on whether power is supplied to the acceleration sensor, for example.
And the walk determination part 62 advances a process to step S46.

Step S46:
The walking determination unit 62 determines whether or not the acquired acceleration data exceeds a preset acceleration threshold value. At this time, when the acquired acceleration data exceeds a preset acceleration threshold, the walking determination unit 62 determines that the pedestrian carrying the mobile terminal device 8 is walking, and the process is performed in step S47. Proceed to On the other hand, when the acquired acceleration data is equal to or less than a preset acceleration threshold value, the walking determination unit 62 determines that the pedestrian carrying the mobile terminal device 8 is not walking, and advances the process to step S41.

Step S47:
The information notification unit 63 determines that at least the congestion determination unit 61 is in the congestion state or the dangerous place information detection unit 74 is in the dangerous state, and the walking determination unit 62 determines that the pedestrian is walking. In this case, the information of alerting for prompting the pedestrian not to operate the portable terminal device 6 while walking is notified.

In the present embodiment, using either an audio signal or an image signal, the mobile terminal device 8 is operated, and the operator who is walking is temporarily stopped and alerted to observe the surroundings. Therefore, it becomes possible to alert the operator who is walking by operating the mobile terminal device in the attendee, that it is dangerous to operate the mobile terminal device 8 in the detection range. Collisions between each other or accidents at dangerous places existing in the detection range can be avoided.
In the present embodiment, the configuration for detecting congestion information has been described using the congestion detection unit 13 similar to that in the first embodiment. However, as in the second and third embodiments, the congestion is detected. The configuration of the detection unit 33 may be used.

  Further, the pedestrian alarm server 1 of FIG. 1, the pedestrian alarm server 3 of FIG. 2, the pedestrian alarm server 5 of FIG. 3, the portable terminal device 6 of FIG. 3, and the pedestrian alarm server 7 of FIG. A program for realizing each function and each function of the mobile terminal device 8 of FIG. 6 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system, A process for controlling the operation of each device may be performed by executing. Here, the “computer system” includes an OS and hardware such as peripheral devices.

Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design and the like within a scope not departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1, 3, 5, 711 ... Alarm server for pedestrians 2 ... Imaging device 4 ... IC tag reader 6, 8 ... Portable terminal device 11, 31 ... Imaging data input part 12, 32 ... Peripheral information detection part 13, 33 ... Congestion detection Unit 14, 34 ... Congestion notification unit 54, 63, 75 ... Information notification unit 61 ... Congestion determination unit 62 ... Walking determination unit 64 ... Application activation determination unit 74 ... Hazardous location information detection unit 76 ... Risk level map database 85 ... Risk determination Part

Claims (5)

A pedestrian alarm for notifying an operation pedestrian who is operating a portable terminal device of peripheral information in a predetermined range where the operation pedestrian is walking and preventing an accident caused by the operation pedestrian Server,
A surrounding information detection unit that detects the number of moving objects that is the number of moving objects in the predetermined range;
A congestion detection unit that compares the moving body density obtained from the number of moving bodies with a preset moving body density threshold and detects whether the predetermined range is congested,
A pedestrian alarm server, comprising: an information notification unit that notifies the operation pedestrian of peripheral information including congestion information indicating the congestion state in the predetermined range. The said information notification part notifies the congestion information which shows whether it is the said congestion state as said surrounding information with respect to the said portable terminal device which the said operation pedestrian is carrying. Alarm server for pedestrians. A risk map database storing the presence or absence of a dangerous place in the predetermined range;
A risk determination unit that refers to the risk map database and determines whether or not the predetermined range where the operation pedestrian is walking is dangerous. The alarm server for pedestrians described in 1. Risk information indicating whether the predetermined range in which the operation pedestrian is walking is dangerous as the peripheral information for the portable terminal device carried by the operation pedestrian in the information notification unit. The pedestrian alarm server according to claim 3, wherein notification is performed. A mobile terminal device in which peripheral information in an existing predetermined range is notified from a pedestrian alarm server having jurisdiction over the predetermined range,
A congestion determination unit that determines whether or not the congestion information indicating the congestion state of the predetermined range included in the peripheral information indicates congestion;
A walking determination unit for detecting whether or not an operation pedestrian who is a pedestrian carrying the mobile terminal device is walking;
When the congestion determination unit determines from the congestion information that the predetermined range is congested, and the walking determination unit detects that the pedestrian is walking, the portable terminal device is carried An information notification unit that notifies an operation pedestrian of an alert.

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