JP2019023819A - Signal system, server and signal display method - Google Patents

Abstract

To provide a signal system, a server and a signal display method that enable a driver, etc. to easily recognize a cautionary place through driving assistance.SOLUTION: A signal system comprises a vehicle, a gathering unit which gathers predetermined information, and a generation unit which generates signal information on a predetermined spot based upon the predetermined information, and the vehicle displays signal display information, based upon the signal information, in a predetermined space inside the vehicle.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a signal system, a server, and a signal display method.

  2. Description of the Related Art Conventionally, a system that supports safe driving has been developed by extracting a potential danger point (a point requiring attention) and transmitting information on the potential danger point to a vehicle.

  For example, Patent Document 1 (International Publication No. 2014/157359) includes the following map generation system. That is, the map generation system collects vehicle speed information including at least speed, acceleration, and deceleration from the vehicle, and from the collected vehicle speed information, the first position where the sudden deceleration event that satisfies the predetermined condition and the sudden deceleration event are detected. An extraction unit that extracts sudden deceleration information including the traveling direction of the vehicle when it occurs, a storage unit that stores map data, and a plurality of the map data stored in the storage unit with a predetermined size and a predetermined number of divisions When the vehicle passes based on the dividing unit that generates mesh map data divided into meshes, the rapid deceleration information extracted by the extracting unit, and the mesh map data generated by the dividing unit An estimation unit that estimates a position requiring attention as a point requiring attention.

International Publication No. 2014/157359

  In the map generation system described in Patent Literature 1, it is possible to improve the extraction accuracy for extracting the driving support location in the driving support system. However, in this system, it is possible to estimate a point requiring attention based on the vehicle speed information of the vehicle, but whether or not a passenger of a vehicle including a driver (hereinafter also referred to as “driver or the like”) is a point requiring attention. There is no disclosure or suggestion of means for easily recognizing that it is a point requiring attention in determining whether or not.

  The present invention has been made to solve the above-described problems, and an object thereof is to provide a signal system, a server, and a signal display method that enable a driver or the like to easily recognize a point requiring attention in driving assistance. It is to be.

  (1) In order to solve the above problems, a signal system according to an aspect of the present invention includes a vehicle, a collection unit that collects predetermined information, and a generation unit that generates signal information at a predetermined point based on the predetermined information. The vehicle displays signal display information based on the signal information in a predetermined space inside the vehicle.

  (12) In order to solve the above problems, a signal display method according to an aspect of the present invention includes a step of collecting predetermined information, a step of generating signal information of a predetermined point based on the predetermined information, and the signal Displaying signal display information based on the information in a predetermined space inside the vehicle.

  The present invention can be realized not only as a signal system and a signal display method including such a characteristic processing unit and characteristic processing, but also as a server used in the signal system. Moreover, it is realizable as a program for making a computer perform this process. Further, it can be realized as a semiconductor integrated circuit that realizes part or all of the signal system. Moreover, it can implement | achieve using the vehicle-mounted apparatus mounted in a vehicle instead of a vehicle.

  According to the present invention, a driver or the like can easily recognize a point requiring attention.

FIG. 1 is a diagram showing a configuration of a signal system according to an embodiment of the present invention. FIG. 2 is a diagram showing a display example of signal display information on the display unit of the signal system according to the embodiment of the present invention. FIG. 3 is a diagram showing the configuration of the signal system according to the first embodiment of the present invention. FIG. 4 is a flowchart showing operations related to operation of the traffic light control model in the signal system server according to the first embodiment of the present invention. FIG. 5 is a diagram showing a configuration of a signal system according to the second embodiment of the present invention. FIG. 6 is a flowchart showing an operation related to construction of a traffic light control model in the signal system server according to the second embodiment of the present invention. FIG. 7 is a flowchart showing an operation related to the operation of the traffic light control model in the signal system server according to the second embodiment of the present invention. FIG. 8 is a diagram showing a configuration of a signal system according to the third embodiment of the present invention. FIG. 9 is a flowchart showing operations related to construction of a traffic light control model and setting of a threshold in a signal system server according to the third embodiment of the present invention. FIG. 10 is a flowchart showing an operation related to the operation of the traffic light control model in the signal system server according to the third embodiment of the present invention. FIG. 11 is a diagram showing a configuration of a signal system according to the fourth embodiment of the present invention. FIG. 12 is a flowchart showing an operation related to construction of a traffic light control model in a signal system server according to the fourth embodiment of the present invention. FIG. 13: is a flowchart which shows the operation | movement which concerns on operation | use of the traffic light control model in the server of the signal system which concerns on 4th Embodiment of this invention.

  First, the contents of the embodiment of the present invention will be listed and described.

  (1) A signal system according to an embodiment of the present invention is a signal system including a vehicle, a collection unit that collects predetermined information, and a generation unit that generates signal information of a predetermined point based on the predetermined information. The vehicle displays signal display information based on the signal information in a predetermined space inside the vehicle.

  With such a configuration, it is possible to visualize a point requiring attention. Therefore, a driver or the like can easily recognize a point requiring attention.

  (2) Preferably, the predetermined point is an intersection where a traffic light equipped with a signal lamp is not installed, and the predetermined information includes position information of an existing vehicle located on a road flowing into the intersection.

  With such a configuration, it is not necessary to install a traffic signal at the intersection, so that, for example, costs associated with the installation and operation of the traffic signal can be reduced.

  (3) Preferably, the predetermined point is an intersection where a traffic signal including one or a plurality of signal lamps is installed, at least one of the signal lamps has stopped operating, and the predetermined information is: It includes position information of existing vehicles located on the road flowing into the intersection.

  With such a configuration, for example, even if the operation of the signal lamp installed at the intersection stops, the driver or the like can obtain the signal information necessary for traveling of the vehicle with the signal display information related to the intersection displayed on the vehicle. Since it can be grasped, traffic operation can be continued appropriately.

  (4) Preferably, the said predetermined information contains the positional information on all the existing vehicles located on all the roads which flow into the said intersection.

  With such a configuration, traffic signal control can be performed based on the position information of all existing vehicles, so that traffic operation can be performed appropriately, and vehicles can be managed intensively.

  (5) Preferably, the predetermined information includes abnormality detection information regarding a first point on a road in a traveling direction of the vehicle, and the predetermined point is a point from the position of the vehicle to the first point. And the generation unit generates the signal information according to a degree of abnormality included in the abnormality detection information.

  With such a configuration, when an abnormality at the first point is detected, the driver, etc. can grasp the abnormality at a predetermined point before reaching the first point. You can call attention.

  (6) Preferably, the predetermined information includes a detection result of the number of pedestrians by a sensor installed at the first point, and the degree of the abnormality depends on a comparison between the detection result and a predetermined threshold value. It is determined.

  With such a configuration, the driver or the like can sense a point where a sudden jump of a human being occurs, such as a school road or a residential area, and urge the driver or the like to be aware of the sudden jump of a human. it can.

  (7) Preferably, the predetermined information includes a detection result regarding at least one of rock fall and collapse by a sensor installed at the first point, and the degree of abnormality is the detection result. And a predetermined threshold value.

  With such a configuration, the driver or the like can sense a point where a falling rock or a collapse is likely to occur, such as a mountain, and can prompt the driver or the like to be aware of the falling rock or the collapse.

  (8) Preferably, the predetermined information includes a traffic jam tail position and the vehicle position downstream of the first point, and the degree of abnormality is a distance from the traffic jam tail position to the vehicle position. It is determined according to a comparison with a plurality of determination distances set based on a plurality of decelerations.

  With such a configuration, the driver or the like can detect the tail position of the traffic jam, so that it is possible to prevent the rear collision of the tail position on the vehicle.

  (9) Preferably, the vehicle includes a control unit that controls traveling and stopping of the vehicle based on the signal information.

  In this way, by controlling whether the vehicle itself passes, for example, a predetermined point or stops before the predetermined point, the load on the driver or the like can be reduced.

  (10) Preferably, the signal display information includes information capable of recognizing a signal lamp and its lamp color.

  In this way, by displaying in the appearance format of the signal lamp familiar to the driver or the like, it is easy for the driver or the like to recognize the point requiring attention more easily.

  (11) Preferably, in the signal system according to the embodiment of the present invention, a server including the collection unit, the generation unit, and a transmission unit that transmits the signal information to the vehicle is used.

  With such a configuration, for example, a vehicle that has received the signal information displays the signal information in a predetermined space inside the vehicle, whereby a point requiring attention can be visualized. Therefore, a driver or the like can easily recognize a point requiring attention.

  (12) A signal display method according to an embodiment of the present invention includes a step of collecting predetermined information, a step of generating signal information of a predetermined point based on the predetermined information, and a signal display information based on the signal information. And displaying in a predetermined space inside the vehicle.

  With such a configuration, it is possible to visualize a point requiring attention. Therefore, a driver or the like can easily recognize a point requiring attention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated. Moreover, you may combine arbitrarily at least one part of embodiment described below.

[Configuration and basic operation]
FIG. 1 is a diagram showing a configuration of a signal system according to an embodiment of the present invention.

  With reference to FIG. 1, the signaling system includes, for example, a vehicle 1 and a server 2. The vehicle 1 includes, for example, a display unit 10 and a control unit 11. Moreover, the server 2 is provided with the collection part 20, the production | generation part 21, and the transmission part 22, for example.

  The server 2 is installed, for example, in a traffic control center or the like, generates signal information based on the collected information, and transmits the signal information to the vehicle 1 approaching a predetermined point. The signal information includes, for example, information indicating whether the vehicle 1 may proceed or stop at a predetermined point. More specifically, the signal information includes information indicating the signal lamp color (blue, yellow, red, etc.) that is the color of the traffic light. (Blinking / extinction light) may be included. In the embodiment of the present invention, blue indicates not only “can proceed” but also “safe state”, “low possibility of abnormality”, etc., and yellow indicates “except when it cannot be safely stopped”. , Not only “stop” but also “slightly dangerous” or “high possibility of abnormality”, etc. Red indicates not only “stop” but also “dangerous” or “high possibility of abnormality” Show.

  The collection unit 20 is, for example, probe data from a vehicle (vehicle in-vehicle device), traffic signal information related to traffic signal control installed at an intersection, human detection information from a sensor, GPS information from a smartphone, Collect vibration data. Although details of these information will be described later, these will be collectively referred to as “predetermined information” hereinafter.

  For example, the generation unit 21 generates signal information of a predetermined point such as an intersection based on the predetermined information collected by the collection unit 20.

  For example, the transmission unit 22 transmits the signal information generated by the generation unit 21 to the vehicle 1.

  The vehicle 1 receives the signal information transmitted from the server 2, generates signal display information based on the signal information, and provides it to the driver or the like.

  The display unit 10 displays, for example, signal display information based on the signal information in a predetermined space inside the vehicle 1.

The signal display information is information generated for display on the display unit 10 based on the signal information. For example, it is information which can recognize a signal lamp device and a signal lamp color.
The predetermined space is, for example, a display. In addition, not only a display but the window of the vehicle 1 etc. may be sufficient, for example.

  FIG. 2 is a diagram showing a display example of signal display information on the display unit of the signal system according to the embodiment of the present invention.

  Referring to FIG. 2, the signal display information is a virtual signal lamp displayed at an intersection, and this signal lamp includes three signal lamps. The signal lamp colors indicated by the respective signal lamps are blue, yellow, and red, respectively, and any one of the signal lights displays one of the three colors of blue, yellow, and red. For example, at this time, in the case of yellow or red display, the reason why the display is yellow or red, that is, the reason why it is a point requiring attention may be added. In this way, by displaying in the appearance format of the signal lamp familiar to the driver or the like, it is easy for the driver or the like to recognize the point requiring attention more easily.

  Further, as shown in FIG. 2, a virtual road may be displayed on the display unit 10 together with the signal display information, and may be displayed so that a predetermined point is an intersection. That is, even if the road on which the vehicle 1 is traveling is a single road, a virtual road that intersects with the road may be displayed. This makes it easier for the driver or the like to determine at which position to stop.

  The signal display information is not limited to a configuration that displays a signal lamp device including three signal lamps, but may be a configuration in which only one signal lamp is displayed and each of the three colors is switched on. In addition, for example, the letters “can proceed (meaning blue)”, “stop (meaning yellow)”, “stop (meaning red)” except when it cannot be stopped safely, on a predetermined space such as a display If a display area and a lighting area below each are prepared, each state can be expressed by lighting only one signal lamp color (for example, only red) in the lighting area. Express each state by displaying icons that mean “stop (meaning blue)”, “stop (meaning yellow)” and “stop (meaning red)” except when it ca n’t stop safely You can also.

For example, the control unit 11 controls the running and stopping of the vehicle 1 based on the signal information.
Specifically, signal information transmitted from the transmission unit 22 of the server 2 or signal display information based on the signal information is automatically determined by a control unit (ECU) in the vehicle 1 to control the vehicle speed. Do. For example, in the signal information, when the signal lamp color is blue, the vehicle 1 moves forward, when the signal lamp color is yellow, the vehicle 1 slows down, and when the signal lamp color is red, the vehicle 1 stops. Thus, by controlling whether the vehicle 1 itself passes, for example, a predetermined point or stops before the predetermined point, the load on the driver or the like can be reduced.

  The collecting unit 20 and the generating unit 21 may not be provided in the server 2, and at least one of the collecting unit 20 and the generating unit 21 may be provided in the vehicle 1. When both the collection unit 20 and the generation unit 21 are provided in the vehicle 1, the signal system according to the embodiment of the present invention can be realized only by the vehicle 1 without the server 2.

  The generation of the signal display information based on the signal information is not limited to the configuration performed in each vehicle including the vehicle 1, and may be a configuration performed in the generation unit 21 of the server 2. When the generation unit 21 of the server 2 is configured to generate the signal display information, the transmission unit 22 transmits the signal display information to each vehicle including the vehicle 1. With such a configuration, it is possible to save the trouble of generating signal display information in each vehicle. The same applies to each embodiment described later.

  Hereinafter, first to fourth embodiments that further embody the embodiments of the present invention will be described in order. The predetermined information and the predetermined points described above are different in each of the first to fourth embodiments.

<First Embodiment>
FIG. 3 is a diagram showing the configuration of the signal system according to the first embodiment of the present invention.
Referring to FIG. 3, the predetermined point is an intersection I1 indicating an intersection where a traffic light including a signal lamp is not installed. Alternatively, the predetermined point is an intersection where a traffic signal including one or a plurality of signal lamps is installed, and at least one of these signal lamps is an intersection I2 indicating an intersection where the operation is stopped.

  The collecting unit 20 is, for example, a probe from an in-vehicle device (not shown in FIG. 3) mounted on the vehicles 1a, 1b, 1c, 1d around the intersection I1 and the vehicles 1e, 1f, 1g, 1h around the intersection I2. Collect predetermined information including data. Specifically, the intersection I1 is a vehicle 1 located on the inflowing roads R10, R11, R12, R13 (hereinafter, a vehicle located on the road flowing into the intersection is also referred to as “existing vehicle”). The probe data of the vehicles 1a, 1b, 1c, and 1d are collected, and for the intersection I2, vehicles 1e, 1f, 1g, and 1h, which are vehicles 1 (existing vehicles) located on the inflowing roads R20, R21, R22, and R23. Collect probe data.

  The probe data includes information such as time, position (latitude, longitude, altitude), speed, acceleration, etc., for example, every predetermined period (for example, 1 second).

  When the collection unit 20 collects predetermined information including probe data not only from the vehicles around the intersection I1 and the intersection I2 but also from the in-vehicle devices of other vehicles, the position information included in the probe data and the intersection By selecting the map data of the roads R10, R11, R12, R13 flowing into I1 and the road data R20, R21, R22, R23 flowing into the intersection I2, the probe data of the existing vehicles related to these intersections is selected. Can do.

  The collecting unit 20 collects traffic signal information related to traffic signal control from the traffic signal SN2 installed at the intersection I2. This traffic signal information includes, for example, vehicle detection information in vehicle detectors set on the roads R20, R21, R22, and R23.

  The generation unit 21, for example, based on the position information of the vehicle 1 included in the probe data collected by the collection unit 20, particularly the position information of the vehicle 1 (existing vehicle) located on the road flowing into the intersection. Signal information is generated.

  The signal information is generated according to, for example, a publicly known technique described in Japanese Patent Application Laid-Open No. 2009-252066, Japanese Patent Application Laid-Open No. 2009-015817, or the like according to a pattern control method, a MODERATO (Management by Origin-Destination Related Adaptation for Traffic Optimization) control method, It is done by.

  Here, the pattern control method is a method in which a plurality of control patterns based on a prior traffic survey are set in advance and controlled according to the optimum pattern set according to the traffic situation measured by the vehicle detector at the intersection entrance. is there.

  The MODERATO control method is a program formation control method that automatically updates signal control parameters according to traffic conditions. By applying this, the traffic volume data at the intersection is measured by a vehicle sensor at the entrance of the intersection. It is possible to estimate the time (delay time) for passing traffic and waiting for a signal, and to calculate that time to be minimized.

  Moreover, it is preferable that the collection part 20 collects the probe data of all the existing vehicles located on all the roads which flow into an intersection. With such a configuration, traffic signal control can be performed based on the position information of all existing vehicles, so that traffic operation can be performed appropriately, and vehicles can be managed intensively.

  Hereinafter, the operation in the server 2 of the signal system according to the first embodiment of the present invention will be described.

  This operation is classified into, for example, (1) traffic signal information setting, (2) traffic signal peripheral information collection, (3) traffic signal control model construction, and (4) traffic signal control model operation.

  First, in “(1) Setting of traffic light information”, for example, the server 2 determines a place (intersection) where a traffic light is set. This traffic signal is not only a virtual traffic signal (refers to a traffic signal displayed in a predetermined space inside the vehicle 1 as signal display information) but also an existing physical traffic signal (refers to a traffic signal actually installed on the road). .) May be included. The place set when the traffic light is a virtual traffic light is the intersection I1, and the place set when the traffic light is a physical traffic light is the intersection I2.

  When a virtual traffic signal is set like the intersection I1, signal information related to this virtual traffic signal may be transmitted to the vehicle 1. Then, the driver of the vehicle 1 may travel according to the signal display information based on this signal information, or the vehicle 1 itself may travel according to this signal information. As a result, it is not necessary to actually install a traffic signal at the intersection, so that, for example, the cost for installing and operating the traffic signal can be reduced.

  In addition, when a physical signal is set like the intersection I2, the server 2 monitors the physical signal and detects that the signal has failed, such as the operation of the signal lamp stops. The signal information of the virtual traffic light may be generated based on the collected probe data or the like after being replaced with a virtual traffic light, and the signal information may be transmitted to the vehicle 1. Then, the driver of the vehicle 1 may travel according to the signal display information based on this signal information, or the vehicle 1 itself may travel according to this signal information. As a result, even if the operation of the signal lamp stops, the driver or the like can grasp the signal information necessary for traveling of the vehicle 1 by the signal display information related to this intersection displayed on the vehicle 1. Traffic operation can be continued properly.

  Next, in “(2) Signal Signal Peripheral Information Collection”, for example, the server 2 (collection unit 20) has information on signal signal peripherals set in (1) for “(3) Construction of signal control model” described later. To collect. Specifically, when the intersection determined in (1) is the above-described intersection I1, the probe data of the vehicles on which the roads R10, R11, R12, R13 flowing into the intersection I1 are collected. On the other hand, when the intersection determined in (1) is the intersection I2, not only is the probe data of the vehicles existing on the roads R20, R21, R22, R23 flowing into the intersection I2 collected, but also the existing I2 of the intersection I2 is collected. Traffic light information may be collected from physical traffic lights. In addition, when the traffic signal (physical traffic signal) is installed in the intersection adjacent to the intersection I1 or the intersection I2, the traffic signal information of this traffic signal may be further collected.

  In “(3) Construction of traffic light control model”, for example, the server 2 (generating unit 21) applies a predetermined signal control method to the traffic light set in (1) using the information collected in (2). . More specifically, for example, the pattern control method or MODERATO control method described above is applied as the predetermined signal control method, and the signal information of the intersection is obtained based on the probe data and traffic signal information of the existing vehicle collected in (2). Build a traffic light control model to generate. At this time, various information (the length of the road, the number of lanes, etc.) of the road flowing into the intersection determined in (1) may be used. As described above, this model may be constructed by using a known technique described in Japanese Patent Application Laid-Open Nos. 2009-252066 and 2009-015817. In the case of the intersection I2, if a model is constructed using signal information in addition to probe data, signal information that maintains continuity before and after a signal failure can be generated.

“(4) Operation of traffic light control model” will be described in detail with reference to the drawings.
FIG. 4 is a flowchart showing operations related to operation of the traffic light control model in the signal system server according to the first embodiment of the present invention.

  First, the server 2 (collection unit 20) collects information around the traffic signal in order to generate signal information related to the traffic signal set in (1), for example (step S101). Specifically, when the intersection determined in (1) is the intersection I1, probe data of vehicles existing on the roads R10, R11, R12, R13 flowing into the intersection I1 is collected. When the intersection determined in (1) is the intersection I2, in addition to collecting probe data of vehicles existing on the roads R20, R21, R22, R23 flowing into the intersection I2, the existing physical of the intersection I2 is collected. Traffic signal information may be collected from traffic signals. When a traffic signal (physical traffic signal) is installed at an intersection adjacent to the intersection I2, traffic signal information of this traffic signal may be further collected.

  Next, the server 2 (generation unit 21) performs signal control according to the signal control method set in (3) (step S102). More specifically, the server 2 (generating unit 21) generates signal information related to the traffic signal set in (1) based on the traffic signal peripheral information collected in step S101 and the traffic signal control model constructed in (3). In the case of the intersection I2, when no abnormality occurs in the traffic light at the intersection I2, signal information is not generated. When an abnormality occurs, that is, when the stop of the operation of the signal lamp is detected. Only the signal information needs to be generated. This is because when there is no abnormality, the vehicle 1 travels according to the signal lamp color that is lit on the signal lamp of the actual traffic light.

  Further, the server 2 (transmission unit 22) transmits the signal information generated in step S102 to the vehicle approaching the intersection determined in (1) (step S103). More specifically, based on the position information included in the probe data collected in step S101, it is determined whether the vehicle is approaching the intersection or the vehicle is moving away from the intersection, and the vehicle determined to be approaching Signal information is transmitted to.

  Upon receiving the signal information, the vehicle 1 (the display unit 10 thereof) displays the signal display information based on the signal information in a predetermined space inside the vehicle 1. With such a configuration, it is possible to visualize a point requiring attention. Therefore, a driver or the like can easily recognize a point requiring attention.

  The vehicle 1 that has received the signal information may broadcast this signal information to surrounding vehicles, for example. By doing this, the vehicles around the intersection can share signal information with each other, so even if there is a vehicle that cannot directly receive the signal information from the server 2, the signal information can be obtained indirectly from other vehicles. It is possible to ensure acquisition of signal information.

  Further, at the intersection I2, for example, even when the signal light color related to the physical traffic light in the traveling direction of the vehicle 1 shows blue, the server 2 ignores the signal from the other road that intersects the road in the traveling direction. When a dangerous vehicle that is about to pass through is detected, the signal lamp color related to the virtual traffic signal in the traveling direction may be red. As described above, the configuration in which the driver or the like is urged to stop the vehicle by the signal light color of the virtual traffic light regardless of the signal light color of the physical traffic light can prevent a collision accident between the vehicles. This dangerous vehicle can be detected based on, for example, the distance to the intersection I2, the speed, the acceleration, and the like. More specifically, for example, the determination can be made based on whether the distance to the intersection I2 exceeds a predetermined threshold and whether the speed, acceleration, or the like of the dangerous vehicle exceeds a predetermined threshold.

Second Embodiment
FIG. 5 is a diagram showing a configuration of a signal system according to the second embodiment of the present invention.

  Referring to FIG. 5, the predetermined point is, for example, a point from the position of vehicle 1 to the first point on the road in the traveling direction of vehicle 1. Specifically, the predetermined point is a point separated from the first point by a predetermined distance (for example, 300 m) in order for a driver or the like to recognize an abnormality at the first point in advance. The first point is, for example, a point requiring attention in a residential area where humans are expected to jump out.

  The collection unit 20 collects predetermined information including probe data of the vehicle 1 and abnormality detection information regarding the first point. The abnormality detection information is information indicating a result of detecting the possibility of a predetermined abnormality, and more specifically, for example, in the time zone in which humans are expected to jump out, that is, the time zone in which humans are likely to gather. This is human detection information that detects the presence of a human at one point. The human detection information is, for example, information such as the number of pedestrians detected using the sensor (human detection sensor) 30a installed at the first point, and is transmitted from the sensor 30a to the collection unit 20 of the server 2. The In addition, a human can also be detected using the GPS function of a smart phone, etc. In this case, a smart phone transmits the positional information by a GPS function etc. to the collection part 20 of the server 2 as human detection information.

  For example, the generation unit 21 generates abnormality detection information based on human detection information, probe data, and the like collected by the collection unit 20, and generates signal information based on the degree of abnormality included in the abnormality detection information. The degree of abnormality is determined, for example, in accordance with a comparison between the number of pedestrians indicated by the human detection information and a set predetermined threshold value.

  Hereinafter, the operation of the signal system server according to the second embodiment of the present invention will be described.

  This operation is classified into, for example, (1) traffic signal information setting, (2) traffic signal peripheral information collection, (3) traffic signal control model construction, and (4) traffic signal control model operation.

  First, in “(1) Setting of traffic light information”, for example, the server 2 determines a place where a traffic light is set. This place is a point separated by a predetermined distance from the above-mentioned predetermined point, for example, a first point indicating a point requiring attention in a residential area where humans are expected to jump out.

  Next, in “(2) Collection of signal peripheral information”, for example, the server 2 (collection unit 20) collects information around the signal set in (1). The information to be collected includes, for example, probe data of vehicles around the traffic light set in (1), human detection information of the sensor 30a installed at the first point, and the like. The probe data is the same as that described in the first embodiment, but may further include information indicating whether the vehicle is moving toward or away from a predetermined point. It should be noted that the number of pedestrians may be investigated by, for example, a questionnaire for humans without being limited to the probe data and the sensor 30a.

“(3) Construction of traffic light control model” will be described in detail with reference to the drawings.
FIG. 6 is a flowchart showing an operation related to construction of a traffic light control model in the signal system server according to the second embodiment of the present invention.

  First, the server 2 (generation unit 21) performs data analysis using data in a specific period among the human detection information collected in (2) (step S201). Here, the specific period is a period during which the above-described preliminary survey is performed. For example, “A: the past month”, “B: the past year”, “C: the annual Golden Week (GW) period”, and the like. More specifically, the server 2 calculates, for example, an average value of the number of pedestrians for each day type and an average value of the number of pedestrians per hour based on the human detection information in the specific period. The day type can be classified into, for example, “Monday to Friday” and “Saturday / Sunday / Holiday”, or can be classified into “Monday to Saturday” and “Sunday / Holiday”.

  Next, the server 2 (generation unit 21) constructs (models) an abnormality detection model (step S202). Specifically, the server 2 is calculated in step S201 for each combination of day type and time zone (for example, three time zones of 6-12 o'clock, 12-18 o'clock, and 18-24 o'clock). Of the average value of the number of pedestrians for each day type and the average value of the number of pedestrians per hour, the weighted average value of those corresponding to the combination is obtained, and this is a parameter indicating the degree of danger (hereinafter referred to as “danger Also referred to as “degree”.

Finally, the server 2 (generation unit 21) sets a threshold value of signal information related to signal control (step S203).
More specifically, the weighted average value for each combination of the day type and the time zone calculated in step S202 is “no possibility of danger”, “possibility of danger”, “high possibility of danger”. If the time point that is the target of abnormality determination in “(4) Operation of traffic light control model”, which will be described later, corresponds to a combination of day type and time zone that is “possibly dangerous”, the signal lamp color is yellow. Set to blink, and set the signal lamp color to blink red if it corresponds to the combination of day type and time zone that is “highly dangerous”.

  In addition, based on the average value of the number of pedestrians for each day type calculated in step S201 and the average value of the number of pedestrians per hour, the number of pedestrians is “no possibility of abnormality (danger)” and “ 1st threshold value W1 for classifying as “abnormality (danger) is possible”, among the number of pedestrians classified as “abnormality (danger)”, further possible “abnormality (danger)” The second threshold W2 (the second threshold W2 is larger than the first threshold W1) for categorizing “high performance” is determined, and becomes an object of abnormality determination in “(4) Operation of traffic light control model” described later. When the number of pedestrians exceeds the second threshold W2, the signal lamp color is set to light red, and when the number exceeds the first threshold W1 and equal to or less than the second threshold W2, the signal lamp color is set to light yellow.

“(4) Operation of traffic light control model” will be described in detail with reference to the drawings.
FIG. 7 is a flowchart showing an operation related to the operation of the traffic light control model in the signal system server according to the second embodiment of the present invention.

  First, the server 2 (collecting unit 20) collects information around the traffic light set in (1) in order to evaluate, for example, whether or not an abnormality has occurred at the above-described predetermined point (for example) ( Step S301). Specifically, as in (2), probe data of the vehicle 1 around this traffic light, human detection information of the sensor 30a installed at the first point, and the like are collected.

  Next, according to the model created in (3), the server 2 (generating unit 21) presents the current number of pedestrians indicated by the human detection information collected in step S301 and the threshold value for the number of pedestrians described above, that is, (3). The abnormality is determined by comparing the first threshold value W1 and the second threshold value W2 set in step (step S302). As a result of the comparison in step S302, if it is determined that the number of pedestrians exceeds at least one of the first threshold value W1 and the second threshold value W2, the process proceeds to step S307, and any of the first threshold value W1 and the second threshold value W2 If it is determined that it does not exceed, the process proceeds to step S304 (step S303).

  If the server 2 (generating unit 21) determines in step S303 that the number of pedestrians exceeds the second threshold value W2, the signal information is set to red, exceeds the first threshold value W1, and is equal to or less than the second threshold value W2. Is determined to be yellow, the signal information is set to yellow (step S307).

  Further, the server 2 (generating unit 21) determines, for example, whether the current time is a dangerous day type or time zone according to the model created in (3) (step S304). Specifically, the server 2 sets the combination of the “potentially dangerous” day type and time zone classified as (3) at the present time, and the combination of the “highly dangerous” day type and time zone. It is determined whether it is applicable.

  In step S304, the server 2 (the generation unit 21) determines that the current time corresponds to a combination of a day type and a time zone “possibly dangerous” or a combination of a day type and a time zone “high possibility of danger”. If YES, the process proceeds to step S305, and if it is determined that the combination of the “possibly dangerous” day type and the time zone is met, the signal information is set to blink yellow and the “high possibility of danger” day type is set. When it is determined that the combination corresponds to the combination of the time zone and the signal information, red blinking is set (step S305). On the other hand, when it is determined in step S304 that the current time does not correspond to any combination of the day type and time zone “possibly dangerous” and the combination of the day type and time zone “high possibility of danger” Advances to step S306, and blue is set in the signal information (step S306).

  Finally, the server 2 (transmission unit 22) transmits the signal display information to the vehicle 1 approaching a predetermined point, for example (step S308). The determination as to whether or not the vehicle 1 is approaching a predetermined point is based on, for example, information included in the probe data of the vehicle 1 that indicates whether the vehicle 1 is moving toward or away from the predetermined point. However, it may be performed based on the position information of the first point and the position information included in the probe data of the vehicle 1.

  The vehicle 1 that has received the signal information from the server 2 generates signal display information based on the signal information, displays it on the display unit 10, and provides it to the driver or the like. With such a configuration, when an abnormality at the first point is detected, the driver, etc. can grasp the abnormality at a predetermined point before reaching the first point. You can call attention. In addition, the driver or the like can sense a point where a human sudden jumping out easily occurs, such as a school road or a residential area, and can prompt the driver or the like to be aware of the sudden jumping out of the human being.

<Third Embodiment>
FIG. 8 is a diagram showing a configuration of a signal system according to the third embodiment of the present invention.

  Referring to FIG. 8, the predetermined point is, for example, a point from the position of vehicle 1 to the first point on the road in the traveling direction of vehicle 1. Specifically, the predetermined point is a point that is separated from the first point by a predetermined distance (for example, 300 m) or an intersection up to the first point because a driver or the like recognizes an abnormality at the first point in advance. More preferably, it is an intersection of a detour that allows the vehicle 1 to reach the destination without passing through the first point, and a road where the vehicle 1 reaches the destination via the first point. For example, the first point is a point requiring attention such as a falling rock or a collapse.

  The collection unit 20 collects predetermined information including probe data of the vehicle 1 and abnormality detection information regarding the first point. The abnormality detection information is, for example, information indicating the possibility of falling rocks or collapse, and more specifically, data related to vibration (hereinafter, referred to as “sensor” (vibration sensor) 30b installed at the first point). This information is also referred to as “vibration data”) and is transmitted from the sensor 30b to the collection unit 20 of the server 2. The sensor 30b may not be installed at the first point, and may be installed, for example, on a bridge around a mountain where there is a risk of falling rocks or collapse.

  For example, the generation unit 21 generates abnormality detection information based on vibration data and probe data collected by the collection unit 20, and generates signal information based on the degree of abnormality included in the abnormality detection information. The degree of abnormality is determined in accordance with, for example, comparison between vibration data (vibration amount and the like) and a predetermined threshold set by a method based on an abnormality detection model described later.

  The operation of the signal system server according to the third embodiment of the present invention will be described below.

  This operation is classified into, for example, (1) traffic signal information setting, (2) traffic signal peripheral information collection, (3) traffic signal control model construction and threshold setting, and (4) traffic signal control model operation. Is done.

  First, in “(1) Setting of traffic light information”, for example, the server 2 determines a place where a traffic light is set. The place is the above-mentioned predetermined point, for example, a detour that allows the vehicle 1 to reach the destination without passing through the first point indicating a cautionary point such as falling rock, collapse, etc., and the vehicle 1 via the first point It is an intersection with a road that can reach the destination.

  Next, in “(2) Collection of signal peripheral information”, for example, the server 2 (collection unit 20) collects information around the signal set in (1). The information to be collected includes, for example, probe data of vehicles around the traffic light set in (1), vibration data of the sensor 30b installed at the first point, and the like. The probe data is the same as that described in the first embodiment. However, as described in the second embodiment, whether the vehicle further moves toward a predetermined point or moves away from the predetermined point. It may include information to be shown.

“(3) Construction of traffic light control model and threshold setting” will be described in detail with reference to the drawings.
FIG. 9 is a flowchart showing operations related to construction of a traffic light control model and setting of a threshold in a signal system server according to the third embodiment of the present invention.

  First, the server 2 (generation unit 21) performs data analysis using data in a specific period among the vibration data collected in (2) (step S401). The specific period is the same as the specific period described in the second embodiment, for example, but may further include “D: rainy season (May to July)”. More specifically, the server 2 creates statistical data based on vibration data in a specific period, and plots an approximate curve of, for example, a normal distribution using the statistical data.

  Next, the server 2 (generation unit 21) constructs (models) an abnormality detection model (step S402). Specifically, the server 2 calculates an average value and σ (standard deviation) from the approximate curve of the normal distribution plotted in step S401, for example.

Finally, the server 2 (generation unit 21) sets a threshold value of signal information related to signal control (step S403).
More specifically, for example, a value that is 2σ or 3σ away from the average value calculated in step S402 is set as an outlier, and a value that is 2σ away from this average value is set as the first threshold value V1, and a value that is 3σ away is set as the second threshold value V2. To do. Then, the server 2 turns on the signal lamp color in red when the vibration amount to be subjected to abnormality determination exceeds “second threshold value V2” in “(4) Operation of traffic light control model” described later, and sets the first threshold value V1. Is set so that the signal lamp color is turned on in yellow.

  Note that the threshold setting of the signal information is not limited to using the above-described “outlier detection”, and for example, “change point detection”, “abnormal behavior detection”, etc. in JP 2010-198579 A can be used. Good.

“(4) Operation of traffic light control model” will be described in detail with reference to the drawings.
FIG. 10 is a flowchart showing an operation related to the operation of the traffic light control model in the signal system server according to the third embodiment of the present invention.

  First, the server 2 (collecting unit 20) collects information around the traffic light set in (1) in order to evaluate, for example, whether or not an abnormality has occurred at the above-described predetermined point (for example) ( Step S501). Specifically, as in (2), the probe data of the vehicle 1 around this traffic light, the vibration data of the sensor 30b installed at the first point, and the like are collected.

  Next, according to the model created in (3), the server 2 (generation unit 21) is set with the current vibration amount indicated by the vibration data collected in step S501 and the above-described vibration amount threshold, that is, (3). The abnormality is determined by comparing the first threshold value V1 and the second threshold value V2 (step S502). As a result of the comparison in step S502, if it is determined that the vibration amount exceeds at least one of the first threshold value V1 and the second threshold value V2, the process proceeds to step S504, and both the first threshold value V1 and the second threshold value V2 are detected. If it is determined that it has not exceeded, the process proceeds to step S505 (step S503).

  If the server 2 (generation unit 21) determines in step S503 that the vibration amount exceeds the second threshold value V2, the signal 2 is set to red, exceeds the first threshold value V1, and is equal to or less than the second threshold value V2. If it is determined, yellow is set in the signal information (step S504). On the other hand, if it is determined in step S503 that the vibration amount does not exceed both the first threshold value V1 and the second threshold value V2, blue is set in the signal information (step S505).

  Finally, the server 2 (transmission unit 22) transmits signal information to the vehicle 1 approaching a predetermined point, for example (step S506). The determination as to whether or not the vehicle 1 is approaching a predetermined point is as described in the second embodiment.

  The vehicle 1 that has received the signal information from the server 2 generates signal display information based on the signal information, displays it on the display unit 10, and provides it to the driver or the like. With such a configuration, the driver or the like can sense a point where a falling rock or a collapse is likely to occur, such as a mountain, and can prompt the driver or the like to be aware of the falling rock or the collapse.

<Fourth embodiment>
FIG. 11 is a diagram showing a configuration of a signal system according to the fourth embodiment of the present invention.

  Referring to FIG. 11, the predetermined point is, for example, a point from the position of vehicle 1 to the first point on the road in the traveling direction of vehicle 1. Specifically, the predetermined point is a point separated from the first point by a predetermined distance (for example, 300 m) in order for a driver or the like to recognize an abnormality at the first point in advance. The first point is a point requiring attention such as a rear-end collision with a vehicle having a traffic jam on a steep curve or a road with poor visibility.

  The collection unit 20 collects predetermined information including probe data of the vehicle 1 and abnormality detection information regarding the first point. The abnormality detection information includes, for example, vehicle detection data of a sensor (vehicle sensor) 30c installed on the road in the traveling direction of the vehicle 1, and probe data of vehicles around the first point on the road, that is, on this road Vehicle group 1A traveling downstream from the first point and probe data of the vehicle 1 traveling upstream from the first point.

  For example, the generation unit 21 generates abnormality detection information based on the vehicle detection data and probe data collected by the collection unit 20, and generates signal information based on the degree of abnormality included in the abnormality detection information. The degree of abnormality is set based on, for example, the distance from the congestion end position (the position of the end-of-congestion vehicle in the vehicle group 1A) to the position of the vehicle 1 downstream from the first point and a plurality of decelerations. It is determined according to comparison with a plurality of determination distances.

  The operation of the signal system server according to the fourth embodiment of the present invention will be described below.

  This operation is classified into, for example, (1) traffic signal information setting, (2) traffic signal peripheral information collection, (3) traffic signal control model construction, and (4) traffic signal control model operation.

  First, in “(1) Setting of traffic light information”, for example, the server 2 determines a place (predetermined point) where the traffic light is set. The place is a point that is a predetermined distance away from the first point that indicates a point requiring attention such as a rear-end collision with a vehicle with a traffic jam on a road with a sharp curve or poor visibility.

  Next, in “(2) Collection of signal peripheral information”, for example, the server 2 (collection unit 20) collects information around the signal set in (1). The collected information includes, for example, vehicle detection data of the sensor 30c installed on the road in the traveling direction of the vehicle 1 and probe data of vehicles around the first point on the road (from the first point on the road). Vehicle group 1A traveling downstream and probe data of vehicle 1 traveling upstream from the first point). The probe data is the same as that described in the first embodiment. However, as described in the second embodiment, whether the vehicle further moves toward a predetermined point or moves away from the predetermined point. It may include information to be shown.

“(3) Construction of traffic light control model” will be described in detail with reference to the drawings.
FIG. 12 is a flowchart showing an operation related to construction of a traffic light control model in a signal system server according to the fourth embodiment of the present invention.

  First, the server 2 (generation unit 21) applies an algorithm for detecting a traffic jam tail position based on the vehicle detection data, probe data, and the like collected in (2) (step S601). More specifically, the server 2 (the generation unit 21) uses, for example, a known technique described in Japanese Patent Application Laid-Open No. 2009-146138 and the like, collected vehicle detection data of the sensor 30c and probe data of the vehicle group 1A. Based on the above, the traffic jam end position is estimated. Here, the server 2 (generation unit 21) may also detect a stopped vehicle other than a traffic jam, a vehicle that should be determined to be sensitive, such as a vehicle parked in a parking prohibited area.

  Next, the server 2 (generation unit 21) sets a threshold value of signal display information related to signal control (step S602). More specifically, the first threshold value U1 and the second threshold value U2 are set as the threshold values of the inter-vehicle distance between the vehicle 1 and the stopped vehicle positioned ahead of the vehicle 1. The first threshold value U1 is a distance (for example, 200 m) that the vehicle 1 needs to decelerate, for example. The second threshold value U2 is a distance (for example, 100 m) that requires the vehicle 1 to stop suddenly, for example. When the server 2 determines that there is a stopped vehicle related to the end of the traffic jam at a distance that is greater than or equal to the second threshold value U2 and less than the first threshold value U1 when viewed from the vehicle 1, the signal light color is lit in yellow, and when viewed from the vehicle 1, When it is determined that there is a stopped vehicle related to the end of the traffic jam at a distance less than the second threshold value U2, the signal lamp color is set to light red.

“(4) Operation of traffic light control model” will be described in detail with reference to the drawings.
FIG. 13: is a flowchart which shows the operation | movement which concerns on operation | use of the traffic light control model in the server of the signal system which concerns on 4th Embodiment of this invention.

  First, the server 2 (collecting unit 20) collects information around the traffic light set in (1) in order to evaluate, for example, whether or not an abnormality has occurred at the above-described predetermined point (for example) ( Step S701). Specifically, as in (2), the vehicle detection data of the sensor 30c installed on the road in the traveling direction of the vehicle 1 and the probe data of the vehicle around the first point on the road (on this road) The vehicle group 1A traveling downstream from the first point and the probe data of the vehicle 1 traveling upstream from the first point are collected.

  Next, the server 2 (generating unit 21) determines the presence or absence of the stopped vehicle by obtaining the position of the stopped vehicle (traffic congestion end position) related to the tail of the traffic jam according to the algorithm constructed in (3) (step) S702). When the stop vehicle exists, for example, the inter-vehicle distance between the vehicle 1 and the stop vehicle positioned ahead of the vehicle 1, and the above-mentioned inter-vehicle distance threshold, that is, the first threshold U1 and the second threshold set in (3) When the threshold value U2 is compared and it is determined that the inter-vehicle distance is smaller than at least one of the first threshold value U1 and the second threshold value U2, the process proceeds to step S704, and both the first threshold value U1 and the second threshold value are greater than or equal to each other. If it is determined that the vehicle is stopped, or if it is determined that there is no stopped vehicle, the process proceeds to step S705 (step S703).

  When the server 2 (generating unit 21) determines that the inter-vehicle distance is less than the second threshold value U2 in step S703, it sets red in the signal information, and when it is determined that the distance is greater than or equal to the second threshold value and less than the first threshold value. Yellow is set in the signal information (step S704). On the other hand, if it is determined in step S703 that the distance between the vehicle 1 and the vehicle 1 is greater than or equal to both the first threshold value U1 and the second threshold value, or if it is determined that there is no stopped vehicle, blue is set in the signal information ( Step S705).

  Finally, the server 2 (transmission unit 22) transmits signal information to the vehicle 1 approaching a predetermined point, for example (step S706). The determination as to whether or not the vehicle 1 is approaching a predetermined point is as described in the second embodiment.

  The vehicle 1 that has received the signal information from the server 2 generates signal display information based on the signal information, displays it on the display unit 10, and provides it to the driver or the like. With such a configuration, the driver or the like can detect the tail position of the traffic jam, so that it is possible to prevent the rear collision of the tail position on the vehicle.

  In each of the first embodiment, the second embodiment, the third embodiment, and the fourth embodiment described above, the collection unit 20 performs “(2) Signal signal peripheral information collection” and “(4) Signal control model. "Collection of information around traffic lights (step S101, step S301, step S501, step S701)" in the "operation of", respectively, but separate collection units (for example, the first collection unit and the second collection unit) ) May be performed.

  In each of the first embodiment, the second embodiment, and the fourth embodiment described above, the generation unit 21 performs “(3) Construction of a traffic light control model” and “(4) Operation of a traffic light control model”. Signal information is generated / set, determination of abnormality, etc. (steps S102, steps S302 to S307, steps S702 to S705) ”is performed. However, separate generation units (for example, the first generation unit and the second generation unit) are performed. Part) may do. In the third embodiment described above, the generation unit 21 generates and sets signal information and determines abnormality in “(3) Construction of traffic signal control model and threshold setting” and “(4) Operation of traffic signal control model”. Etc. (steps S502 to S505) ”are performed, but different generation units (for example, the first generation unit and the second generation unit) may perform the same.

  By the way, in the map generation system described in Patent Document 1 (International Publication No. 2014/157359), the extraction accuracy for extracting the driving support location in the driving support system can be improved. However, in this system, it is possible to estimate a point requiring attention based on the vehicle speed information of the vehicle, but it is easy to recognize that it is a point requiring attention when determining whether or not the driver is a point requiring attention. There is no disclosure or suggestion of means to do this.

  On the other hand, the signal system according to the embodiment of the present invention includes a vehicle 1, a collection unit 20 that collects predetermined information, and a generation unit 21 that generates signal information of a predetermined point based on the predetermined information. Prepare. The vehicle 1 displays signal display information based on the signal information in a predetermined space inside the vehicle 1.

  With such a configuration, it is possible to visualize a point requiring attention. Therefore, a driver or the like can easily recognize a point requiring attention.

  In the signal system according to the embodiment of the present invention, the predetermined point is an intersection I1 where no traffic light equipped with a signal lamp is installed, and the predetermined information is roads R10, R11, R12, R13 flowing into the intersection I1. Contains the location information of the existing vehicle located above.

  With such a configuration, it is not necessary to install a traffic light at the intersection I1, so that, for example, the cost for installing and operating the traffic light can be reduced.

  In the signal system according to the embodiment of the present invention, the predetermined point is an intersection I2 where a traffic signal including one or more signal lamps is installed, and at least one of the signal lamps stops operating. The predetermined information includes position information of existing vehicles located on the roads R20, R21, R22, R23 flowing into the intersection I2.

  With such a configuration, for example, even if the operation of the signal lamp installed at the intersection I2 is stopped, the driver or the like uses the signal display information related to the intersection I2 displayed on the vehicle to indicate signals necessary for traveling the vehicle. Since the information can be grasped, traffic operation can be continued appropriately.

  Further, in the signal system according to the embodiment of the present invention, the predetermined information is all the existing vehicles located on all roads R10, R11, R12, R13 flowing into the intersection I1, or all flowing into the intersection I2. It includes the position information of all existing vehicles located on the roads R20, R21, R22, R23.

  With such a configuration, traffic signal control can be performed based on the position information of all existing vehicles, so that traffic operation can be performed appropriately, and vehicles can be managed intensively.

  In the signal system according to the embodiment of the present invention, the predetermined information includes abnormality detection information regarding the first point on the road in the traveling direction of the vehicle 1, and the predetermined point is from the position of the vehicle 1 to the first point. The generation unit 21 generates signal information according to the degree of abnormality included in the abnormality detection information.

  With such a configuration, when an abnormality at the first point is detected, the driver, etc. can grasp the abnormality at a predetermined point before reaching the first point. You can call attention.

  Further, in the signal system according to the embodiment of the present invention, the predetermined information includes a detection result of the number of pedestrians by the sensor 30a installed at the first point, and the degree of abnormality includes the detection result and a predetermined threshold value. It is determined according to the comparison.

  With such a configuration, the driver or the like can sense a point where a sudden jump of a human being occurs, such as a school road or a residential area, and urge the driver or the like to be aware of the sudden jump of a human. it can.

  Further, in the signal system according to the embodiment of the present invention, the predetermined information includes a detection result regarding at least one of falling rocks and collapse by the sensor 30b installed at the first point, The degree is determined according to a comparison between the sensing result and a predetermined threshold value.

  With such a configuration, the driver or the like can sense a point where a falling rock or a collapse is likely to occur, such as a mountain, and can prompt the driver or the like to be aware of the falling rock or the collapse.

  Further, in the signal system according to the embodiment of the present invention, the predetermined information includes the congestion end position and the position of the vehicle 1 downstream from the first point, and the degree of abnormality is the position of the vehicle 1 from the congestion end position. And a plurality of determination distances set based on a plurality of decelerations.

  With such a configuration, the driver or the like can detect the tail position of the traffic jam, so that a rear-end collision with the vehicle at the traffic jam tail position can be prevented.

  In the signal system according to the embodiment of the present invention, the vehicle 1 includes a control unit 11 that controls the running and stopping of the vehicle 1 based on the signal information.

  Thus, by controlling whether the vehicle 1 itself passes, for example, a predetermined point or stops before the predetermined point, the load on the driver or the like can be reduced.

  In the signal system according to the embodiment of the present invention, the signal display information includes information capable of recognizing the signal lamp and its lamp color.

  In this way, by displaying in the appearance format of the signal lamp familiar to the driver or the like, it is easy for the driver or the like to recognize the point requiring attention more easily.

  Moreover, the server 2 provided with the collection part 20, the production | generation part 21, and the transmission part 22 which transmits signal information to the vehicle 1 is used for the signal system which concerns on embodiment of this invention.

  With such a configuration, for example, the vehicle 1 that has received the signal information displays it in a predetermined space inside the vehicle 1, so that a point requiring attention can be visualized. Therefore, a driver or the like can easily recognize a point requiring attention.

  The above embodiment should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

The above description includes the following features.
[Appendix 1]
A signal program used in a signaling system,
Computer
A collection unit for collecting predetermined information;
A generating unit that generates signal information of a predetermined point based on the predetermined information;
For functioning as a transmission unit for transmitting the signal information to the vehicle,
Signal program.
[Appendix 2]
An in-vehicle device;
A collection unit for collecting predetermined information;
A generating unit that generates signal information of a predetermined point based on the predetermined information;
A signaling system comprising:
The in-vehicle device displays signal display information based on the signal information in a predetermined space inside a vehicle including the in-vehicle device.
Signal system.

1, 1a, 1b, 1c, 1d, 1e, 1f, 1g, 1h Vehicle 10 Display unit 11 Control unit 2 Server 20 Collection unit 21 Generation unit 22 Transmission unit 30a, 30b, 30c Sensor 1A Vehicle group R10, R11, R12 , R13, R20, R21, R22, R23 Road I1, I2 Intersection SN1, SN2 Traffic light

Claims (12)

A vehicle,
A collection unit for collecting predetermined information;
A generating unit that generates signal information of a predetermined point based on the predetermined information;
A signaling system comprising:
The vehicle displays signal display information based on the signal information in a predetermined space inside the vehicle.
Signal system. The predetermined point is an intersection where a traffic light equipped with a signal lamp is not installed,
The predetermined information includes position information of existing vehicles located on a road flowing into the intersection.
The signaling system according to claim 1. The predetermined point is an intersection where a traffic signal including one or a plurality of signal lamps is installed,
At least one of the signal lights has stopped operating;
The predetermined information includes position information of existing vehicles located on a road flowing into the intersection.
The signaling system according to claim 1.   The signal system according to claim 2 or 3, wherein the predetermined information includes position information of all existing vehicles located on all roads flowing into the intersection. The predetermined information includes abnormality detection information related to a first point on the road in the traveling direction of the vehicle,
The predetermined point is a point from the position of the vehicle to the first point,
The generation unit generates the signal information according to a degree of abnormality included in the abnormality detection information.
The signaling system according to claim 1. The predetermined information includes a result of sensing the number of pedestrians with a sensor installed at the first point,
The degree of abnormality is determined according to a comparison between the sensing result and a predetermined threshold.
The signal system according to claim 5. The predetermined information includes a detection result relating to at least one of falling rocks and collapsed by a sensor installed at the first point,
The degree of abnormality is determined according to a comparison between the sensing result and a predetermined threshold.
The signal system according to claim 5. The predetermined information includes a traffic jam tail position downstream of the first point and the position of the vehicle,
The degree of the abnormality is determined in accordance with a comparison between a distance from the congestion end position to the vehicle position and a plurality of determination distances set based on a plurality of decelerations.
The signal system according to claim 5. The vehicle includes a control unit that controls travel and stop of the vehicle based on the signal information.
The signal system according to any one of claims 1 to 8. The signal display information includes information capable of recognizing a signal lamp and its lamp color,
The signaling system according to any one of claims 1 to 9. The collecting unit;
The generating unit;
A transmission unit for transmitting the signal information to the vehicle,
A server used in the signaling system according to claim 1. Collecting predetermined information;
Generating signal information of a predetermined point based on the predetermined information;
Displaying signal display information based on the signal information in a predetermined space inside the vehicle,
Signal display method.

Images