JP2018180907A - Traffic prediction program, traffic prediction apparatus, and traffic prediction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a traffic prediction program which can predict a traffic density to a destination.SOLUTION: A traffic prediction program instructs a computer to execute processing in which, when a vehicle receives an output request of a prediction of a traffic density from a specific spot to a predetermined destination in a time zone in which the vehicle can arrive at the predetermined destination, a traffic density to the predetermined destination in the time zone in which the vehicle can arrive at the predetermined destination is predicted on the basis of a travel history data group in a time zone older than a time at which the output request of the prediction is received.SELECTED DRAWING: Figure 14

Description

  The present invention relates to a traffic prediction program, a traffic prediction device, and a traffic prediction method.

In order to determine whether or not to take a break when driving a vehicle for a long time, for example, it is important from the aspect of traffic safety to grasp the traffic situation on a freeway.
For this reason, for example, a congestion state detection system for detecting a congestion state of a car on a road has been proposed (see, for example, Patent Document 1 etc.).

JP 2005-135234 A

  However, although the technology described in Patent Document 1 can detect the congestion state of the vehicle in real time, it has a problem that prediction is difficult.

  In one aspect, it is an object of the present invention to provide a traffic prediction program, a traffic prediction device, and a traffic prediction method capable of predicting the traffic volume to a destination.

  In one embodiment, the traffic prediction program receives the output request of the prediction of the traffic volume from the specific point in the time zone when the vehicle can arrive at the predetermined point to the predetermined point. The computer is made to execute a process of predicting the traffic volume to the predetermined point in the time zone in which the vehicle can arrive at the predetermined point based on the traveling history data group in the past time zone from the received time.

  In one aspect, it is possible to provide a traffic prediction program, a traffic prediction device, and a traffic prediction method capable of predicting the traffic volume to a destination.

FIG. 1 is a diagram showing an example of a system having a traffic prediction device of the present invention. FIG. 2 is an explanatory view showing an example of the flow of a vehicle traveling from each departure point to each destination via a point α which is the current location of a certain vehicle. FIG. 3 is an explanatory view showing an example of the flow of the vehicle with reference to the time t ₀ when passing through the point α which is the current position in the “predicted travel history data group of the day to be predicted”. FIG. 4 is an explanatory view showing an example of the flow of the vehicle based on the time t ₀ when passing through the point α which is the current position in the “preceding day of travel history data group from the day of prediction”. FIG. 5 is an explanatory view showing an example of extracting a traveling history data group similar to “a traveling history data group on the current day to be predicted” from “a traveling history data group on the previous day to be predicted”. FIG. 6 is an explanatory view showing an example of a functional configuration of the traffic prediction device. FIG. 7 is a diagram showing an example of travel history data received by the communication unit. FIG. 8 is a diagram showing an example of the traveling history data stored in the storage unit. FIG. 9 is a diagram illustrating an example of the route data stored in the storage unit. FIG. 10 is an explanatory view showing an example of a map image including a distribution of departure places. FIG. 11 is an explanatory view showing an example of the hardware configuration of the traffic prediction apparatus. FIG. 12 is a flowchart showing an example of the flow from platform analysis processing to notification processing. FIG. 13 is a diagram showing an example in which the information display device displays the predicted result. FIG. 14 is a flow chart showing an example of the flow in which the traffic prediction device predicts the congestion rate to the destination. FIG. 15 is an explanatory view showing another example of the flow of the vehicle from each departure point to each destination via the point α which is the current location of a certain vehicle. FIG. 16 is a diagram showing another example in which the information display device displays the predicted result.

  Hereinafter, one embodiment of the present invention will be described, but the present invention is not limited to this embodiment.

FIG. 1 is a diagram showing an example of a system 10 having a traffic prediction device 100 of the present invention.
In the system 10, for example, the traffic prediction apparatus 100 predicts the traffic volume to a predetermined point on the expressway, and displays the traffic volume to the predicted predetermined point to the user of the expressway or the road manager. It is a thing.

  As shown in FIG. 1, the system 10 includes a traffic prediction apparatus 100, an information display apparatus 200 installed along a road, and a terminal device 300a mounted on vehicles 400a, 400b, 400c,. , 300b, 300c,...

The terminal devices 300 a, 300 b, 300 c,... Are communicably connected to the traffic prediction apparatus 100 via the network 500. In addition, the traffic prediction device 100 is communicably connected to the information display device 200.
Since the terminal devices 300a, 300b, 300c,... Have the same configuration as each other, they will be collectively referred to as “terminal device 300” below. Also, the vehicles 400a, 400b, 400c, ... may be simply referred to as "vehicles" when it is not necessary to distinguish them.

The terminal device 300 is, for example, a digital tachograph mounted on a commercial vehicle such as a truck, an on-vehicle device of a car navigation system mounted on a passenger car, and has a GPS (Global Positioning System) unit, a speed sensor, and the like. The terminal device 300 acquires traveling history data in which position data, velocity data, and the like are linked with time data by these speed sensors or the like, and transmits the acquired traveling history data to the traffic prediction apparatus 100.
Although the traffic prediction apparatus 100 receives the traveling history data from the terminal device 300, the present invention is not limited to this. For example, the traveling history data acquired by ETC (Electronic Toll Collection System) may be used. You may make it receive.

The traffic prediction apparatus 100 stores the traveling history data transmitted from each of the terminal devices 300 as a traveling history data group in the storage unit, and predicts the traffic volume to a predetermined point based on the stored traveling history data group.
Specifically, when traffic prediction device 100 receives an output request for prediction of traffic volume to a predetermined point in a time zone in which a vehicle can arrive at a predetermined point, traffic prediction device 100 reaches a predetermined point based on travel history data. Predict traffic.

Here, the vehicle includes, for example, a passenger car and a commercial vehicle.
The predetermined point can be specified as appropriate, and for example, a destination such as an interchange of a freeway can be mentioned.
The specific point is appropriately selected according to the user's instruction, and may be, for example, the point at which the output request for traffic volume prediction is sent. In the present embodiment, the specific point is a point α.
The time zone which can arrive at a predetermined point means the range of a fixed time calculated from the distance from the current position of the vehicle to the predetermined point and the average speed of the vehicle, and the length of the range is appropriately selected. be able to.
Although the transmission source of the output request of the traffic volume to the predetermined point is each terminal device 300 in the present embodiment, the present invention is not limited to this. For example, a portable terminal such as a smart phone owned by a driver or a road manager An apparatus, an information processing apparatus such as a personal computer, and the like can be given.

  In the present embodiment, the information display apparatus 200 is an electric light bulletin board installed on the side of the predicted route direction from the point at which the output request for prediction is received, and in front of a predetermined distance from the predetermined point. The information display device 200 displays the traffic volume to the predetermined point predicted by the traffic prediction device 100 for the driver of the vehicle. As a result, the driver of the vehicle can easily determine which parking facility is to take a break, thereby reducing accidents due to driver fatigue.

In the present embodiment, the display method by the information display device 200 is represented by the required time to a predetermined point.
In the present embodiment, although the information display device 200 displays the required time to the predetermined point, the present invention is not limited thereto. For example, the display of the digital tachograph or the on-vehicle device of the car navigation system reaches the predetermined point. The required time may be displayed. In addition, the display of the information display device 200 or a digital tachograph or an on-vehicle device of a car navigation system may display a map image as shown in FIG. 10 described later. Furthermore, based on the map image as shown in FIG. 10 displayed on the display of the information processing apparatus of the road manager, the information display apparatus 200 may display the information that the road manager has judged to be displayed. .

The information display device 200 is installed in front of a predetermined distance from a predetermined point, and displays, to the driver of the vehicle, the traffic volume in the direction in which the traffic volume predicted by the traffic prediction apparatus 100 is the largest. This makes it easier for the driver of the vehicle to decide whether to detour or at which parking facility to take a break.
In the present embodiment, the information display device 200 is described as being installed in front of a predetermined distance from a predetermined point, but the present invention is not limited to this. For example, the information display device 200 is installed in SA. May be When the information display device 200 is installed in the SA, the congestion can be prevented by guiding the SA to move promptly so as not to be caught in the congestion.

  Hereinafter, the process of the traffic prediction apparatus 100 predicting the traffic volume to the destination of the expressway will be specifically described with reference to FIGS. 2 to 6 as an example.

  FIG. 2 is an explanatory view showing an example of the flow of a vehicle traveling from each departure place A, B, C to each destination C, D, E via a point α which is the current location of a certain vehicle. The shading of the oval mark indicating the place of departure or destination in FIG. 2 indicates the number of vehicles traveling from the place of departure or destination as the place of departure or destination; Many, low concentration indicates that the number of vehicles is small.

FIG. 3 is an explanatory view showing an example of the flow of the vehicle based on the time t ₀ when passing through the point α which is the current position in “the travel history data group of the day to be predicted”. , C show the movement of the car group that has departed each time. In FIG. 3, the vertical axis is the distance from the point α which is the current position, and the traveling direction is positive. The horizontal axis is a time axis based on 9 am.
The traffic prediction apparatus 100 may arrive at the destination from the terminal device 300 of the vehicle when the vehicle passes the point α at 9 am in the "predictive travel history data group of the day to be predicted" in FIG. Receive an output request for forecasting the traffic volume to the destination in the time zone.
In this embodiment, a vehicle traveling at an average speed of 70 km / h passes through the point α, and the destination existing on the planned route is 140 km ahead (2 L = 140 km), so the vehicle may arrive at the destination The time will be 11 am. Also, in this embodiment, the time zone in which the vehicle can arrive at the destination is 30 minutes before and after, for example, 10 am in the case where the time when the vehicle can arrive at the destination is 11 am. It is a time zone from 30 minutes to 11:30 am.

Next, the traffic prediction apparatus 100 that has received the output request for the prediction of the traffic volume to the destination corresponds to the time zone corresponding to the time zone that can arrive at the destination from "the travel history data group past from the day of prediction" Extract the vehicles that have arrived at the destination.
FIG. 4 is an explanatory view showing an example of the flow of the vehicle based on the time t ₀ when passing through the point α which is the current position in the “preceding day of travel history data group from the day of prediction”. In FIG. 4, the vertical axis is the distance from the point α which is the current position, and the traveling direction is positive. The horizontal axis is a time axis based on 9 am.
Here, the traffic prediction apparatus 100 extracts a vehicle that has arrived at the destination in the time zone from 10:30 am to 11:30 am from “the travel history data group past the day of prediction” in FIG. 4. .
In the present embodiment, the extraction of the vehicle that has arrived at the destination is determined based on the position data of the vehicle included in the traveling history data.

Then, the traffic prediction apparatus 100 predicts the traffic volume to the destination in the time zone in which the vehicle can arrive at the destination based on the extracted travel history data of the vehicle. In other words, the traffic prediction apparatus 100 “predicts from what day and when it is the vehicle that arrived at the destination in the time zone from 10:30 am to 11:30 am from the day of“ predicting that day ”. The traffic volume to the destination is predicted based on the travel history data group.
FIG. 5 is an explanatory view showing an example of extracting a traveling history data group similar to “a traveling history data group on the current day to be predicted” from “a traveling history data group on the previous day to be predicted”.
As shown in FIG. 5, in order to predict the traffic volume to the destination, the traffic prediction apparatus 100 sets “the travel history data group of the day to be predicted” in a time zone before departure which accepts the output request of the prediction. The “previous travel history data group from the day of prediction” in the same time zone is extracted.
In addition, as a method of quickly extracting "previous travel history data group from the current day" in the same time zone, which is most similar to "predicted current day travel history data group", for example, data items of the travel history data The method of extracting from the thing with the near value of is mentioned. Although the data items will be described later, whether it is a day of the week, a holiday or not, the weather, etc. are given priority.

  Next, the functional configuration and hardware configuration of the traffic prediction apparatus 100 will be described.

(Traffic forecasting device)
<Functional Configuration of Traffic Prediction Device>
FIG. 6 is an explanatory view showing an example of a functional configuration of the traffic prediction apparatus 100. As shown in FIG.
As shown in FIG. 6, the traffic prediction apparatus 100 includes a communication unit 110, a storage unit 120, and a control unit 130. The control unit 130 has learned artificial intelligence for predicting the traffic to the destination.

Communication unit 110 receives traveling history data from terminal device 300 mounted on each vehicle based on an instruction from control unit 130, and stores the data in storage unit 120.
Further, the communication unit 110 receives the output request of the prediction of the traffic volume to the destination in the time zone in which the vehicle can arrive at the destination, which is transmitted from the terminal device 300.

  The storage unit 120 includes a travel history database (hereinafter, may be referred to as a “travel history DB”) 121. The traveling history data received by the communication unit 110 is stored in the traveling history DB 121. The storage unit 120 also stores trip data and route data.

FIG. 7 is a diagram showing an example of traveling history data received by the communication unit 110. As shown in FIG.
As shown in FIG. 7, in the present embodiment, the travel history data is “vehicle ID, trip ID, position (longitude, latitude), speed, departure date, departure date, departure location (longitude, latitude), arrival date, destination location (longitude , Latitude), travel distance, and time required.

The data item of "vehicle ID" is data for identifying the said vehicle in which the terminal device 300 is mounted, and is preset.
The data item of "trip ID" is used to identify a trip which is a unit for moving from a certain departure place to a certain destination.
Data items of “date and time” and “position (longitude, latitude)” are acquired by a GPS (Global Positioning System) unit mounted on the terminal device 300.
The data item of "speed" is synchronized with the GPS unit and acquired from the axle of the vehicle using the speed sensor that the terminal device 300 has.
The data items of "departure date and time" and "departure location (longitude, latitude)" are the departure date and time of the trip and the longitude and latitude of the departure location.
The data items “arrival date and time” and “destination (longitude, latitude)” are the arrival date and time of the trip and the longitude and latitude of the destination.
The data item of "moving distance" is the moving distance from the departure point to the current point.
The data item of "time required" is the time required from the place of departure to the current place.

FIG. 8 is a diagram showing an example of the traveling history data stored in the storage unit 120. As shown in FIG.
As shown in FIG. 8, in the present embodiment, in addition to the data items of the travel history data shown in FIG. 7, data items of “day, holiday, weather” are included.
By including the data items of the day of the week, a holiday, and / or the weather in the travel history data, the traffic prediction apparatus 100, for example, predicts the past from the travel history data group when the day to be predicted is a clear day of the first day of consecutive holidays. It is possible to extract the running history data of the sunny day of the first day of the consecutive holidays. For this reason, the traffic prediction apparatus 100 can extract the traveling history data similar to the environment of the day to be predicted, so that the accuracy of predicting the congestion rate of SA3 can be improved.

The data item of “day of the week, holidays” is acquired from the database of “day of the week, holidays” (not shown) of the storage unit 120 with reference to the data of “date and time”, and the data item transmitted from the terminal device 300 It is linked to and stored.
The data item of "weather" is acquired from the server apparatus having weather data of various places via the network 500 with reference to the data of "date and time" and "position (longitude, latitude)" of the traffic prediction apparatus 100, It is stored in association with the data item transmitted from the device 300.
In the present embodiment, the data items of "day of the week, holidays, weather" are linked to the traveling history data by the traffic prediction apparatus 100, but the present invention is not limited to this. The data item of “” may be acquired and linked to the traveling history data.

FIG. 9 is a diagram showing an example of the route data stored in the storage unit 120. As shown in FIG.
As shown in FIG. 9, the route data includes data items of "vehicle ID, trip ID, link ID (longitude, latitude), link entry date, link required time, link average speed" in this embodiment. About the data item of "vehicle ID, trip ID", since it is the same as that of "vehicle ID, trip ID" mentioned above, explanation is omitted.

The data item of "link ID (longitude, latitude)" is an identifier for identifying a predetermined road section. Further, the predetermined road section means, for example, a road section from a predetermined SA to a predetermined junction.
The data item of “link entry date and time” is the date and time when the vehicle enters the road section corresponding to the link ID.
The data item of "link required time" is the time when the vehicle travels the road section corresponding to the link ID.
The data item of “link average speed” is the average speed of the vehicle when passing through the road section corresponding to the link ID.

<< control section >>
The control unit 130 includes an extraction unit 131, an image generation unit 132, a calculation unit 133, a learning unit 134, and an inference unit 135. The function combining the learning unit 134 and the inference unit 135 may be referred to as artificial intelligence. Although the details will be described later, in the present embodiment, the control unit 130 uses the learned image recognition function of artificial intelligence to indicate the distribution of the departure point of the vehicle that has passed the point α at 9 am on the day of prediction. From the image of 1, it predicts by inference of traffic to the destination.

  The extraction unit 131 extracts, from the travel history data group of vehicles, vehicles that have arrived at the destination in a time zone corresponding to a time zone that can arrive at the destination.

  The image generation unit 132 indicates the distribution of the departure point of the vehicle based on travel history data of a time zone corresponding to a past time zone traced back by a predetermined time interval before the time when the output request for prediction is received. Generate an image of 1. This is because it takes time due to variations in the communication speed due to the radio wave reception state and the processing speed of the device until the travel history data is stored in the traffic prediction device 100 from each terminal device 300 of the vehicle being traveled. That is, by setting the predetermined time interval, the traffic prediction apparatus 100 can generate the first image based on the traveling history data group in which more traveling history data are gathered, and therefore the traffic volume to the destination is predicted. Accuracy can be improved. In the present embodiment, since the predetermined time interval is set to 30 minutes, as shown in FIG. 4, the traffic prediction apparatus 100 traces back 30 minutes from 9:00 am when the output request for prediction is received, and goes back to 8:30 am A first image is generated based on the travel history data group before the minute.

FIG. 10 is an explanatory view showing an example of a map image including the distribution of departure places, and shows the departure place, destination, and route of the vehicle that has passed through the point α at 9 am. The place of departure or the destination in FIG. 10 is shown by being painted over for each city. The shading indicates the number of vehicles traveling from the departure place or destination to the departure place or destination, and indicates that the number of vehicles is high when the concentration is high and the number of vehicles is low when the concentration is low. There is. In addition, the city designated as the destination is displayed bordered on the outer periphery. The density of the route indicates the traffic volume of the route. When the concentration is high, the traffic volume of the route is high, and when the concentration is low, the traffic volume of the route is low.
The first image shows only the distribution of the departure point of FIG.

  Further, the image generation unit 132 is a group of travel history data from the current day to be predicted, and is a set of second images generated at every hour based on the travel history data of the vehicle extracted by the extraction unit 131. The second image group is stored in the storage unit 120 as a teacher image data group. In addition, the time of day means a time without a fraction of minutes or seconds.

  The calculation unit 133 calculates the traffic volume to the destination corresponding to each second image, associates it with each second image, and stores it in the storage unit 120 as a teacher correct data group.

In addition, in the following platform processing, the calculation unit 133 performs each calculation processing based on travel history data that is past from the day of prediction.
(1) As data related to the point α, the traffic volume for 30 minutes before and after the time t _{0 when} the output request for prediction at the point α is received is calculated.
(2) As data relating to the destination, the continuous traveling time in the vicinity of the destination, the number of vehicles arriving at the destination, the average required time of the vehicles arriving at the destination, and the traffic volume to the destination are calculated.
(3) The traffic volume between the point α and the destination and the average required time between the point α and the destination are calculated as data related to traveling between the point α and the destination.
(4) As data relating to departure places and destinations, departure zone information and traffic by zone of vehicles passing through point α in 30 minutes before and after time t _{0 when} the output request for prediction at point α is received Calculate an average required time between the points α and α, and an average required time between the points α and the destination.

  The learning unit 134 obtains a learned weight so that the traffic volume from the first image to the destination can be inferred from the relationship between the teacher image data group and the teacher correct data group using a deep learning method.

The inference unit 135 uses the learned weights obtained by the learning unit 134 to carry out similarity of the features of the generated image, extract past travel history data to be a basis for prediction, and calculate the traffic volume to the destination. Predict.
Based on the first image generated based on the current day's travel history data group to be predicted, the similarity of the image features is generated every second hour based on the past travel history data group from the current day to be predicted The determination is made by comparing each with the second image of the group of images.
Thus, the traffic prediction apparatus 100 can accurately predict the traffic volume to the destination by using the learned artificial intelligence.

  In the present embodiment, the traffic prediction apparatus 100 predicts the traffic volume to the destination using the learned artificial intelligence image recognition function, but the present invention is not limited to this, for example, standard deviation, etc. It may be predicted by a method using the numerical value of.

<Hardware Configuration of Traffic Prediction Device>
FIG. 11 is an explanatory view showing an example of the hardware configuration of the traffic prediction apparatus 100. As shown in FIG.
As shown in FIG. 11, the traffic prediction apparatus 100 has the following units. Each unit is communicably connected via a bus 189.

  A CPU (central processing unit) 181 executes processing performed by each unit of the control unit 130. The processor that executes the software is hardware.

A RAM (Random Access Memory) 182 functions as a working range which is expanded when the various programs stored in the storage unit 120 are executed by the control unit 130.
Examples of the RAM 182 include a dynamic random access memory (DRAM) and a static random access memory (SRAM).

  A GPU (Graphics Processing Unit) 183 executes calculation processing necessary for processing image data.

  A VRAM (Video Random Access Memory) 184 is a memory area for holding data necessary for displaying an image on a display such as a monitor, and is also referred to as graphics memory or video memory. The VRAM 184 may be a dedicated dual port one or a DRAM or SRAM.

  The input device 185 is not particularly limited as long as it can receive various requests for the traffic prediction apparatus 100, and any known device can be used as appropriate, and examples thereof include a keyboard, a mouse, a touch panel, and a microphone.

  The output device 186 is not particularly limited, and any known device can be used as appropriate, and examples thereof include a display and a speaker.

  The communication interface 187 is not particularly limited, and any known communication interface can be used as appropriate, and examples thereof include communication devices using wireless or wired communication.

The main storage device 188 stores a traffic prediction program, and the CPU 181 and / or the GPU 183 read out and execute the program to extract the extraction unit 131, the image generation unit 132, the calculation unit 133, the learning unit 134, and the inference unit 135. Act as. In addition to the traffic prediction program, the main storage unit 188 stores various programs, data, and the like necessary for the control unit 130 to execute various programs. Specifically, the main storage device 188 stores a boot program such as a Basic Input / Output System (BIOS), an Extensible Firmware Interface (EFI), and the like.
The main storage device 188 is not particularly limited as long as various information can be stored, and can be appropriately selected according to the purpose. Examples thereof include a solid state drive and a hard disk drive. Also, the main storage device 188 may be a portable storage device such as a CD (Compact Disc) drive, a DVD (Digital Versatile Disc) drive, or a BD (Blu-ray (registered trademark) Disc) drive. Furthermore, the main storage device 188 may be part of a cloud that is a group of computers on a network.

  FIG. 12 is a flowchart showing an example of the flow from platform analysis processing to notification processing. A flow in which artificial intelligence included in the traffic prediction apparatus 100 predicts the traffic volume to the destination by the deep learning method will be described according to the flowchart shown in FIG.

In step S101, when performing the platform analysis process, the calculation unit 133 shifts the process to S102.
In the platform analysis process, the following processes (1) to (4) are performed at every hour until the previous month with respect to major passage points across the country based on travel history data in the past from the day of prediction.
(1) As data related to the point α, the traffic volume for 30 minutes before and after the time t _{0 when} the output request for prediction at the point α is received is calculated.
(2) As data relating to the destination, the continuous travel time in the vicinity of the destination, the number of vehicles arriving at the destination, the average arrival time of vehicles arriving at the destination, and the traffic volume to the destination are calculated.
(3) The traffic volume between the point α and the destination and the average required time between the point α and the destination are calculated as data related to traveling between the point α and the destination.
(4) As data relating to departure places and destinations, departure zone information and traffic by zone of vehicles passing through point α in 30 minutes before and after time t _{0 when} the output request for prediction at point α is received Calculate an average required time between the points α and α, and an average required time between the points α and the destination.

In step S102, when the image generation process is performed, the image generation unit 132 shifts the process to S103.
In the image generation process, in this embodiment, every hour based on the traveling history data group of the time zone corresponding to the past time zone traced back by a predetermined time interval before the time when the predicted output request is received. A first image is generated that shows the distribution of the departure point of the vehicle.
In addition, the image generation unit 132 is a teacher image of a second image group which generates a second image indicating the distribution of the departure place of the vehicle at each hour based on the travel history data of the vehicle extracted by the extraction unit 131. Store as a data group.
Furthermore, the calculation unit 133 calculates the traffic volume to the destination corresponding to each second image, associates it with each second image, and stores it in the storage unit 120 as a teacher correct data group.

In step S103, the learning unit 134 shifts the process to S104 when the learning process is performed.
In the learning process, the learning unit 134 uses the learned weights so that the traffic volume from the first image to the destination can be inferred using the deep learning method from the relationship between the teacher image data group and the teacher correct data group. obtain.

In step S104, when the inference processing is performed, the inference unit 135 shifts the processing to S105.
In the inference process, the inference unit 135 uses the learned weights obtained by the learning unit 134 to carry out similarity of the features of the generated image, extract past travel history data to be a basis for prediction, and reach the destination Predict the traffic volume of

In step S105, the traffic prediction device 100 ends the present processing when the notification processing is performed on the information display device 200.
In the notification process, the traffic prediction apparatus 100 transmits, to the information display apparatus 200, the predicted traffic volume to the destination. The information display device 200 displays the time required for the destination predicted by the traffic prediction device 100 to the driver of the vehicle, as shown in FIG.

  FIG. 14 is a flow chart showing an example of a flow in which the traffic prediction apparatus 100 predicts the required time to the destination. A flow in which the traffic prediction apparatus 100 predicts the required time to the destination will be described according to the flowchart shown in FIG.

  In step S201, the traffic prediction apparatus 100 shifts the process to S202 upon receiving, from the terminal device 300 of the vehicle, an output request for predicting the required time to the destination in the time zone in which the vehicle can arrive at the destination.

  In step S202, the traffic prediction apparatus 100 ends this processing when it predicts the required time to the destination in the time zone in which the vehicle can arrive at the destination based on the traveling history data.

  As described above, when the traffic prediction device receives an output request for prediction of the required time to a predetermined point in a time zone where the vehicle can arrive at the predetermined point, the traffic prediction device leaves a predetermined time interval more than the received time. The required time can be predicted on the basis of the travel history data group in the past time zone that has been traced back.

  In addition, as shown in FIG. 15, when it is predicted that the traffic volume to the F direction increases when the vehicle passes the point α at 9:00 pm, as shown in FIG. The required time to the F area in the band may be displayed.

Further, the following appendices will be disclosed regarding the above embodiment.
(Supplementary Note 1)
When receiving an output request for prediction of traffic volume from a specific point in a time zone in which a vehicle can arrive at a predetermined point to the predetermined point,
Predicting a traffic volume to the predetermined point in a time zone in which the vehicle can arrive at the predetermined point, based on a travel history data group in a time zone before the time when the output request for the prediction is received;
A traffic prediction program that causes a computer to execute a process.
(Supplementary Note 2)
The starting point of the vehicle generated at predetermined time intervals based on the travel history data group of a time zone corresponding to a past time zone traced back by a predetermined time interval before the time at which the prediction output request is received The traffic prediction program according to Supplementary Note 1, which extracts the past travel history data serving as a basis for prediction from the similarity of image features indicating the distribution of.
(Supplementary Note 3)
11. The traffic prediction program according to appendix 1 or 2, wherein the prediction result of the traffic volume to the predetermined point is displayed in front of a predetermined distance from the predetermined point on the predicted route.
(Supplementary Note 4)
The traffic prediction program according to any one of appendices 1 to 3, wherein the travel history data includes data of at least one of a day of the week, a holiday, and a weather.
(Supplementary Note 5)
When receiving an output request for predicting the traffic volume to the predetermined point in a time zone in which the vehicle can arrive at the predetermined point,
A time zone in which the vehicle can arrive at the predetermined point based on a travel history data group of a time zone corresponding to a past time zone traced back by a predetermined time interval before a time at which the prediction output request is received Predict traffic to the predetermined point in
A traffic prediction apparatus comprising a control unit that executes processing.
(Supplementary Note 6)
When receiving an output request for predicting the traffic volume to the predetermined point in a time zone in which the vehicle can arrive at the predetermined point,
A time zone in which the vehicle can arrive at the predetermined point based on a travel history data group of a time zone corresponding to a past time zone traced back by a predetermined time interval before a time at which the prediction output request is received Predict traffic to the predetermined point in
A traffic prediction method characterized in that a computer executes processing.

10 System 100 Traffic Prediction Device 130 Control Unit 200 Information Display Device 300 Terminal Device 400 Vehicle

Claims (6)

When receiving an output request for prediction of traffic volume from a specific point in a time zone in which a vehicle can arrive at a predetermined point to the predetermined point,
Predicting a traffic volume to the predetermined point in a time zone in which the vehicle can arrive at the predetermined point, based on a travel history data group in a time zone before the time when the output request for the prediction is received;
A traffic prediction program that causes a computer to execute a process.   The starting point of the vehicle generated at predetermined time intervals based on the travel history data group of a time zone corresponding to a past time zone traced back by a predetermined time interval before the time at which the prediction output request is received The traffic prediction program according to claim 1, wherein the past travel history data serving as a basis for prediction is extracted from the similarity of image features indicating the distribution of.   The traffic prediction program according to claim 1 or 2, wherein the prediction result of the traffic volume to the predetermined point is displayed in front of a predetermined distance from the predetermined point on the predicted route.   The traffic prediction program according to any one of claims 1 to 3, wherein the travel history data includes data of at least one of a day of the week, a holiday, and a weather. When receiving an output request for predicting the traffic volume to the predetermined point in a time zone in which the vehicle can arrive at the predetermined point,
A time zone in which the vehicle can arrive at the predetermined point based on a travel history data group of a time zone corresponding to a past time zone traced back by a predetermined time interval before a time at which the prediction output request is received Predict traffic to the predetermined point in
A traffic prediction apparatus comprising a control unit that executes processing. When receiving an output request for predicting the traffic volume to the predetermined point in a time zone in which the vehicle can arrive at the predetermined point,
A time zone in which the vehicle can arrive at the predetermined point based on a travel history data group of a time zone corresponding to a past time zone traced back by a predetermined time interval before a time at which the prediction output request is received Predict traffic to the predetermined point in
A traffic prediction method characterized in that a computer executes processing.