JP7102858B2 - Pathfinding system, route guidance system, route search program and route guidance program - Google Patents

Description

The present invention relates to a route search system, a route guidance system, a route search program, and a route guidance program.

Conventionally, a technique for identifying a vehicle route is known. For example, Patent Document 1 discloses a technique for searching a route based on a passing cost, so that the passing cost increases as the number of sharp curves in the road increases and the vehicle weight increases. The technology for suppressing fuel consumption by changing the above is disclosed.

Japanese Unexamined Patent Publication No. 2011-185604

Vehicles used to carry luggage are heavier than ordinary passenger cars. The recommended vehicle speed when traveling on a curve often differs between a heavy vehicle and a light vehicle. Therefore, if the weight of the vehicle is different, the travel time of the section including the curve will be different. In the prior art, it has not been possible to search for a route according to such a change in travel time due to the weight of the vehicle.
The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique for making it possible to use a route that reflects a change in travel time according to the weight of a vehicle.

In order to achieve the above objectives, the route search system searches for a route to reach the destination based on the destination acquisition unit for acquiring the destination of the vehicle and the passing cost according to the vehicle speed in the road section. The transit cost in the road section including the curve, which includes the search unit, is determined according to the recommended vehicle speed obtained based on the weight of the vehicle and the curvature of the curve.

Further, in order to achieve the above-mentioned object, the route search program uses a computer as a destination acquisition unit for acquiring the destination of the vehicle, and a route to reach the destination based on the passing cost according to the vehicle speed of the vehicle in the road section. It is a route search program that functions as a route search unit for searching for a path, and the passing cost in a road section including a curve is determined according to a recommended vehicle speed acquired based on the weight of the vehicle and the curvature of the curve.

Further, in order to achieve the above object, the route guidance system is acquired based on the passing cost of the vehicle in the road section according to the vehicle speed, and in the road section including the curve, based on the weight of the vehicle and the curvature of the curve. It is provided with a route acquisition unit for acquiring a route for reaching the destination of the vehicle and a route guidance unit for guiding the route, which are searched based on the passing cost determined according to the recommended vehicle speed.

Further, in order to achieve the above object, the route guidance program uses a computer based on the passing cost of the vehicle according to the vehicle speed in the road section, and the weight of the vehicle and the curvature of the curve in the road section including the curve. It functions as a route acquisition unit that acquires a route for reaching the destination of the vehicle and a route guidance unit that guides the route, which is searched based on the passing cost determined according to the recommended vehicle speed acquired.

That is, according to the route search system and the route search program, the passing cost of the curve is specified based on the recommended vehicle speed acquired based on the weight of the vehicle and the curvature of the curve. Therefore, a curve that needs to travel at a low speed due to the heavy weight of the vehicle is set to a passing cost according to the recommended vehicle speed. Therefore, if the search is performed based on the passing cost, it is possible to execute the route search that reflects the change in the travel time according to the weight of the vehicle. Further, according to the route guidance system and the route guidance program, the user can select a route that reflects the change in travel time according to the weight of the vehicle by traveling the vehicle according to the guided route.

It is a block diagram of a route search system and a route guidance system. It is a flowchart which shows the route search process. 3A and 3B are diagrams showing an example of route search. It is a figure which shows the example of a warning.

Here, embodiments of the present invention will be described in the following order.
(1) System configuration:
(1-1) Configuration of route guidance system:
(1-2) Configuration of pathfinding system:
(1-3) Operation manager terminal configuration (2) Route search processing:
(3) Other embodiments:

(1) System configuration:
FIG. 1 is a block diagram showing a configuration of a route guidance system 10 and a route search system 100 according to the present invention. In the present embodiment, the route search system 100 is used when carrying a load by a plurality of vehicles (in this embodiment, a transport vehicle such as a truck). In the present embodiment, the route search system 100 cooperates with the route guidance system 10 and the operation manager terminal 50 used in the vehicle. The operation manager terminal 50 is a terminal used by a business operator that provides a cargo transportation service using a plurality of vehicles, and is mainly used for performing operation management of a plurality of vehicles. One or more terminals are prepared for the operation manager terminal 50, and are installed at, for example, a base of a business operator. The route guidance system 10 may be used in each of a plurality of vehicles and may be mounted on the vehicle, or a portable terminal may be brought into the vehicle and used.

(1-1) Configuration of route guidance system:
In the present embodiment, the operation manager formulates a cargo transportation plan in response to a request for transportation from the cargo shipper, and specifies a travel plan for each of the plurality of vehicles. The travel plan includes at least the luggage for each vehicle and the destination to which the luggage is transported. Since the destination is the destination of the cargo, unloading work is performed at the destination.

Of course, there may be a plurality of luggage loaded on one vehicle. Further, there may be a plurality of destinations, and when a plurality of packages are unloaded at different points, each point can be a destination. In addition, when a new package is collected in the process of transportation, the point where the package is loaded can be the destination. Furthermore, when the transportation of the luggage is completed and the vehicle returns to the base with no luggage loaded, the base can be the destination. Further, the travel plan may include various other information, for example, the deadline for transporting the luggage to the destination, and the like.

In any case, in the present embodiment, it is necessary for each vehicle to travel according to the travel plan of each vehicle. The route guidance system 10 according to the present embodiment is a terminal for guiding a vehicle along a route according to a travel plan. The route guidance system 10 includes a control unit 20 including a CPU, RAM, ROM, and the like, a recording medium (not shown), a communication unit 15, a GNSS receiving unit 16, a vehicle speed sensor 17, and a gyro sensor 18. The control unit 20 can execute a route guidance program 21 (not shown) stored in a recording medium (not shown) or a ROM (not shown).

In a recording medium (not shown), information indicating a route to be traveled in order to carry out transportation according to the travel plan and map information are recorded. Map information is information used to identify the position of the vehicle and the facility to be guided, and specifies the node data indicating the position of the node set on the road on which the vehicle travels and the shape of the road between the nodes. It includes shape interpolation point data indicating the position of the shape interpolation point, link data indicating the connection between nodes, data indicating the position of features existing on the road and its surroundings, and the like. The attributes of the feature are associated with the data indicating the feature.

The GNSS receiving unit 16 is a device that receives a signal of the Global Navigation Satellite System, receives a radio wave from a navigation satellite, and outputs a signal for calculating the current location of the vehicle via an interface (not shown). The control unit 20 acquires this signal and acquires the current location of the vehicle. The vehicle speed sensor 17 outputs a signal corresponding to the rotational speed of the wheels provided in the vehicle. The control unit 20 acquires this signal via an interface (not shown) to acquire the vehicle speed. The gyro sensor 18 detects the angular acceleration for turning in the horizontal plane of the vehicle and outputs a signal corresponding to the direction of the vehicle. The control unit 20 acquires this signal and acquires the traveling direction of the vehicle. The vehicle speed sensor 17, the gyro sensor 18, and the like are used to identify the traveling locus of the vehicle. In the present embodiment, the current location is specified based on the departure position and the traveling locus of the vehicle, and the departure position and the traveling locus are specified. The current location of the vehicle specified based on the above is corrected based on the output signal of the GNSS receiving unit 16.

The communication unit 15 includes a circuit for communicating with another device. The control unit 20 can communicate with the route search system 100 via the communication unit 15. The control unit 20 acquires a route transmitted from the route search system 100 by the function of the route guidance program 21, and guides the vehicle according to the route.

That is, when the control unit 20 executes the route guidance program 21, the control unit 20 functions as the route acquisition unit 21a and the route guidance unit 21b. The route acquisition unit 21a is a program module that causes the control unit 20 to execute a function of acquiring a route transmitted from the route search system 100. That is, the control unit 20 communicates with the route search system 100 via the communication unit 15 by the function of the route acquisition unit 21a, and acquires information indicating the route searched by the route search system 100.

The route guidance unit 21b is a program module that causes the control unit 20 to execute a function of guiding a route. That is, the control unit 20 displays a map on a user I / F unit (display, speaker, etc.) (not shown) by the function of the route guidance unit 21b, and highlights the route displayed on the map. Then, the control unit 20 guides the vehicle to travel on the route by outputting a voice or the like indicating the traveling direction at an intersection or the like to the user I / F unit.

In the present embodiment, the route generated by the route search system 100 is a route searched based on the passing cost according to the vehicle speed of the vehicle in the road section. Further, in the present embodiment, when the road section includes a curve, the passing cost is determined according to the recommended vehicle speed acquired based on the weight of the vehicle and the curvature of the curve in the road section (details will be described later). ). Therefore, when the weight of the vehicle is heavy, the route is searched so as to avoid road sections where the weight of the vehicle is slower than other vehicles of general weight and the travel time is shortened as a result. Will be done. Therefore, the user of the route guidance system 10 (the driver of the vehicle) can use the route reflecting the change in the travel time according to the weight of the vehicle and drive the vehicle along the route.

(1-2) Configuration of pathfinding system:
The path search system 100 includes a control unit 200 including a CPU, RAM, ROM, and the like, a recording medium 300, and a communication unit 400. The communication unit 400 includes a circuit for exchanging information with the route guidance system 10 and the operation manager terminal 50, and the control unit 200 communicates with the route guidance system 10 and the operation manager terminal 50 via the communication unit 400. It can be performed. In addition, the control unit 200 can execute the program stored in the recording medium 300 or the ROM. In the present embodiment, the route search program 210 can be executed as this program.

Further, the traveling plan information 300a, the vehicle information 300b, the map information 300c, and the cost information 300d are recorded on the recording medium 300. The travel plan information 300a is information indicating a travel plan for each vehicle. The operation manager creates a travel plan for each vehicle using the operation manager terminal 50, and the identification information of each vehicle is used as the travel plan for each vehicle. Is transmitted to the route search system 100 at an arbitrary timing in association with. That is, the control unit 200 acquires the travel plan information 300a indicating the travel plan via the communication unit 400 and records it on the recording medium 300. When the travel plan information 300a is recorded, the luggage to be carried and the destination of each luggage are specified for each vehicle.

The vehicle information 300b is information indicating the weight of the vehicle in which the route guidance system 10 is used, and is information indicating the total weight when the vehicle is loaded with luggage. In the present embodiment, the weight of the vehicle is determined in advance, is associated with the vehicle identification information, and is recorded on the recording medium 300 as the vehicle information 300b. In the present embodiment, the sum of the weight in the unloaded state (body weight) and the maximum load capacity of the cargo is regarded as the weight of the vehicle. That is, the process of adding the weight of each individual cargo according to the loading status of the cargo is omitted, and the maximum weight of the vehicle is specified for each vehicle.

表１に示すように、車両情報３００ｂにおいては、車両の識別情報と車両の重量とを対応づけている。 In the present embodiment, the vehicle information 300b is determined from the specifications of the vehicle, but of course, other methods such as measurement by a sensor or the like may be adopted. Table 1 shows an example of vehicle information 300b of a plurality of vehicles.

As shown in Table 1, in the vehicle information 300b, the vehicle identification information and the weight of the vehicle are associated with each other.

The map information 300c is the same information as the map information recorded in the recording medium of the route guidance system 10, and indicates node data, shape interpolation point data, link data, positions of features existing on the road and its surroundings, and the like. Contains data etc. The data indicating the position of the feature includes the attributes of the feature. Further, in the present embodiment, the link data includes the distance of the road section indicated by the link data and the limited vehicle speed. When the road section includes a curve, the curvature of the curve is included in the link data. Of course, the distance and curvature of the road section may be calculated from the positions of the nodes and shape interpolation points.

表２に示すように、リンクデータには道路区間を示す識別情報（表２においてはＬ₁等と表記）が対応づけられており、識別情報に対して道路区間の距離、曲率、制限車速が対応づけられる。 Table 2 shows a part of the link data regarding the road section including the curve.

As shown in Table 2, the link data is associated with identification information indicating the road section (denoted as L ₁ etc. in Table 2), and the distance, curvature, and vehicle speed limit of the road section are associated with the identification information. Can be associated.

The cost information 300d is information indicating the passing cost for each road section indicated by the map information 300c, and the passing cost when selecting a route is associated with the link data indicating the road section. In the present embodiment, the transit cost is defined so that the larger the transit cost, the lower the possibility of being selected as the route.

Further, in the present embodiment, the transit cost is set to be a value proportional to the statistical length of travel time when passing through the road section. That is, by dividing the distance of each road section by the average vehicle speed of the vehicle in each road section, the statistical travel time of each road section can be obtained. The average vehicle speed of the vehicle in the road section may be obtained by various methods, and in the present embodiment, the vehicle speed is the limit vehicle speed of the road section (of course, the vehicle speed may be smaller than the limit vehicle speed), but it can be obtained by statistics or measurement. It may be the average vehicle speed obtained.

In the present embodiment, the statistical travel time of each road section is specified in advance, and the transit cost proportional to the length of the travel time is predetermined. Then, the passage cost of the road section is associated with the identification information of the road section (L ₁ , etc. shown in Table 2), and the cost information 300d is recorded in the recording medium 300. Therefore, by searching for a route that minimizes the transit cost, it is possible to search for a route that can reach the destination in the shortest time.

In the present embodiment, the passing cost determined in this way is referred to as a default cost. Of course, costs defined based on other ideas may be used together. For example, a distance cost that is proportional to the distance of a road section is defined, and a route that minimizes the total distance can be searched. Alternatively, a plurality of types of costs may be considered in various weights.

The default cost in this embodiment can be adjusted. That is, it is possible to make it more difficult to be selected as a route than the default by making the passage cost of the road section larger than the default. In addition, by making the passage cost of the road section smaller than the default, it is possible to make it easier to be selected as a route than when searching with the default passage cost.

In this embodiment, the passing cost is adjusted based on the recommended vehicle speed obtained based on the weight of the vehicle and the curvature of the curve. That is, even if the curves have the same curvature, when the weight of the vehicle is large, the difficulty of handling the vehicle is higher than when the curve is small. For example, when the weight of the vehicle is large, the braking distance becomes larger than when the weight of the vehicle is small, and it becomes difficult to stop the vehicle in response to a change in the situation or the like. In addition, when the weight of the vehicle is heavy, it becomes harder to turn than when it is small, and the skill of the driver is required. Further, a vehicle loaded with luggage has a risk of collapse as compared with a vehicle not loaded, and it is necessary to drive the vehicle so as not to cause the collapse.

As described above, the heavier the weight of the vehicle, the higher the difficulty of handling the vehicle, but in the present embodiment, it is considered that the difficulty can be evaluated by the centrifugal force. That is, in the present embodiment, it is considered that the vehicle is easy to handle when the centrifugal force acting on the vehicle on the curve is equal to or less than a predetermined value.

Centrifugal force is generally expressed as M × V ² × φ by the mass M of the vehicle, the vehicle speed V, and the curvature φ. Therefore, in order for the centrifugal force to be the default value C or less, the vehicle speed V ₀ may be (C / (φ × M)) ^1/2 or less. Therefore, in the present embodiment, the recommended vehicle speed is a vehicle speed (for example, a vehicle speed obtained by subtracting a constant value or multiplying by a coefficient smaller than 1) with a margin provided at the vehicle speed V ₀ that sets the centrifugal force to the default value C or less. Let it be Vr.

The transit cost is a cost proportional to the length of the travel time, and the travel time can be specified by (distance of the road section) / (average vehicle speed). Therefore, if the average vehicle speed Vl of the road section (limited vehicle speed in the present embodiment) used when calculating the default cost and the recommended vehicle speed Vr in the road section are different, the passing cost will be different. Therefore, in the present embodiment, the cost coefficient is defined by the ratio (Vl / Vr) of the average vehicle speed Vl of the road section used when calculating the default cost and the recommended vehicle speed Vr in the road section. The default cost is adjusted according to the cost coefficient. In the present embodiment, the cost coefficient is acquired when the route is searched, but of course, the recommended vehicle speed for each road section is acquired in advance based on the weights of various vehicles, and is included in the cost information 300d. You may.

In the present embodiment, the route search program 210 includes a destination acquisition unit 210a and a route search unit 210b. The destination acquisition unit 210a is a program module that causes the control unit 200 to execute a function of acquiring the destination of the vehicle. That is, the control unit 200 refers to the travel plan information 300a and acquires the destination of the vehicle to be searched for the route based on the vehicle identification information.

The route search unit 210b is a program module that causes the control unit 200 to execute a function of searching for a route to reach a destination based on a passing cost according to the vehicle speed of a vehicle in a road section. That is, the control unit 200 searches for a route for each vehicle to reach the destination based on the map information 300c. The departure point of the vehicle is known. For example, the base of the transportation company may be the departure point, but of course, if the departure point is different for each vehicle, the route from the departure point to the destination is searched for each vehicle. Alternatively, the current location of each vehicle may be the starting point.

The route search is performed based on the cost information 300d. That is, the control unit 200 acquires the passage cost for the road section to be determined for determining whether or not to select the road section connected to the node with the departure point of each vehicle as the starting node. The passing cost is a default value indicated by the cost information 300d or a value obtained by multiplying the default value by a cost coefficient. The passing cost of the road section to be determined may be calculated in advance, or the passing cost may be calculated when it is determined whether or not the route should be selected.

When calculating the passing cost for the road section for which the passing cost is calculated, the control unit 200 determines the passing cost according to the recommended vehicle speed acquired based on the weight of the vehicle and the curvature of the curve. That is, the control unit 200 refers to the vehicle information 300b and acquires the weight of the vehicle to be searched for the route. Further, the control unit 200 refers to the map information 300c and determines whether or not the road section for which the passage cost is calculated is a curve section (whether or not the curvature is a certain value or more).

When the road section for which the passage cost is calculated is a curved section, the control unit 200 acquires the curvature of the curve of the road section based on the map information 300c. Further, the control unit 200 acquires a vehicle speed V ₀ so that the centrifugal force acting on the curve section having a curvature φ with respect to the vehicle having a weight M becomes the default value C or less. Then, the control unit 200 sets the vehicle speed in which a margin is provided at the vehicle speed V ₀ as the recommended vehicle speed Vr.

When the recommended vehicle speed Vr is acquired, the control unit 200 refers to the map information 300c, acquires the limited vehicle speed Vl of the road section for which the passing cost is calculated, and acquires Vl / Vr as a cost coefficient. Then, the control unit 200 considers the value obtained by multiplying the default passing cost of the road section for which the passing cost is calculated by the cost coefficient as the passing cost of the road section.

When it is not determined that the road section for which the passage cost is calculated is a curve section, the control unit 200 acquires the default passage cost based on the cost information 300d and considers it as the passage cost of the road section.

When the transit cost is obtained, the control unit 200 searches for a route from the starting point to the destination by a known method, for example, Dijkstra's algorithm, based on the passing cost. When the route is searched, the control unit 200 transmits the route of each vehicle to the route guidance system 10 used by each vehicle by the function of the route search unit 210b. That is, the control unit 200 communicates with each of the plurality of vehicles via the communication unit 400, and identifies the transmission destination of the route of each vehicle based on the identification information of each vehicle. Then, the control unit 200 transmits the route of each vehicle to the route guidance system 10 of each vehicle.

When the route of each vehicle is transmitted to the route guidance system 10 of each vehicle as described above, the route of each vehicle is guided by each route guidance system 10. In the present embodiment, the route search system 100 determines the passage cost in the curve section by multiplying the default cost by the cost coefficient Vl / Vr. Then, the recommended vehicle speed Vr is determined so that the centrifugal force becomes the default value C or less based on the recommended vehicle speed acquired based on the weight of the vehicle and the curvature of the curve.

In order for the centrifugal force to be below the default value C, the vehicle speed V ₀ should be (C / (φ × M)) ^1/2 or less, so it is recommended when the weight of the vehicle is heavy, rather than when it is small. The vehicle speed Vr becomes smaller. Therefore, when the vehicle is large, the recommended vehicle speed Vr is smaller and the cost coefficient Vl / Vr is larger than when the vehicle is small. As a result, when the vehicle is large, the recommended vehicle speed Vr is smaller than when it is small, and the adjusted passing cost is increased.

In the present embodiment, since the route is searched based on the transit cost calculated in this way, it is possible to execute the route search reflecting the change in the travel time according to the weight of the vehicle. Further, in a situation where the difficulty becomes higher due to the increase in the weight of the vehicle and as a result, the vehicle is forced to travel at a small vehicle speed, the route can be searched in a state where the decrease in the vehicle speed is reflected. Therefore, even if the vehicle speed decreases according to the weight of the vehicle, the route is searched in consideration of the decrease. Therefore, it is possible to avoid road sections where travel time can be reduced. Further, when the estimated arrival time is acquired based on the route, the prediction accuracy can be improved.

(1-3) Operation manager terminal configuration:
The operation manager terminal 50 is a terminal for the operation manager to input a travel plan for each vehicle. The operation manager terminal 50 includes a control unit 52 including a CPU, RAM, ROM, and the like, a recording medium (not shown), a user I / F unit 54, and a communication unit 55. The control unit 52 can execute a program (not shown) stored in a recording medium (not shown) or a ROM (not shown).

The user I / F unit 54 includes an input unit that accepts the input of the operation manager and an output unit that displays information, and can display arbitrary information on the output unit. Of course, the output mode of the output unit is not limited to the display, and may be an audio output or the like. The communication unit 55 includes a circuit for communicating with another device, and the control unit 52 can communicate with the path search system 100 via the communication unit 55.

The control unit 52 can display an interface screen for inputting a travel plan of each vehicle on the output unit of the user I / F unit 54 by a function of a program (not shown). The operation manager can input the luggage, the destination, etc. to be loaded on each vehicle while visually recognizing the vehicle identification information on the interface screen.

That is, the control unit 52 receives the load to be loaded on each vehicle based on the operation of the operation manager using the input unit of the user I / F unit 54. Further, the control unit 52 accepts the destination and the like based on the operation of the operation manager using the input unit of the user I / F unit 54. Then, the control unit 52 associates the luggage loaded on each vehicle with the destination with respect to the identification information of each vehicle, and transmits the identification information to the route search system 100 via the communication unit 55. In the above configuration, if the operation manager specifies a destination, a route that reflects the change in travel time according to the weight of the vehicle is searched and guided. In the present embodiment, information indicating the cargo is transmitted, but if the weight of the vehicle is specified in consideration of the actual weight of the cargo, the information on the weight of the cargo is transmitted and the route search system is used. It may be used at 100.

(2) Route search processing:
Next, the route search process executed by the control unit 200 will be described. The operation manager creates travel plan information 300a indicating a travel plan for each vehicle in advance using the operation manager terminal 50, and transmits the travel plan information 300a to the route search system 100. The route search system 100 acquires the travel plan information 300a via the communication unit 400 and records it on the recording medium 300. In a vehicle in which the route guidance system 10 is used, information indicating the weight of the vehicle is specified in advance, and vehicle information 300b is generated in association with the vehicle identification information. The vehicle information 300b is transmitted from the vehicle to the route search system 100, and the route search system 100 acquires the vehicle information 300b via the communication unit 400 and records it on the recording medium 300.

As described above, the route search system 100 is in a state where the travel plan information 300a and the vehicle information 300b are recorded on the recording medium 300, and the map information 300c and the cost information 300d are pre-defined and recorded on the recording medium 300. Executes the route search process. The route search process can be executed for each of the vehicles managed by the operation manager. Here, the route search process will be described with one vehicle as the target vehicle for the route search, but when the route is searched for each of the plurality of vehicles, the travel plan information 300a of each vehicle is based on the vehicle identification information. And the vehicle information 300b is referred to, and the route search process is executed for each vehicle.

When the route search process is started, the control unit 200 acquires the travel plan (step S100). That is, the control unit 200 acquires the travel plan information 300a associated with the identification information of the vehicle to be searched for the route from the recording medium 300 and records it in a RAM or the like (not shown).

Next, the control unit 200 acquires the destination by the function of the destination acquisition unit 210a (step S105). That is, the control unit 200 refers to the travel plan information 300a acquired in step S100, acquires the destination of the vehicle, and records it in the RAM or the like.

After that, the control unit 200 determines the passage cost for each road section in order to search the route from the departure point to the destination of the vehicle by the function of the route search unit 210b. The transit cost may be determined at least at the stage of determining whether or not the road section is selected. Therefore, the passage cost of the road section for which the passage cost needs to be referred to may be sequentially determined in the process of route search, or the passage cost of a plurality of road sections for which the passage cost can be referred to may be predetermined. ..

Here, a configuration in which the passage costs of a plurality of road sections are predetermined will be described. Therefore, in this case, the control unit 200 identifies a plurality of road sections that exist between the starting point and the destination and can serve as a route. In this example, these plurality of road sections are subject to transit cost calculation. The target for calculating the transit cost may be a road section that can be a route, for example, from a road section within a predetermined distance from the departure point, a road section within a predetermined distance from the destination, and a straight line extending from the departure point to the destination. Examples include a configuration in which a road section within a predetermined distance is considered to be a transit cost calculation target. Of course, if it becomes possible to select a road section whose transit cost is undecided in the process of route search, the route search will be continued after the transit cost is determined for that road section.

Next, the control unit 200 acquires the weight of the vehicle by the function of the route search unit 210b (step S110). That is, the control unit 200 acquires the weight M of the vehicle to be searched for the route based on the vehicle information 300b. For example, in the case where the vehicle information 300b is an example as shown in Table 1, when the vehicle identification information ID 1 is used, the control unit 200 acquires the weight M as 15000 kg.

Next, the control unit 200 acquires the curvature of the road section for which the passage cost is calculated by the function of the route search unit 210b (step S115). That is, the control unit 200 refers to the map information 300c and acquires the curvature φ of the road section for which the passage cost is calculated. For example, in the example shown in Table 2, when the road section for which the passage cost is calculated is L ₁ , the control unit 200 acquires the curvature φ as φ ₁ .

Next, the control unit 200 acquires the recommended vehicle speed based on the weight and curvature of the vehicle by the function of the route search unit 210b (step S120). That is, the control unit 200 determines whether or not the road section for which the passage cost is calculated is a curve section based on the curvature φ of the road section for which the passage cost is calculated. When the road section for which the passage cost is calculated is a curve section, the control unit 200 sets the vehicle speed V ₀ such that the centrifugal force acting on the vehicle on the curve is equal to or less than the default value C V ₀ = (C / (φ × M). )) Calculate as ^1/2 . Then, the vehicle speed set to a smaller value by providing a margin at the vehicle speed V ₀ is defined as the recommended vehicle speed Vr. For example, in the example shown in Table 2, when the road section for which the passing cost is calculated is L ₁ , the recommended vehicle speed Vr is calculated to be 40 km / h or the like. When the road section for which the passing cost is calculated is not a curved section, the control unit 200 skips steps S120 and S125 and considers the cost coefficient of the road section for which the passing cost is calculated to be 1 (substantially cost adjustment is performed). do not have).

Next, the control unit 200 acquires a cost coefficient based on the recommended vehicle speed by the function of the route search unit 210b (step S125). That is, the control unit 200 acquires the limited vehicle speed Vl of the road section for which the passing cost is calculated by referring to the map information 300c, and acquires the ratio (Vl / Vr) of the limited vehicle speed Vl and the recommended vehicle speed Vr as a cost coefficient. .. For example, in the example shown in Table 2, when the road section for which the passing cost is calculated is L ₁ and the recommended vehicle speed Vr is 40 km / h, the cost coefficient is 50/40.

Next, the control unit 200 adjusts the cost based on the cost coefficient by the function of the route search unit 210b (step S130). That is, the control unit 200 refers to the map information 300c and acquires the default cost in the road section for which the passage cost is calculated. Then, the control unit 200 acquires the cost by multiplying the default cost by the cost coefficient.

When the cost coefficient of the road section that is a candidate for the route is obtained in the route search as described above, the control unit 200 searches for the route by the function of the route search unit 210b (step S140). That is, the control unit 200 searches for a route from the starting point to the destination by an algorithm such as Dijkstra's algorithm based on the passing cost determined in step S130.

3A and 3B are diagrams showing an example of a route search according to the present embodiment. In these figures, the nodes are shown by white circles, the links are shown by solid lines, and the transit costs are shown superimposed on the links. The starting node is S, and the destination node is G. Further, FIG. 3A shows the passing cost in a light vehicle, and FIG. 3 shows the passing cost in a heavy vehicle.

Further, in this example, it is assumed that the road section L ₃ includes a curved section and the other sections are straight lines. The vehicle illustrated in FIG. 3B is heavier and has a lower recommended vehicle speed than the vehicle illustrated in FIG. 3A, resulting in a higher cost factor. In the example shown in FIG. 3B, reflecting this situation, the passing cost of the road section L ₃ is 5/4 times that of the example shown in FIG. 3A.

Then, when the route is searched based on the passing cost shown in FIG. 3A, the route traveling along with the road sections L ₁ , L ₂ , and L ₃ is searched by minimizing the sum of the passing costs. On the other hand, when the route is searched based on the passage cost shown in FIG. 3B, the route traveling along with the road sections L ₄ and L ₅ is searched. In this embodiment, it is possible to execute a route search that reflects a change in travel time according to the weight of the vehicle in this way.

(3) Other embodiments:
The above embodiment is an example for carrying out the present invention, and various other embodiments are provided as long as the passing cost is determined according to the recommended vehicle speed obtained based on the weight of the vehicle and the curvature of the curve. The form can be adopted. For example, the recommended vehicle speed obtained based on the weight of the vehicle and the curvature of the curve is not limited to the configuration calculated based on the above calculation formula (C / (φ × M)) ^1/2 , and the weight of the vehicle is not limited. A map in which the recommended vehicle speed is associated with the combination of the curve and the curvature of the curve may be defined in advance and acquired based on the map.

Each system constituting the above-described embodiment may be composed of a smaller number of devices having a shared function. Examples of such an example include an example in which at least one system shown in FIG. 1 is composed of the same device as one or more other systems. For example, the route guidance system 10 and the operation manager terminal 50 may be configured by an integrated device, the route search system 100 and the operation manager terminal 50 may be configured by an integrated device, or a route search. The system 100 and the route guidance system 10 may be configured as an integrated device.

Of course, the route guidance system 10 may be provided in the vehicle, or may be a portable terminal or the like. Further, the system shown in FIG. 1 may be composed of a larger number of systems. For example, the route search system 100 may be configured by a cloud server. Further, the route search system 100 may be accessed from the operation manager terminal 50, and the travel plan information 300a may be created under the control of the route search system 100.

Further, at least a part of each unit (destination acquisition unit 210a, route search unit 210b) constituting the route search system 100 may be divided into a plurality of devices and exist. For example, the route search unit 210b may have a configuration in which the function of acquiring the passage cost is realized by the route search system 100, and the function of searching the route is realized by the route guidance system 10.

Further, it is possible to assume a configuration in which a part of the configuration of the above-described embodiment is omitted, or a configuration in which the processing is varied or omitted. For example, the cost may be calculated based on the weight of the vehicle and the curvature of the curve for all road sections, instead of adjusting the cost based on the cost coefficient.

Furthermore, the change in travel time according to the weight of the vehicle may occur outside the curve section. For example, when it is necessary to reduce the vehicle speed or stop the vehicle in front of a curve section, before a stop line, before an intersection, etc., the braking distance changes according to the weight of the vehicle. Therefore, the passing cost may be determined so that the passing cost increases as the braking distance increases, considering the braking distance that increases as the weight of the vehicle increases. Further, since the braking distance also depends on the braking performance, the passing cost may be adjusted according to the braking performance of the vehicle.

The destination acquisition unit only needs to be able to acquire the destination. That is, it suffices if the arrival point of the vehicle can be acquired as the destination. The destination may be a plurality of points including a transit destination and a final destination, and may include a point where cargo is not loaded and unloaded. The latter includes the base when the cargo is unloaded and then returned to the base of the vehicle with no cargo loaded.

It suffices if the route search unit can search for a route to reach the destination based on the passing cost according to the vehicle speed of the vehicle in the road section. That is, whether or not each road section constituting the road network should be selected as a route is expressed by the passage cost, and the route search unit is based on the passage cost (for example, the sum of the passage costs is minimized). It is possible to search for a route.

The passage cost may be a value that defines whether or not the road section is easily selected as a route. For example, it is possible to adopt a configuration in which the larger the passage cost, the more difficult it is to be selected as a route. In addition, the passing cost is set to a value according to the vehicle speed. That is, the degree to which each road section is recommended as a route is evaluated by the vehicle speed. Therefore, the higher the vehicle speed (average vehicle speed, etc.) that can be realized in the road section, the smaller the passing cost may be. May be smaller, and various definitions are possible.

Of course, as in the above embodiment, the transit cost may be determined based on the distance of the road section (distance between nodes). That is, it can be said that the passing cost is determined based on the vehicle speed even if the travel time calculated based on the vehicle speed and the distance of the road section is shorter and the passing cost is smaller.

In any case, in the route search unit, at least in the case of a road section including a curve, when determining the passing cost according to the vehicle speed, the recommended vehicle speed obtained based on the weight of the vehicle and the curvature of the curve is used. The transit cost will be adjusted accordingly. That is, in a curve, the heavier the vehicle, the more it is necessary to decelerate the vehicle speed, but if the recommended vehicle speed of the curve is calculated from the weight of the vehicle and the curvature of the curve, an index indicating the degree of deceleration on the curve according to the weight of the vehicle can be used. Can be obtained. Therefore, when determining the passing cost based on the vehicle speed, if the passing cost on the curve is acquired by the recommended vehicle speed, the passing cost reflecting the degree of deceleration on the curve according to the weight of the vehicle can be determined. The route search unit may search for a route based on the passing cost according to the vehicle speed, but of course, other factors such as a road type may be taken into consideration in the route search.

The weight of the vehicle may be obtained so that the deceleration of the vehicle on the curve can be evaluated, and is the total weight including the luggage. Therefore, the maximum value of the weight of the vehicle may be evaluated based on the maximum load capacity in the vehicle as in the above-described embodiment, or the weight of the vehicle is evaluated according to the weight of the load loaded on the vehicle. Is also good. For example, the weight of the vehicle may be measured when the vehicle is loaded with luggage, or the known vehicle body weight (weight when the luggage is not loaded) and the weight of the loaded luggage (measured value). The weight of the vehicle may be the sum of the weight of the vehicle and the weight of the vehicle.

The curvature of the curve may be specified in various ways, may be recorded in the map information in advance as in the above-described embodiment, or may be calculated based on the positions of the nodes and shape interpolation points. , It may be specified based on the traveling history information (probe information) of the vehicle. The recommended vehicle speed is a vehicle speed recommended when the vehicle travels on a curve, and may be specified by various methods as long as it is obtained based on the weight of the vehicle and the curvature of the curve. Therefore, various configurations can be adopted in addition to the configuration in which the recommended vehicle speed is calculated by providing a predetermined margin from the vehicle speed such that the centrifugal force acting on the vehicle on the curve is within the allowable range as described above. For example, the vehicle speed itself may be such that the centrifugal force is within an allowable range.

Of course, when there are a plurality of curves having different curvatures in a single road section (section existing between nodes), the curvature may be acquired for each of them, or the maximum curvature may be acquired. ..

When the recommended vehicle speed is low, the passing cost may be set to be higher than when the recommended vehicle speed is high, but more specifically, it is preferable that the passing cost changes according to the change in the recommended vehicle speed. That is, when the vehicle speed on the road section is specified, the travel time required to pass through the road section can be specified based on the distance of the road section and the like. Therefore, if the transit cost is configured to change according to the length of the travel time of the road section specified from the vehicle speed, the transit cost can be defined according to the vehicle speed, and the road section that requires a short passage time can be defined. Can be searched so that is preferentially selected.

In addition, transit costs may be adjusted by factors other than vehicle weight and curve curvature. Such elements may include the distance of the road section, the average travel time on the road section, and the like, but of course, elements other than these may be included. For example, when the driving skill of the driver of the vehicle is low, a configuration may be adopted in which the passing cost in the road section including the curve is larger than that when the driving skill is high.

Specifically, in the above-described embodiment, the control unit 200 acquires the driving technique of the driver of the vehicle by the function of the route search unit 210b. The driving technique may be acquired by various methods, for example, it may be specified by the user, or it may be acquired based on the driving history of the vehicle. As the latter, for example, the number of times an operation for determining a driving technique (for example, overspeed, sudden braking, sudden acceleration, sudden steering, etc.) is performed in a vehicle is measured, and based on the frequency and probability of occurrence. There is a configuration in which driving skills are acquired.

Then, the control unit 200 is configured to set the cost coefficient to be larger than 1 when the driving skill of the driver of the vehicle is low, and to increase the magnitude of the cost coefficient according to the driving skill. According to this configuration, when the driving skill is low, the cost in the road section including the curve is higher than when the driving skill is high. Therefore, when the driving technique is low and the weight of the vehicle is heavy, it is possible to search for a route in consideration of the characteristics of the driver such that the vehicle speed is greatly reduced in the curve.

Further, the search for a route considering the recommended vehicle speed corresponding to the weight of the vehicle and the curvature of the curve may be performed in a part of the route of the vehicle. For example, when it is assumed that the vehicle travels from the departure point to the luggage transportation completion point with the luggage loaded and then returns to the departure point after unloading the luggage, the route search unit is determined according to the recommended vehicle speed. You may search for a route to reach the destination, which is the transportation completion point, at the transit cost. In this case, when the route from the transportation completion point to the destination beyond the transportation completion point is searched, the route search unit considers that the average vehicle speed (statistically average vehicle speed such as the limited vehicle speed) is used instead of the recommended vehicle speed. The search is performed at a transit cost determined according to the vehicle speed to be considered).

That is, when a heavy vehicle is loaded with luggage, the route is searched for at a passing cost that reflects the situation where the heavy vehicle slows down on a curve, and the route without luggage is loaded. May adopt a configuration in which the search is performed at the default transit cost. According to this configuration, heavy vehicles follow a route that reflects slower vehicle speeds on curves while loaded, and other factors are prioritized while not loaded (" You can search along the route (for example, short distance or short travel time). Of course, it may be possible for the user to specify whether or not to execute the route search based on the passing cost determined based on the recommended vehicle speed after unloading the luggage by various user interfaces.

Further, various modes can be adopted as the guidance mode in the route guidance system 10. For example, when the control unit 20 uses the function of the route guidance unit 21b to include a road section in which the passage cost determined according to the recommended vehicle speed is associated with the route, the road section is before reaching the road section. It may be configured to provide guidance regarding. That is, according to the present embodiment, the route is searched so as to avoid the road where the vehicle speed decreases due to the heavy weight of the vehicle as much as possible. However, the route may include a road in which the vehicle speed decreases due to the heavy weight of the vehicle due to reasons such as the fact that there are few road options on the actual road.

Therefore, in such a case, a warning may be given to the driver. FIG. 4 is a diagram showing an example of a warning displayed in the output unit of the user I / F unit (not shown) included in the route guidance system 10. That is, in this example, a map around the current location Ca of the vehicle is displayed, and the route is indicated by a thick solid line. In this situation, it is warned that there is a curve to be careful of in a heavy vehicle 500 m ahead on the route. According to this configuration, the driver can know in advance that he / she will take a curve to be careful of in a heavy vehicle, and increase the possibility of driving more safely by paying attention to driving on the curve. Can be done.

Of course, such a guidance mode is an example, and may be configured to provide guidance regarding a recommended vehicle speed in the curve section. The guidance regarding the recommended vehicle speed may be the recommended vehicle speed itself, an image showing the magnitude of the recommended vehicle speed, or voice guidance, and various configurations can be adopted.

Further, a method such as the present invention in which the passing cost is determined according to the recommended vehicle speed acquired based on the weight of the vehicle and the curvature of the curve can also be applied as a program or a method. In addition, the above systems, programs, and methods may be realized as a single device or may be realized by using parts shared with each part provided in the vehicle, including various aspects. It is a program. For example, it is possible to provide a method and a program realized by the above system. In addition, some of them are software and some of them are hardware, which can be changed as appropriate. Further, the invention is also established as a recording medium for a program that controls an apparatus. Of course, the recording medium of the software may be a magnetic recording medium or a semiconductor memory, and any recording medium to be developed in the future can be considered in exactly the same way.

10 ... Route guidance system, 15 ... Communication unit, 16 ... GNSS receiver unit, 17 ... Vehicle speed sensor, 18 ... Gyro sensor, 20 ... Control unit, 21 ... Route guidance program, 21a ... Route acquisition unit, 21b ... Route guidance unit, 50 ... Operation manager terminal, 52 ... Control unit, 54 ... User I / F unit, 55 ... Communication unit, 100 ... Route search system, 200 ... Control unit, 210 ... Route search program, 210a ... Destination acquisition unit, 210b ... Route search unit, 300 ... Recording medium, 300a ... Travel plan information, 300b ... Vehicle information, 300c ... Map information, 300d ... Cost information, 400 ... Communication unit

Claims (10)

The destination acquisition department that acquires the destination of the vehicle ,
The travel time required to pass the road section including the curve is determined according to the recommended vehicle speed obtained based on the weight of the vehicle and the curvature of the curve, and according to the travel time, With a route search unit that determines the passage cost in the road section and searches for a route to reach the destination based on the passage cost.
A pathfinding system equipped with . The route search unit
Based on the weight of the vehicle and the curvature of the curve included in the road section, the recommended speed for the road section including the curve is set so that the centrifugal force acting on the vehicle becomes equal to or less than a specified value. The route search system according to claim 1, which is acquired as. When the recommended vehicle speed is small, the passing cost is larger than when the recommended vehicle speed is large.
The route search system according to claim 2 . The route search unit
When the driving skill of the driver of the vehicle is low, the passing cost in the road section including the curve is increased as compared with the case where the driving skill is high.
The route search system according to any one of claims 1 to 3 . The route to reach the destination, which is the transportation completion point of the luggage carried by the vehicle, is searched for at the transit cost determined according to the recommended speed.
The route to the destination beyond the transportation completion point is searched for at the transit cost determined according to the average vehicle speed.
The route search system according to any one of claims 1 to 4 . A route acquisition unit that acquires a route for reaching the destination of the vehicle, which is searched based on the passing cost according to the vehicle speed in the road section, and
A route guide unit that guides the route and
With
The transit cost of the road section including the curve is determined according to the travel time required to pass the road section including the curve.
The travel time is determined according to the recommended speed obtained based on the weight of the vehicle and the curvature of the curve.
Route guidance system. The route guidance unit
When the route includes the road section to which the passing cost determined according to the recommended speed is associated, the guidance regarding the road section is provided before reaching the road section.
The route guidance system according to claim 6 . The route guidance unit
Guidance on the recommended vehicle speed,
The route guidance system according to claim 7 . Computer,
Destination acquisition department to acquire the destination of the vehicle and
The travel time required to pass the road section including the curve is determined according to the recommended vehicle speed obtained based on the weight of the vehicle and the curvature of the curve, and according to the travel time, A route search unit that determines the passage cost in the road section and searches for a route to reach the destination based on the passage cost.
A pathfinding program to function as . Computer,
A route acquisition unit that acquires a route for reaching the destination of the vehicle, which is searched based on the passing cost according to the vehicle speed in the road section.
Route guidance unit that guides the route,
To function as
The transit cost of the road section including the curve is determined according to the travel time required to pass the road section including the curve.
The travel time is determined according to the recommended speed obtained based on the weight of the vehicle and the curvature of the curve.
Route guidance program.

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