JP2020034376A - Autonomous travel control device, autonomous travel control method, program and storage medium - Google Patents

Abstract

To automatically determine a travel plan of an automatic driving vehicle after a user gets off, on the basis of next schedule.SOLUTION: An autonomous travel control device is mounted on a vehicle capable of autonomous traveling and controls the autonomous traveling of the vehicle. The autonomous travel control device acquires a position of always parking place in which the vehicle is always parked and a schedule indicating a destination at which the vehicle arrives and a scheduled time to arrive at the destination. Also, the autonomous travel control device acquires a start instruction from a user of the vehicle. Then, the autonomous travel control device acquires a travel plan for returning to the always parking place when the schedule to be executed within a predetermined period by schedule acquisition means and controls the autonomous traveling of the vehicle after start instruction acquisition means acquires the start instruction according to the acquired travel plan.SELECTED DRAWING: Figure 6

Description

  The present invention relates to control of self-driving vehicles.

  Patent Document 1 describes a method of setting the behavior of an automatic driving vehicle after a user gets off the vehicle. Specifically, in Patent Literature 1, as a behavior after the self-driving vehicle gets off, the user moves to a preset parking lot, waits for calling at a nearby parking lot, and gets off after a predetermined time. Returning to, or waiting at a designated point after a predetermined time can be set.

Japanese Patent No. 6320496

  However, in the above method, every time the user gets off the self-driving vehicle, it is necessary to set the subsequent behavior, which is complicated.

  The present invention has been made in order to solve the above-described problems, and has been made based on the following schedule to enable a user to automatically determine a travel plan of an automatic driving vehicle after getting off the vehicle. Aim.

  The invention according to claim 1 is an autonomous traveling control device mounted on a vehicle capable of autonomous traveling and controlling the autonomous traveling of the vehicle, wherein the vehicle acquires a position of a regular parking place where the vehicle can always park. Parking place position obtaining means, schedule obtaining means for obtaining a schedule indicating a destination at which the vehicle should arrive, and a scheduled time at which the vehicle should arrive at the destination, and a departure instruction for obtaining a departure instruction from a user of the vehicle Acquiring means, a traveling plan acquiring means for acquiring a traveling plan for returning to the regular parking place when a schedule to be executed within a predetermined period is not acquired by the schedule acquiring means, and acquiring the traveling plan by the traveling plan acquiring means. Control means for controlling the autonomous traveling of the vehicle after the departure instruction acquisition means acquires the departure instruction according to the traveling plan. To.

  The invention according to claim 6 is an autonomous traveling control method which is mounted on a vehicle capable of autonomous traveling and is executed by an autonomous traveling control device that controls the autonomous traveling of the vehicle. A regular parking place position acquiring step of acquiring a position of a parking place, a schedule acquiring step of acquiring a schedule indicating a destination at which the vehicle should arrive and a scheduled time at which the vehicle should arrive at the destination, from a user of the vehicle. A departure instruction acquisition step of acquiring a departure instruction, and a travel plan acquisition step of acquiring a travel plan for returning to the regular parking place when a schedule to be executed within a predetermined period has not been acquired by the schedule acquisition step, According to the travel plan acquired in the travel plan acquisition step, the departure instruction acquisition step controls the autonomous traveling of the vehicle after acquiring the departure instruction. Characterized in that it comprises a control step.

  The invention according to claim 7 is a program that is mounted on a vehicle capable of autonomous traveling, includes a computer, and is executed by an autonomous traveling control device that controls the autonomous traveling of the vehicle, wherein the vehicle can always park. Regular parking place position acquiring means for acquiring a position of a regular parking place, schedule acquiring means for acquiring a schedule indicating a destination at which the vehicle should arrive and a scheduled time at which the vehicle should arrive at the destination, from a user of the vehicle. Departure instruction acquisition means for acquiring a departure instruction, travel plan acquisition means for acquiring a travel plan for returning to the regular parking place when a schedule to be executed within a predetermined period is not acquired by the schedule acquisition means, According to the travel plan acquired by the acquisition means, the autonomous traveling of the vehicle after the departure instruction acquisition means acquires the departure instruction Gosuru control means, characterized by causing the computer to function as a.

1 shows a schematic configuration of an automatic driving vehicle control system according to an embodiment. FIG. 3 is a block diagram illustrating a functional configuration of a terminal device. FIG. 2 is a block diagram illustrating a functional configuration of a server device. 1 shows an example of a parking lot database. 1 shows an example of a user database. It is a flowchart of a travel plan generation process. It is a flowchart of a cost calculation process. The example of a travel plan is shown. It is an example of a cost calculation result about a plurality of travel plans.

  One preferred embodiment of the present invention is an autonomous traveling control device mounted on a vehicle capable of autonomous traveling and controlling the autonomous traveling of the vehicle, and acquires a position of a regular parking place where the vehicle can always park. Regular parking place position acquiring means, a schedule acquiring means for acquiring a schedule indicating a destination to which the vehicle should arrive and a scheduled time to arrive at the destination, and a departure instruction from a user of the vehicle. A departure instruction acquiring means, a traveling plan acquiring means for acquiring a traveling plan for returning to the regular parking place when a schedule to be executed within a predetermined period is not acquired by the schedule acquiring means, and Control means for controlling the autonomous traveling of the vehicle after the departure instruction acquisition means acquires the departure instruction in accordance with the acquired travel plan.

  The above-mentioned autonomous traveling control device is mounted on a vehicle capable of autonomous traveling and controls the autonomous traveling of the vehicle. The autonomous traveling control device acquires a position of a regular parking place where the vehicle can always park, a destination where the vehicle should arrive, and a schedule indicating a scheduled time of arrival at the destination. In addition, the autonomous traveling control device acquires a departure instruction from a user of the vehicle. The autonomous traveling control device acquires a traveling plan for returning to the regular parking place when the schedule to be executed within the predetermined period is not acquired by the schedule acquiring means, and issues a departure instruction according to the acquired traveling plan. The autonomous traveling of the vehicle after the acquisition means acquires the departure instruction is controlled. Thus, if there is no schedule within the predetermined period, the vehicle is controlled to return to the regular parking place.

  In one aspect of the autonomous traveling control device, the traveling plan acquisition unit arrives at the destination by the scheduled time when the schedule acquisition unit acquires a schedule to be executed within a predetermined period. A first travel plan that parks at the service parking location before arriving at the destination, and a parking plan that is different from the service parking location before arriving at the destination; A plurality of travel plans including a second travel plan, and the control unit acquires the departure instruction acquisition unit according to one travel plan selected from the plurality of travel plans based on a predetermined criterion. Controls the autonomous traveling of the vehicle after acquiring the departure instruction. In this aspect, when there is a schedule within the predetermined period, a plurality of travel plans to the destination are acquired, and the vehicle is controlled according to one travel plan selected from the travel plans.

  In another aspect of the above-mentioned autonomous traveling control device, the regular parking place position acquiring means acquires the positions of a plurality of regular parking places, and the travel plan acquiring means executes within a predetermined period by the schedule acquiring means. When the schedule to be acquired has not been acquired, a travel plan for returning to the regular parking place closest to the position where the departure instruction has been acquired among the plurality of regular parking places is acquired. In this aspect, the vehicle is controlled so as to return to the closer one of the plurality of regular parking places.

  In another aspect of the above-described autonomous traveling control device, the traveling plan acquisition unit may be configured to return to the destination by the scheduled time when the schedule to be executed within a predetermined period is acquired by the schedule acquisition unit. A travel plan for arriving, wherein the travel plan is to be parked at a service parking location where the travel distance to the destination is the shortest among the plurality of service parking locations. In this aspect, when there is a schedule within a predetermined period, a traveling route using a regular parking place where the traveling distance to the destination is the shortest is acquired.

  Another aspect of the above-mentioned autonomous traveling control device includes a setting unit that allows a user to set the predetermined reference. In this aspect, the user can arbitrarily set the criteria for selecting the travel plan.

  Another preferred embodiment of the present invention is an autonomous traveling control method that is mounted on a vehicle capable of autonomous traveling and is executed by an autonomous traveling control device that controls the autonomous traveling of the vehicle, wherein the vehicle can always be parked. A regular parking place position acquiring step of acquiring a position of a regular parking place, a schedule acquiring step of acquiring a schedule indicating a destination at which the vehicle should arrive and a scheduled time at which the vehicle should arrive at the destination, use of the vehicle A departure instruction acquiring step of acquiring a departure instruction from a driver, and a traveling plan acquiring step of acquiring a traveling plan for returning to the regular parking place when a schedule to be executed within a predetermined period has not been acquired by the schedule acquiring step. And the autonomous traveling of the vehicle after the departure instruction acquiring step acquires the departure instruction according to the traveling plan acquired by the traveling plan acquisition step. Comprising a Gosuru control step. According to this method, if there is no schedule within the predetermined period, the vehicle is controlled to return to the regular parking place.

  Another preferred embodiment of the present invention is a program that is mounted on a vehicle capable of autonomous traveling, includes a computer, and is executed by an autonomous traveling control device that controls autonomous traveling of the vehicle, wherein the vehicle is constantly parked. Regular parking place position acquiring means for acquiring a position of a possible regular parking place, schedule acquiring means for acquiring a schedule indicating a destination to which the vehicle should arrive and a scheduled time to arrive at the destination, a user of the vehicle A departure instruction acquisition unit for acquiring a departure instruction from a travel plan acquisition unit for acquiring a travel plan for returning to the regular parking place when a schedule to be executed within a predetermined period is not acquired by the schedule acquisition unit; The autonomous operation of the vehicle after the departure instruction acquisition means acquires the departure instruction according to the travel plan acquired by the travel plan acquisition means Control means for controlling the rows, as causing the computer to function. By executing this program on a computer, the above-described autonomous traveling control device can be realized. This program can be stored in a storage medium and handled.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
[Autonomous driving system]
(overall structure)
FIG. 1 illustrates a schematic configuration of the automatic driving vehicle control system according to the embodiment. The automatic driving vehicle control system includes a terminal device 1 mounted on a vehicle capable of autonomous traveling (hereinafter, referred to as an “autonomous driving vehicle V”) and a server device 2 that communicates with the terminal device 1 via a network. Prepare.

  The server device 2 communicates with the terminal device 1 of the self-driving vehicle V, and supplies various data necessary for the self-driving vehicle V to perform autonomous traveling. The terminal device 1 acquires the current position of the self-driving vehicle V at predetermined time intervals, and transmits the current position to the server device 2. The terminal device 1 receives map data and feature data around the current position of the automatic driving vehicle V from the server device 2 and controls the autonomous driving of the automatic driving vehicle V.

Further, in the present embodiment, the server device 2 determines a travel plan of the self-driving vehicle V after the user gets off the vehicle according to a predetermined schedule of the user, and transmits the travel plan to the terminal device 1. The terminal device 1 causes the automatic driving vehicle V to travel according to the travel plan received from the server device 2.
(Configuration of terminal device)
FIG. 2 is a block diagram illustrating a functional configuration of the terminal device 1. As illustrated in FIG. 2, the terminal device 1 mainly includes a communication unit 11, a storage unit 12, an input unit 13, a control unit 14, an interface 15, and an output unit 16. Each element in the terminal device 1 is mutually connected via a bus line 98.

  The communication unit 11 transmits the current position of the automatic driving vehicle V to the server device 2 or receives various data necessary for the autonomous driving of the automatic driving vehicle V from the server device 2 based on the control of the control unit 14. I do. In addition, the communication unit 11 may perform a process of transmitting a signal for controlling the vehicle to the vehicle and a process of receiving a signal related to the state of the vehicle from the vehicle.

  The storage unit 12 stores a program executed by the control unit 14 and information necessary for the control unit 14 to execute a predetermined process. In the present embodiment, the storage unit 12 stores a plurality of map DBs 4, a sensor data cache 6, and vehicle attribute information IV.

  The map DB 4 is a database including, for example, road data, facility data, and feature data around the road. The sensor data cache 6 is a cache memory that temporarily stores output data (so-called raw data) of the sensor unit 7. The vehicle attribute information IV indicates information on the attributes of the vehicle on which the terminal device 1 is mounted, such as the type of the vehicle, the vehicle ID, the vehicle size such as the vehicle length, the vehicle width, and the vehicle height, and the fuel type of the vehicle.

  The input unit 13 is a button for a user to operate, a touch panel, a remote controller, a voice input device, and the like. For example, an input for specifying a destination for a route search, an input for specifying on / off of automatic driving, and the like. And the like, and supplies the generated input signal to the control unit 14. Alternatively, the user may communicate with a mobile terminal owned by the user and receive an operation performed by the user via the mobile terminal. The output unit 16 is, for example, a display, a speaker, or the like that performs output under the control of the control unit 14.

  The interface 15 performs an interface operation for supplying output data of the sensor unit 7 to the control unit 14 and the sensor data cache 6. The sensor unit 7 includes a plurality of external sensors for recognizing a surrounding environment of the vehicle such as a rider 31 and a camera 32 and internal sensors such as a GPS receiver 33, a gyro sensor 34, a position sensor 35, and a three-axis sensor 36. Including. The rider 31 discretely measures the distance to an object existing in the outside world, recognizes the surface of the object as a three-dimensional point group, and generates point group data. The camera 32 generates image data captured from the vehicle. The position sensor 35 is provided for detecting the position of each external field sensor, and the three-axis sensor 36 is provided for detecting the attitude of each external field sensor. Note that the sensor unit 7 may include any external and internal sensors other than the external and internal sensors shown in FIG. For example, the sensor unit 7 may include an ultrasonic sensor, an infrared sensor, a microphone, or the like as an external sensor.

  The control unit 14 includes a CPU that executes a predetermined program on one or a plurality of platforms, and controls the entire terminal device 1. Specifically, the control unit 14 measures the current position of the self-driving vehicle V, and transmits the current position to the server device 2 via the communication unit 11. Further, when the user gets off the automatic driving vehicle V and gives a departure instruction, the control unit 14 transmits a signal (hereinafter, referred to as a “departure instruction signal”) to the server device 2. . The departure instruction signal is generated, for example, when the user operates a door button or operates a remote controller after getting off the self-driving vehicle, and is transmitted to the server device 2.

  Further, as described later, the control unit 14 receives a travel plan after the user gets off the automatic driving vehicle V from the server device 2 and autonomously drives the automatic driving vehicle V (not shown) via the communication unit 11 or the like. Supply to the travel control unit. The autonomous traveling control unit executes the autonomous traveling of the self-driving vehicle V according to the traveling plan.

(Server device)
FIG. 3 is a block diagram illustrating a functional configuration of the server device 2. As shown in FIG. 3, the server device 2 mainly includes a communication unit 21, a storage unit 22, and a control unit 23. Each element in the server device 2 is mutually connected via a bus line 99.

  The communication unit 21 receives the current position and the departure instruction signal of the self-driving vehicle V transmitted from the terminal device 1 and transmits the travel plan determined by the server device 2 to the terminal device 2 based on the control of the control unit 23. Or

  The storage unit 22 stores a program executed by the control unit 23 and information necessary for the control unit 23 to execute a predetermined process. Further, in the present embodiment, the storage unit 22 stores a map database (hereinafter, “database” is referred to as “DB”) 24, a toll DB 25, a parking lot DB 26, and a user DB 27.

  The map DB 24 stores map data to be distributed to the terminal device 1. The map DB 24 stores various data used for autonomous driving of the autonomous vehicle, such as road data, facility data, and feature data around the road.

  The toll DB 25 mainly stores tolls for expressways and toll roads. The control unit 23 can acquire a toll between specific interchanges by referring to the toll DB 25.

  The parking lot DB 26 stores information on the parking lot. FIG. 4 shows an example of the parking lot DB 26. The parking lot DB 26 stores, for each “parking lot ID”, “name”, “position”, “fee”, “vacancy”, and “whether or not automatic driving vehicles can be parked” for each parking lot. The “parking lot ID” is identification information for uniquely identifying each parking lot, and the “name” is a name indicating the parking lot. “Position” is the geographical position of the parking lot, and is indicated by latitude and longitude. The “fee” is a parking fee at the parking lot, and is, for example, indicated in units of hours. “Availability” indicates the current availability of the parking lot.

  “Autonomous driving vehicle entry availability” indicates whether or not the parking lot permits entry of automatic driving vehicles. In general, in order to accept the entry of an automatic driving vehicle, various facilities for safely driving and parking the automatic driving vehicle in a parking lot are required. Parking facilities that are fully equipped with such facilities and that allow entry of self-driving cars are set to “permitted”, and parking areas that do not allow self-driving cars are automatically parked. The entry into the driving car is set to “impossible”.

  The user DB 27 stores information on the user of the self-driving vehicle V. FIG. 5 shows an example of the user DB 27. The user DB 27 stores “vehicle ID”, “schedule”, “common parking lot ID”, “vehicle fuel efficiency”, and “priority cost” for each “user ID”. “User ID” is information for uniquely identifying each user, and is assigned to each user. “Vehicle ID” is identification information of the self-driving vehicle V used by the user, and for example, a vehicle number or the like can be used.

  “Schedule” indicates a future schedule of the user. Specifically, one schedule includes “scheduled time” and “destination”. In the example of FIG. 5, in the next schedule of the user whose user ID is U00001, the scheduled time is “10:00 on June 22, 2018”, and the destination is “A station”. If there are a plurality of future schedules, they are all stored.

  The “common parking lot ID” is identification information indicating a parking lot normally used by the user. Note that the ID used in the parking lot DB 26 can be used as the parking lot ID. Generally, new parking lots that do not require the user to pay a usage fee, such as a parking lot at the user's home, a company parking lot, or a parking lot for which the user has contracted for use, are registered as regular parking lots. . Note that a plurality of regular parking lots may be registered for one user. For example, a user may register both a home and a company parking lot as a regular parking lot.

  “Vehicle fuel efficiency” is the fuel efficiency of the vehicle indicated by the vehicle ID. The value of the fuel efficiency may be a general numerical value of the vehicle of the type, or may be a numerical value unique to the user calculated based on the actual running history of the user.

  The “priority cost” indicates the cost that the user has priority when determining the travel plan of the self-driving vehicle V after the user gets off the vehicle, and as described later, “charge cost”, “risk cost” , “Scheduled advance cost” and “Total cost” are stored by the user.

  In the above configuration, the terminal device 1 is an example of the autonomous traveling control device of the present invention, and the control unit 14 controls the regular parking place position acquiring unit, the schedule acquiring unit, the departure instruction acquiring unit, the traveling plan acquiring unit, and the control of the present invention. The input unit 13 is an example of a setting unit of the present invention.

[Driving plan generation method]
Next, a method for generating a travel plan will be described. In the present embodiment, when the user gets off the automatic driving vehicle V, the server device 2 determines a traveling plan that defines a subsequent action of the automatic driving vehicle V in consideration of the next schedule of the user. .

(Basic policy)
First, a basic policy for determining a travel plan will be described. In this embodiment, for the action of the self-driving vehicle V after the user gets off, which cost the user attaches importance to is set in advance via the input unit 13. Specifically, the user selects one of the four costs of “charge cost”, “risk cost”, “planned advance cost”, and “total cost” as the priority cost to which the user has priority. The selected cost is registered in the user DB 27 as a priority cost as shown in FIG.

  Here, the “fee cost” is a cost indicating a fee generated when the self-driving vehicle V travels, and is based on an energy consumption (fuel fee), a parking lot, a toll road fee, and the like used at the time of traveling. Is calculated. The “risk cost” is a cost that indicates the degree of danger or the possibility of an accident when the automatic driving vehicle V runs, and is calculated according to the route on which the automatic driving vehicle V runs. The “scheduled advance cost” is a cost indicating a possibility of coping when the scheduled time specified in the schedule is advanced (earlier than scheduled), and indicates the next destination and the current position of the automatic driving vehicle V. Is calculated based on the distance between. The “total cost” is a cost when all of the above “fee cost”, “risk cost”, and “schedule advance cost” are considered, and is based on the respective values of the charge cost, the risk cost, and the schedule advance cost. Is calculated.

When the user gets off the automatic driving vehicle V with the priority cost set, the server device 2 determines a travel plan based on the next schedule of the user. At that time, the server device 2 first generates the following three types of travel plans as candidates.
(A) Regular parking lot use plan In this traveling plan, the self-driving car V starts from the point at which the user gets off the self-driving car V (hereinafter referred to as “disembarkation point”), and the regular parking lot of the user. Move to and wait, and then head to the destination from the regular parking lot.
(B) External parking lot use plan In this traveling plan, the self-driving vehicle V moves from the disembarkation point to an external parking lot around the destination and waits, and then heads from the external parking lot to the destination. "External parking lot" shall mean a parking lot other than the regular parking lot of the user. The external parking lot is preferably a parking lot around the destination. However, if there is no appropriate parking lot around the destination, a parking lot existing within a predetermined range from the route from the current position to the destination is preferred. It may be.
(C) Circumference Plan In this traveling plan, the self-driving vehicle V travels from the disembarkation point to the destination without waiting in the parking lot, and when arriving near the destination, circulates a road near the destination until the scheduled time.

  When the three candidates for the travel plan are obtained in this way, the server device 2 calculates the above four costs for each of the three candidates (A) to (C), namely, the fee cost, the risk cost, the scheduled advance cost, and , Calculate the total cost. Then, the server device 2 determines, as the travel plan, the one with the smallest cost value set as the priority cost by the user among the three candidates. For example, when a certain user sets the toll cost as the priority cost, the server device 2 determines a candidate having the smallest toll cost among the three candidates as the travel plan. As a result, a travel plan suitable for the cost that is prioritized by the user can be obtained.

(Driving plan generation processing)
Next, the travel plan generation processing performed in accordance with the above basic policy will be described in detail. FIG. 6 is a flowchart of the travel plan generation processing. This processing is executed by the server device 2. Specifically, this is realized by the control unit 23 of the server device 2 executing a prepared program.

  First, the server device 2 determines whether or not a departure instruction signal has been received from the self-driving vehicle V (Step S10). As described above, the departure instruction signal is generated by the terminal device 1 when the user gets off the automatic driving vehicle V, and is transmitted to the server device 2.

  Upon receiving the departure instruction signal (Step S10: Yes), the server device 2 acquires the vehicle ID and the current position of the automatic driving vehicle V that is the transmission source of the departure instruction signal, and refers to the user DB 27 and sets the vehicle ID as the vehicle ID. A user is specified based on the user, and the next schedule of the user is acquired (step S11). Next, the server device 2 determines whether there is a next schedule within a predetermined period (step S12). Here, the “predetermined period” is a predetermined period, and is set to, for example, 24 hours (1 day).

  If there is no next schedule within the predetermined period (step S12: No), that is, if there is no next schedule, or if the next schedule is after 24 hours, the server device 2 simply moves to the regular parking lot. A return travel plan is generated and transmitted to the terminal device 1 (step S13). As a result, when there is no schedule within the predetermined period, the self-driving vehicle returns to the regular parking lot and waits. When the user has registered a plurality of regular parking lots, it is desirable that the server device 2 generates a traveling plan for returning to the regular parking lot closer to the current position of the self-driving vehicle.

  On the other hand, if there is a next schedule within the predetermined period (step S12: Yes), the server device 2 searches for a route from the current position of the self-driving vehicle V to the destination indicated by the next schedule, and sets the route as the destination. The time required to arrive is calculated (step S14).

Next, the server device 2 determines whether or not the surplus time is longer than a first predetermined time (Step S15). Here, the “excess time” is the time remaining until the scheduled time of the next schedule when the automatic driving vehicle V moves from the current position to the destination, and is obtained by the following equation.
Surplus time = (scheduled time−current time) −required time Further, “first predetermined time” is set to, for example, about 10 minutes.

  If the surplus time is not longer than the first predetermined time (step S15: No), there is not much time before the next schedule, so the server device 2 generates a travel plan for the next destination, and The data is transmitted to the device 1 (step S16). Thereby, the self-driving vehicle V immediately starts traveling to the next destination.

  In this case, if the surplus time is shorter than the first predetermined time (10 minutes), but there is some surplus, for example, the surplus time is longer than the second predetermined time (here, “5 minutes”). If the distance is longer, the server device 2 may generate the travel plan so that the self-driving vehicle travels on a route that makes a long circuit. On the other hand, if the surplus time is shorter than the second predetermined time (5 minutes), the self-driving vehicle travels on a normal route (a route that does not make a detour) and arrives at the destination several minutes (5 minutes or less) earlier. Just wait.

  On the other hand, if the surplus time is longer than the first predetermined time, the server device 2 performs the cost calculation process because there is some time margin before the next schedule (step S17). FIG. 7 is a flowchart of the cost calculation process. The cost calculation process includes, for each of the three travel plan candidates described above, ie, the regular parking lot use plan, the external parking lot use plan, and the lap plan, the fee cost, the risk cost, the scheduled advance cost, and the total cost. Is calculated.

  First, with respect to the regular parking lot utilization plan, the server device 2 searches for a route from the current position of the self-driving vehicle V to the destination with the regular parking lot as a transit point (step S31). Next, the server device 2 determines whether or not the self-driving vehicle V can reach the destination by the scheduled time based on the obtained route (Step S32). The regular parking lot is a parking lot of a user's home or a company, and is not always close to the destination. Therefore, if the user passes through the regular parking lot, it may not be possible to arrive at the destination by the scheduled time. When it is not possible to arrive at the destination by the scheduled time (step S32: No), the server device 2 excludes the regular parking lot use plan from the candidates for the travel plan (step S33). On the other hand, if the destination can be reached by the scheduled time (step S32: Yes), the server device 2 calculates the charge cost, the risk cost, the scheduled advance cost, and the total cost based on the route obtained in step S31. It is calculated (step S34). Then, the process returns to the main routine of FIG.

  Next, regarding the external parking lot use plan, the server device 2 first searches for an external parking lot around the destination (step S35). At this time, the server device 2 refers to the parking lot DB 26 and selects an external parking lot whose vacant state is “vacant”. In addition, as shown in FIG. 4, for a parking lot that defines whether or not automatic driving vehicles can enter, an external parking lot is selected in consideration of whether or not automatic driving vehicles can enter. Then, the server device 2 searches for a route to the destination using the obtained external parking lot as a waypoint (step S36).

  Next, the server device 2 refers to the parking lot DB 26 and calculates a parking fee based on the required parking time (Step S37). Next, the server device 2 calculates a fee cost, a risk cost, a scheduled advance cost, and a total cost based on the route obtained in step S36 (step S38). The fee cost includes the parking fee obtained in step S37. Then, the process returns to the main routine of FIG.

  Next, with respect to the circuit plan, the server device 2 searches for a circuit route around the destination (step S39). The orbiting route is, for example, a route orbiting between a destination and an orbiting stopover (a nearby station or facility, etc.). The roundabout is a point around the destination set according to a predetermined standard. Examples of the predetermined criterion include a point within a predetermined distance from the destination, a point adjacent to a road on which an autonomous vehicle can safely travel, such as a main road, and the like. By referring to traffic congestion information and the like, a point where the road to the destination is not congested may be set as a roundabout. As an example, if the roundabout is a facility X around the destination, the round route is a route from the destination to the destination via the facility X. The self-driving vehicle V travels one or more times on the circuit route to adjust the arrival time at the destination. In the circling plan, when the destination is a point where parking is possible, the time may be adjusted by parking instead of circling around the circulating route.

  Next, the server device 2 calculates the number of rounds of the obtained round path (step S40). Specifically, the server device 2 calculates how many times it is necessary to travel on the circuit route, based on the surplus time and the time required for traveling the circuit once. Next, the server device 2 calculates a fee cost, a risk cost, a scheduled advance cost, and a total cost based on the route obtained in step S39 (step S41). Then, the process returns to the main routine of FIG.

  Returning to FIG. 6, the server device 2 acquires the priority cost selected by the user from the user DB 27, and determines one travel plan based on the priority cost (step S18). That is, the server device 2 determines, as a travel plan, one candidate having the minimum priority cost of the user among a plurality of travel plan candidates obtained in the cost calculation process. Then, the server device 2 transmits the determined travel plan to the terminal device 1 (Step S19). In this way, the self-driving vehicle V travels to the destination according to the travel plan that minimizes the priority cost selected by the user.

(Example of driving plan)
Next, an example of a travel plan generated by the travel plan generation process will be described. 8A to 8C show examples of a travel plan. In addition, as for these travel plans, the user of the user ID “U00001” shown in FIG. 5 gets off the automatic driving vehicle V at the station A at 10:00 on June 22, 2018 as shown in the schedule, The next schedule is generated when heading for station B by 15:00 on the same day.

  FIG. 8A shows an example of a regular parking lot use plan. In the regular parking lot use plan, the self-driving vehicle V waits at the regular parking lot of the user and then heads to the destination. In the example of FIG. 8A, the self-driving vehicle V leaves the station A at 10:00, arrives at the regular parking lot at 10:10, and stands by at the regular parking lot. Thereafter, the self-driving car V leaves the regular parking lot at 13:00 and arrives at the B station at 15:00.

  FIG. 8B shows an example of an external parking lot use plan. In the external parking lot utilization plan, the self-driving vehicle V goes to the destination after waiting in the external parking lot. In the example of FIG. 8B, the self-driving car V leaves the A station at 10:00, arrives at an external parking lot near the destination at 11:50, and stands by at the external parking lot. Thereafter, the self-driving car V leaves the regular parking lot at 14:55 and arrives at station B at 15:00.

  FIG. 8C shows an example of a circuit plan. In the lap plan, the self-driving vehicle V immediately goes from the current position to the destination, and after arriving at the destination, makes a lap around the lap route near the destination. In the example of FIG. 8C, the self-driving car V leaves Station A at 10:00 and arrives at Station B at 13:40. Thereafter, the self-driving vehicle V goes around the circuit route near the destination and arrives at the station B at 15:00.

  Note that FIG. 8 exemplifies a regular parking lot use plan, an external parking lot use plan, and a roundabout plan, respectively. A plan may be generated. For example, when there are a plurality of routes that move from the current position to the regular parking lot and a plurality of routes that move from the regular parking lot to the destination, a plurality of regular parking lot use plans are generated. When there are a plurality of routes that move from the current position to the external parking lot and a plurality of routes that move from the external parking lot to the destination, a plurality of external parking lot use plans are generated. In addition, when there are a plurality of routes moving from the current position to the destination, or when there are a plurality of circuit routes near the destination, a plurality of circuit plans are generated.

(Example of cost calculation)
Next, an example of calculating a cost for each travel plan will be described. FIG. 9 is an example of a cost calculation result for a plurality of travel plans. In this example, it is assumed that two regular parking lot use plans, three external parking lot use plans, and two circuit plans are generated by the travel plan generation processing.

  The toll cost is indicated by an amount required when the self-driving vehicle V moves according to the travel plan, and includes a fuel cost, a toll road fee, a parking fee, and the like necessary for the self-driving vehicle V to travel. Specifically, in the regular parking lot use plan, since the use of the regular parking lot is free, the toll cost is the sum of the fuel cost and the toll road fee when using the toll road. In the external parking lot use plan, the toll cost is the sum of the fuel cost, the toll road fee when using a toll road, and the parking fee of the external parking lot. In the round trip plan, there is no parking fee, so the toll cost is the sum of the fuel cost and the toll road fee when using a toll road. The smaller the required fee, the lower the value of the fee cost.

  As a specific calculation method, the server device 2 calculates the fuel cost based on the travel distance of the automatic driving vehicle V according to the travel plan, the fuel efficiency of the vehicle stored in the user DB 27, and the price of the fuel. I do. The fuel price may be stored in the server device 2 such as a national average or an average price for each region. The server device 2 may acquire the toll road fee by referring to the toll DB 25 and the parking lot fee by referring to the parking lot DB 26.

  The risk cost is an index indicating a risk such as an accident when the self-driving vehicle V runs, and the total driving time, the total mileage, the number of passages of the accident-prone spots of the self-driving vehicle V, and the road with a high speed limit (hereinafter referred to as “high-speed”) , "High-restricted speed road")), based on some or all of the travel time and the number of intersections passed. More specifically, the number of risk points per hour, the distance traveled 1 km, the number of accident-prone points, the number of high-speed roads 1 km, and the number of risk points per intersection are determined in advance. May be calculated. The lower the risk such as an accident, the lower the value of the risk cost. The high speed limit road is, for example, a road having a speed limit of 80 km or more. Since the speed limit of an expressway, a toll road, or the like is stored in the map DB 24, the server device 2 only needs to calculate the travel time when the vehicle travels on those roads at the speed limit.

  The scheduled advance cost is an index indicating whether or not the self-driving vehicle V can quickly arrive when the scheduled time in the next schedule is advanced and the user calls for the self-driving vehicle V in a hurry, and It is indicated by the average distance from the current position of the automatic driving vehicle V. Specifically, the server device 2 estimates a scheduled position of the self-driving vehicle V at predetermined time intervals (for example, 20 minutes) according to the travel plan, and calculates a distance between the scheduled position and the destination. Then, those distances are averaged to calculate an average distance. As the average distance is shorter, the self-driving vehicle V is closer to the next destination, and it is possible to quickly respond to the scheduled advance, so that the value of the schedule advance cost is smaller.

  The total cost is the total cost of the fee cost, the risk cost, and the scheduled advance cost. The total cost is selected when the user does not particularly prioritize any one of these three costs, but wants to comprehensively judge these three costs to determine a travel plan. In order to calculate the total cost, a conversion formula or a conversion rule for converting the value of the fee cost, the risk cost, and the scheduled advance cost into a total point is determined in advance. Then, the server device 2 converts the fee cost, the risk cost, and the scheduled advance cost into the total points according to the conversion formula or the conversion rule, respectively, and totals them to calculate the total cost.

  Instead of using the total points, the total cost may be calculated by converting the remaining two into one of the fee cost, the risk cost, and the scheduled advance cost. For example, a conversion formula for converting the value of the risk cost (risk point) and the value of the scheduled advance cost (average distance) into the value of the toll cost (namely, amount) is prepared in advance, and the risk point and the average distance are converted into the amount. The conversion may be performed so that the total cost is indicated by the amount.

  In the above example, the total cost is calculated based on the fee cost, the risk cost, and the scheduled advance cost. However, the total cost may be calculated based on only two of the three. For example, the total cost may be calculated based on the fee cost and the risk cost.

  As illustrated in FIG. 9, when the cost is calculated for each travel plan, the server device 2 selects one travel plan according to the priority cost selected by the user. For example, when the user has selected the toll cost as the priority cost, the server device 2 selects the regular parking lot use plan 1 with the lowest toll cost. When the user has selected the risk cost as the priority cost, the server device 2 selects the external parking lot use plan 3 having the minimum risk cost. In the case where there are a plurality of travel plans with the minimum priority cost value, the server device 2 may select another travel plan or a travel plan with a small overall cost.

[Modification]
Hereinafter, a modified example of the above embodiment will be described. The following modifications can be applied to the above embodiments in appropriate combinations.
(Modification 1)
In the above embodiment, when the user gets off the automatic driving vehicle V, a travel plan from that point to the destination in the next schedule is generated. Regardless, a travel plan between any two schedules may be generated. For example, when the first schedule and the subsequent second schedule are determined as the next day's schedule, the destination and the scheduled time in the first schedule and the destination and the scheduled time in the second schedule are determined. A travel plan between the vehicles may be generated. Thus, the user can confirm the travel plan in advance based on the future schedule.

(Modification 2)
In the above embodiment, the server device 2 generates the travel plan, but instead, the terminal device 1 mounted on the self-driving vehicle V may generate the travel plan. In this case, if the toll DB and the parking lot DB are stored in the storage unit 12 of the terminal device 1 and the control unit 14 of the terminal device 1 executes the above-described travel plan generation processing to determine the travel plan. Good. In this case, since the parking lot DB is required to have real-time properties, an external server device that collects information on the availability of the parking lot may be used from an external server device around the current position of the self-driving car V or around the route to the destination. It is desirable to periodically download information on the vacant state of the parking lot and update the contents of the parking lot DB stored in the terminal device 1.

(Modification 3)
As described above, one driving plan is determined according to the priority cost selected by the user, and after the self-driving vehicle V starts an action according to the driving plan, the traffic condition of the road to be driven, the availability of the parking lot to be parked, and the like. When the state or the like changes, it is desirable that the server device 2 re-executes the travel plan generation process based on the current position of the self-driving vehicle V at that time and the next schedule. Thereby, even when the surrounding environment changes, the automatic driving vehicle V can travel with an optimal travel plan. For example, after the self-driving vehicle V starts running according to the external parking lot use plan, if the planned external parking lot becomes full and becomes unusable, by re-executing the driving plan generation process, An external parking lot use plan that uses another external parking lot may be selected, or a round trip plan may be selected instead of the external parking lot use plan.

(Modification 4)
In the above embodiment, the example of using the external parking lot in the external parking lot use plan is shown, but the external parking lot is not limited to the paid parking lot, for example, a free parking lot attached to a park or a public institution. It may be. In addition to the so-called parking lot, if there is an area or space where a vehicle can be parked without violating traffic regulations, it may be used. From this viewpoint, the places where these vehicles can be parked are collectively referred to as “parking places”.

(Modification 5)
In the above embodiment, the travel plan of the self-driving vehicle V is generated, but the present invention can be applied to a normal vehicle. In that case, a traveling route corresponding to the traveling plan determined by the server device 2 may be set in a car navigation device or the like.

1 terminal device 2 server device 4, 24 map DB
14, 23 control unit 25 toll DB
26 parking lot DB
27 User DB

Claims (8)

An autonomous traveling control device mounted on a vehicle capable of autonomous traveling and controlling autonomous traveling of the vehicle,
A regular parking place position acquiring means for acquiring a position of a regular parking place where the vehicle can always park,
Schedule acquisition means for acquiring a schedule indicating a destination to which the vehicle should arrive and a scheduled time to arrive at the destination;
Departure instruction acquisition means for acquiring a departure instruction from a user of the vehicle,
When a schedule to be executed within a predetermined period has not been acquired by the schedule acquiring unit, a traveling plan acquiring unit that acquires a traveling plan for returning to the regular parking place,
Control means for controlling autonomous traveling of the vehicle after the departure instruction acquisition means has acquired a departure instruction, according to the travel plan acquired by the travel plan acquisition means,
An autonomous traveling control device comprising: The travel plan acquisition means is a travel plan to arrive at the destination by the scheduled time when a schedule to be executed within a predetermined period is acquired by the schedule acquisition means, and A plurality of travels including a first travel plan for parking at the service parking location before arrival and a second travel plan for parking at another parking location different from the service parking location before arrival at the destination Get the plan,
The control unit controls the autonomous traveling of the vehicle after the departure instruction obtaining unit obtains a departure instruction according to one travel plan selected based on a predetermined criterion from among the plurality of travel plans. The autonomous traveling control device according to claim 1. The regular parking place position acquiring means acquires the positions of a plurality of regular parking places,
When the schedule to be executed within a predetermined period has not been acquired by the schedule acquisition unit, the travel plan acquisition unit may include a service parking place closest to the position where the departure instruction is acquired among the plurality of service parking places. The autonomous traveling control device according to claim 1, wherein the returning traveling plan is acquired.   The travel plan acquisition means is a travel plan for arriving at the destination by the scheduled time when the schedule to be executed within a predetermined period is acquired by the schedule acquisition means, and The autonomous traveling control device according to claim 3, wherein a traveling plan for parking at a regular parking location where traveling distance to the destination is the shortest among the locations is acquired.   The autonomous traveling control device according to claim 2, further comprising a setting unit that allows a user to set the predetermined reference. An autonomous traveling control method mounted on a vehicle capable of autonomous traveling and executed by an autonomous traveling control device that controls autonomous traveling of the vehicle,
A regular parking place position acquiring step of acquiring a regular parking place position where the vehicle can always park,
A schedule acquisition step of acquiring a schedule indicating a destination at which the vehicle should arrive and a scheduled time at which the vehicle should arrive at the destination,
A departure instruction obtaining step of obtaining a departure instruction from a user of the vehicle,
When a schedule to be executed within a predetermined period has not been acquired by the schedule acquiring step, a traveling plan acquiring step of acquiring a traveling plan to return to the regular parking place,
A control step of controlling the autonomous traveling of the vehicle after the departure instruction acquisition step acquires the departure instruction, according to the travel plan acquired by the travel plan acquisition step,
An autonomous driving control method, comprising: A program that is mounted on a vehicle capable of autonomous traveling, includes a computer, and is executed by an autonomous traveling control device that controls autonomous traveling of the vehicle,
Regular parking place position acquisition means for acquiring the position of a regular parking place where the vehicle can always park,
Schedule acquisition means for acquiring a schedule indicating a destination to which the vehicle should arrive and a scheduled time to arrive at the destination;
Departure instruction acquisition means for acquiring a departure instruction from a user of the vehicle,
When a schedule to be executed within a predetermined period has not been acquired by the schedule acquiring unit, a traveling plan acquiring unit that acquires a traveling plan for returning to the regular parking place,
Control means for controlling the autonomous traveling of the vehicle after the departure instruction acquisition means has acquired a departure instruction, according to the travel plan acquired by the travel plan acquisition means;
A program for causing the computer to function as a computer.   A storage medium storing the program according to claim 7.

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