JP2017174208A - Taxi service system using self-driving vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a taxi service system which enables traveling even when traveling by automatic driving is disabled due to an unexpected situation, while employing automatic driving.SOLUTION: A taxi service system using a self-driving vehicle includes: a terminal device (100) for a taxi user to operate; a self-driving vehicle (300) capable of traveling automatically and capable of traveling by a remote operation; a remote operation device (200) for executing a remote operation; and a control center (400) capable of communicating with the terminal device, self-driving vehicle and remote operation device via a communication network. The remote operation device includes a monitor part (201) for obtaining, via the communication network, vehicle information on the self-driving vehicle selected from at least one of a generated vehicle distribution plan and a managed schedule, and displaying the information.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a technical field of a system that performs taxi service using an autonomous driving vehicle.

As this type of system, a user (that is, a taxi user) directly communicates with a taxi that is an autonomous driving vehicle or an unmanned vehicle using wireless communication, so that the user can call the autonomous driving vehicle. Has been proposed (see Patent Document 1).
On the other hand, a remote operation system for remotely operating a vehicle has been proposed (see Patent Document 2).

WO2016 / 002527 Publication JP 2014-71655 A

However, according to the taxi service system described above (Patent Document 1), if a sensor for automatic driving or the like malfunctions or an unexpected abnormality occurs in the system, the autonomous driving vehicle may become unable to travel. There is a technical problem that there is. Needless to say, the user is inconvenienced when driving is actually impossible. Even if this is not the case, the user may be worried that he will not be able to travel while riding a taxi, or he may be unable to travel while waiting for a taxi (thus being delayed). I feel a sense of anxiety.
On the other hand, the remote operation by the above-mentioned remote operation system (Patent Document 2) is a completely different technology from the automatic driving. If this technology is applied to the taxi system, it is not a driving by each taxi driver. In addition, remote operation by a remote operator assigned to each taxi is always required, and it is impossible to enjoy the benefits of personnel reduction by adopting automation technology and the benefits of automated driving.

  The present invention has been made in view of the above-described problems, and provides a taxi service system that makes it possible to travel even when automatic driving is disabled due to unforeseen circumstances, while automatic driving is employed. The issue is to provide.

  In order to solve the above problems, a taxi service system using the autonomous driving vehicle of the present invention is accommodated in a communication network, a terminal device for operation by a taxi user, and accommodated in the communication network, An automatic driving vehicle that is used as a taxi and that can be driven by a remote operation from a remote location via the communication network and can be automatically driven, and is accommodated in the communication network A plurality of remote control devices for executing the remote control and the communication network, respectively, and the terminal device, the autonomous driving vehicle and the plurality of remote control devices via the communication network And a control center capable of communication. The control center acquires, via the communication network, reservation information indicating the details of the reservation relating to the taxi, which is input from the terminal device, and stores a reservation processing unit, the autonomous driving vehicle, and the plurality of remote A schedule management unit that manages a schedule of the operating device; and a vehicle allocation plan creation unit that creates a vehicle allocation plan for the reservation with reference to the stored reservation information and the managed schedule. Each of the plurality of remote control devices includes vehicle information to be used for the remote control in the autonomous driving vehicle selected for each of them on at least one of the created dispatch plan and the managed schedule. And a monitor unit for acquiring and displaying via the communication network. The self-driving vehicle arrives at the destination indicated by the reservation information after the user has boarded at the boarding place set based on at least one of the created dispatching plan and the managed schedule. And a clearing unit for performing clearing for the user.

  According to the taxi service system according to the present invention, reservation information is input via a terminal device by a user who intends to use a taxi during operation. Then, in the control center, the reservation processing unit acquires and stores the input reservation information via the communication network. At the same time, in the control center, the schedule management unit manages the schedule of the autonomous driving vehicle and the plurality of remote control devices, and the dispatch plan creation unit manages the reservation information stored in this way. A dispatch plan for a reservation is created or created with reference to the schedule.

  On the other hand, each of the plurality of remote control devices is an automatic driving vehicle used as a taxi selected for at least one of the prepared dispatching plan and the managed schedule, for example, front, rear, left and right cameras of the vehicle Vehicle information used for remote operation such as images and vehicle speed information is acquired via a communication network and displayed in a predetermined format on the monitor unit.

  Therefore, the remote operation device selected for the autonomous driving vehicle can remotely monitor the automatic driving status of the autonomous driving vehicle via the monitor unit. In the event of an unforeseen situation during the automatic operation, if the automatic operation function is disturbed or becomes impossible, the remote control device is connected via the communication network. According to the vehicle information displayed on the monitor unit, it is possible to perform driving by remote control instead of automatic driving by an autonomous driving vehicle.

  In addition, even in normal times when the automatic driving function of the autonomous driving vehicle does not break down, it is known to the user that “if automatic driving fails, it is possible to continue driving by switching to remote operation”. Therefore, it is possible to reduce anxiety that the user is afraid of failure and anxiety given to the user.

  In addition, in such an automatically driven vehicle, as long as the automatic driving function is normal, it is not necessary to drive by a remote operator assigned to each taxi instead of driving by a taxi driver.

  After that, when the vehicle arrives at the destination by automatic driving or by remote operation instead of part or all of the automatic driving, the automatic driving vehicle performs the liquidation for the user by the liquidation unit. Therefore, it is possible to charge and charge a user for fair payment on condition that the user arrives at the destination in both automatic driving and driving by remote control.

  As described above, according to the taxi service system of the present invention, it is possible to give a sense of security to the user due to the presence of remote operation while enjoying the benefits of automation by automatic driving.

  Such effects and other advantages of the present invention will be made clear by the embodiments described hereinafter.

It is a block diagram which shows the structure of the taxi service system of 1st Embodiment. It is a sequence chart which shows operation | movement of 1st Embodiment.

  First, a configuration of an embodiment of a taxi service system using the autonomous driving vehicle of the present invention will be described with reference to FIG.

  In FIG. 1, a taxi service system using an autonomous driving vehicle according to the present embodiment includes a portable device 100, a remote control device 200, an autonomous driving vehicle 300, and a control center 400. The portable device 100, the remote control device 200, the autonomous driving vehicle 300, and the control center 400 are accommodated in one communication network such as the Internet, and as shown by a radio wave symbol 500 in the figure, they mutually pass through the communication network. Wireless communication is possible.

  The mobile device 100 constitutes an example of a “terminal device” according to the present invention. Specifically, the mobile device 100 has a communication function (typically, mobile, mobile, mobile phone, small personal computer, etc.) carried by a user. Internet connection function) and is configured as a terminal device for operation by a user who uses an unmanned taxi. The portable device 100 has a function of identifying its own position by GPS, and as described later in detail (see FIG. 2), various signals are transmitted to and from the control center 400 and the like via a radio signal radio wave 500. When transmitting and receiving, it is configured to be able to notify the self-position at each time point. The ID card (ID CARD) 102 indicates an individual ID (identification information) given to use the autonomous driving vehicle 300 as an unmanned taxi, and is inserted into or incorporated in the portable device 100 separately from the portable device 100. Owned by the user. The unmanned taxi registration ID 104 indicates an ID (identification information) of each unmanned taxi corresponding to each automatic driving vehicle 300, and is taken into the portable device 100 in advance or before or after using the taxi.

  In FIG. 1, for convenience of explanation, only one set of the portable device 100, the ID card 102, and the unmanned taxi registration ID 104 is shown. However, in an actual system, as shown by “... A set of a large number of portable devices 100 and ID cards 102 and unmanned taxi registration IDs 104 are accommodated in the same communication network placed under the control of the control center 400.

  The remote operation device 200 performs remote monitoring of the autonomous driving vehicle 300 assigned to itself (that is, selected by the control center 400 as described later), and further performs remote operation of the autonomous driving vehicle 300 as necessary. It is configured so as to be appropriately executed by a remote operator. Specifically, the remote control device 200 is actually used by driving operation in a situation as if the driver is in the driver's seat of the vehicle by adopting the remote control technology described in Patent Document 2 described above, for example. Is configured to run the autonomous driving vehicle 300 by remote control from a remote place via a communication network.

  More specifically, as shown in FIG. 1, the remote control device 200 imitates the driver's seat of a vehicle corresponding to the autonomous driving vehicle 200 (typically, a general vehicle having no automatic driving function). A monitor 201, a handle 202, a brake 203, an accelerator 204, a light 205, a turn signal 206, a net connector 210, a remote person registration ID 211, and a remote person monitoring monitor 220 are provided. The monitor 201 constitutes an example of a “monitor unit” according to the present invention. Among the parts imitating the driver's seat of these vehicles, the display device such as the monitor 201 and the turn signal 206, and the output device related to the instrument are information necessary for reference when performing the remote operation of the autonomous driving vehicle 300. Image information in front of the autonomous driving vehicle 300 is received by the network connection device 210 (that is, the remote operation device 200 side) from the network connector 310 (that is, the autonomous driving vehicle 300 side) via the radio wave symbol 500, and It is configured to display and output image information and the like. On the other hand, among the parts imitating the driver's seat of these vehicles, the operation input device related to the operation input for driving the vehicle such as the handle 202, the brake 203, the accelerator 204, the light 205, and the turn signal 206 is an automatic driving vehicle 300. When the remote operation of the network connection device 310 is performed, an operation signal indicating a desired operation is transmitted from the network connector 210 (that is, the remote operation device 200 side) via the radio wave symbol 500 to the network connection device 310 (that is, the autonomous driving vehicle 300 side). And the remote operation of the autonomous driving vehicle 300 is executed by the operation signal or the like.

  The network connector 210 transmits and receives various signals with the control center 400, transmits and receives various signals with the autonomous driving vehicle 300 (for example, various signals for remote monitoring and various signals for remote operation), etc. It is configured to be executable via the radio wave 500. Here, the communication between the network connector 210 and the control center 400 may be wireless or wired, such as a high-speed wired line using an optical fiber cable or the like. Furthermore, if the configuration in which the remote control device 200, the mobile phone 100, and the autonomous driving vehicle 300 are connected via the control center 400 is adopted, the network connector 210 may have only a wired connection function. It ’s enough. The remote operation device 200 may be installed in a remote place such as a call center far from the autonomous driving vehicle 300, the portable device 100, and further the control center 400 as long as communication is possible. It may be deployed in the home to be constructed, or may be constructed as a movable unit.

  By using an output device (that is, the monitor 201 or the like) or an operation input device (that is, the handle 201 or the like) constituting the remote operation device 200, the remote operation device 200 can be used as a remote operator to A realistic simulated environment as if sitting in the driver's seat is established. The monitor 201 may perform three-dimensional display by performing imaging corresponding to the three-dimensional display on the side of the autonomous driving vehicle 300, and thereby the environment that imitates an actual driver's seat environment more realistically. 200 can be built. In addition to the basic function of displaying the front of the vehicle, etc., the monitor 201 automatically displays when the autonomous driving vehicle 300 is automatically driven (that is, during remote operation) by switching display or window display. You may function as a monitor for remotely monitoring each apparatus, each site | part, each operation condition, a driving condition, etc. in the driving vehicle 300. FIG. For this reason, the remote control device 200 receives monitoring information indicating normality, failure, abnormality, or the like of the autonomous driving vehicle 300 from the autonomous driving vehicle 300 in a form included in the radio wave signal 500, and monitors the monitor 201 in a predetermined format. It may be configured to be capable of display output. In addition, the display by the monitor 201 may be accompanied by an audio output.

  The remote person registration ID 211 is an ID (identification information) that is individually assigned to a remote person who remotely operates the autonomous driving vehicle 300, or in advance or before or after the start of remote monitoring of the unmanned taxi. Is taken in. The remote person monitoring monitor 220 monitors a video of a remote operator or the like when the remote person or the remote observer, and when this person works as a remote operator who performs remote operation instead of simple remote monitoring. It is configured as follows. That is, a user who is riding on the autonomous driving vehicle 300 can view a state in which the remote operator performs a remote operation or the like as a real-time video in the vehicle via the communication network. As a result, the user can feel more secure while traveling.

  In FIG. 1, for convenience of explanation, only one remote control device 200 is shown. However, in the actual system, it is indicated by “...” In the drawing so as to be compatible with many unmanned taxis or autonomous driving vehicles 300. As described above, a large number of remote control devices 200 are accommodated in the same communication network placed under the control of the control center 400. In order to cope with this, unique remote person registration IDs are respectively given to a large number of remote operators who have acquired driving skills by remote operation in advance.

  The autonomous driving vehicle 300 is a vehicle used as an unmanned taxi. For example, the automatic driving vehicle 300 can automatically travel by adopting the automatic driving technique described in Patent Document 1 described above, and the remote operation technique described in Patent Document 2 described above, for example. By adopting, it is configured as a vehicle that can travel by remote control from a remote place via a communication network.

  Specifically, as shown in FIG. 1, an autonomous driving vehicle 300 includes an automatic driving facility 301 for executing traveling by automatic driving as described above and a remote operating facility 302 for executing traveling by remote operating as described above. And an indoor monitor 303, a network connector 310, a card (card) connection kid 311, an automatic settlement unit 312, a camera 320, a GPS 331, and a charge state monitor 332.

  The automatic driving equipment 301 is equipped with various types mounted on the side of a vehicle that is automatically driven, for example, as described in Patent Document 1 described above, for enabling traveling by automatic driving when automatic driving is executed. Including equipment. When the remote operation facility 302 is executed, the remote operation facility 302 is configured to enable traveling by remote operation from the remote operation device 200 via the communication network, for example, as described in Patent Document 2 described above. Includes various devices mounted on remotely operated vehicles.

  The indoor monitor 303 displays various status parameters and various information related to various driving situations related to the autonomous driving vehicle 300, particularly the automatic driving status or the remote operation status in a predetermined format in a window display or full screen display while the user is in the vehicle. Is configured to display. The user can feel safe during traveling by looking at this in the car. In addition to this, it may be configured such that general broadcasts such as entertainment programs and news can be viewed by switching.

  The Card (card) connection kid 311 is configured to insert the I card 102 owned by the user and read the information when the user gets on the card. After that, the automatic clearing unit 312 is configured to be able to execute clearing by debiting from a credit card linked to the ID card 102 owned by the user or clearing by cash when the user arrives at the destination. Note that the ID card 102 owned by the user may be a credit card itself having a function of using an unmanned taxi.

  The network connector 310 transmits / receives various signals to / from the control center 400, transmits / receives various signals to / from the remote control device 200 (for example, various signals for remote monitoring, various signals for remote operation), etc. It is configured to be executable via the radio wave 500.

  The camera 320 is configured to include a plurality of cameras that capture images of the front side of the autonomous driving vehicle, further rearward of the vehicle, and left and right images. The camera 320 may be configured to include a plurality of imaging devices that capture images from positions slightly separated from each other in the same direction (for example, in front of the vehicle) so as to perform imaging corresponding to three-dimensional display. Thereby, it is possible to perform three-dimensional display on the monitor 201 on the remote operation device 200 side, and an environment imitating the actual driver's seat environment in the remote operation device 200 can be constructed more realistically.

  The GPS device 331 is configured to identify the current position of the autonomous driving vehicle 331 using GPS. The current position obtained here may be notified to the remote monitoring device 200 and the control center 400 as appropriate via the radio signal radio wave 500, and may be further notified to the portable device 100. The control center 400 appropriately adopts the current position obtained here as one of the reference information, and creates a vehicle allocation plan as will be described in detail later (see FIG. 2). The remote operation device 200 may use the current position obtained here for the purpose of specifying the autonomous driving vehicle 300 being remotely operated. The portable device 100 may use the current location obtained here for the purpose of specifying the current location of the autonomous driving vehicle 300 that is an unmanned taxi currently in use, or pick up while waiting for the unmanned taxi. You may utilize for the objective of specifying the present position of the automatic driving vehicle 300 which comes.

  The charge state monitor 332 is, for example, in any case of a hybrid vehicle, an electric vehicle, a fuel cell vehicle, a gasoline vehicle, and the like. For example). The state of charge obtained here may be appropriately notified to the remote monitoring device 200 and the control center 400 via the radio signal radio wave 500, and may be appropriately notified to the portable device 100. The control center 400 adopts the state of charge obtained here as one of the reference information, and creates a vehicle allocation plan as described in detail later (see FIG. 2). The remote operation device 200 may use the state of charge obtained here for the purpose of specifying the state of charge of the autonomous driving vehicle 300 being remotely operated. The portable device 100 may use the state of charge obtained here as the state of charge of the automatic driving vehicle 300 that is an unmanned taxi that is being used, or an automatic driving vehicle that picks up while waiting for an unattended taxi. It may be used for the purpose of specifying the state of charge of 300.

  In FIG. 1, for convenience of explanation, only one autonomous driving vehicle 300 is shown. However, in an actual system, as shown by “...” In the drawing, a large number of autonomous driving vehicles 300 as many unmanned taxis are controlled. It is accommodated in the same communication network placed under the control of the center 400.

As will be described in detail later (see FIG. 2), the control center 400 performs control operations on the plurality of autonomous driving vehicles 300, the plurality of remote control devices 200, and the plurality of portable devices 100 via the communication network. It is configured. Specifically, the control center 400 includes an unmanned taxi bulletin board 401, a registration server 402, an unmanned taxi management system 410, a remote person management facility 420, a vehicle information management facility 430, and a parking lot management facility 440.

The control center 400 wirelessly transmits / receives various signals to / from a large number of portable devices 100, a large number of remote control devices 200 (that is, a network connector 210), and a large number of autonomous driving vehicles 300 (that is, a network connector 310). It is configured to be executable via a communication network using the signal radio wave 500. Here, the communication between the network connector 210 and the control center 400 may be wired such as a high-speed wired line using an optical fiber cable or the like. Furthermore, a configuration in which the remote control device 200, the mobile phone 100, and the autonomous driving vehicle 300 are connected via the control center 400 may be employed. The control center 400 is, for example, installed in a control department that replaces the dispatching department of a traditional manned taxi company, and the control operation is performed semi-automatically or fully while the operator confirms the unmanned taxi bulletin board 401, for example. It is configured to do it automatically.

  The unmanned taxi bulletin board 401 has a large liquid crystal panel or the like, and displays a large number of unmanned taxis under control in a predetermined format. A configuration in which one or a plurality of workers can input various inputs contributing to a vehicle allocation plan to the unmanned taxi management system 410 while monitoring the display of the unmanned taxi bulletin board 401, and monitor whether there is any abnormality in the overall system. Has been.

  In the registration server 402, personal information such as a user ID registered as a person who can use an unmanned taxi and its attributes, and a taxi ID of an unmanned taxi registered as a vehicle used for an unmanned taxi ID information necessary for creating a vehicle allocation plan, such as personal information or individual information such as remote control devices or remote operators registered as remote control capable of remotely operating unmanned taxis and their attributes, Registered in advance or prior to dispatch.

  The unmanned taxi management system 410 includes a reservation processing unit 411, a dispatch plan creation unit 412, and a schedule management unit 413. The reservation processing unit 411 acquires and stores reservation information, which is input from the terminal device 100, indicating the content of the reservation related to the taxi requested by the user (that is, the autonomous driving vehicle 300) via the communication network. It is configured. “Reservation information” here indicates the desired place to get on, the place to get off, the time to get on, the desired arrival time, the desired car type or grade, the desired number of passengers, etc. Information. The reservation information is input by a user who makes a taxi reservation from the keyboard, touch panel, or the like of the portable device 100. The schedule management unit 412 is configured to manage schedules of the plurality of remote control devices 200 and the plurality of autonomous driving vehicles 300. The vehicle allocation plan creation unit 413 is configured to create a vehicle allocation plan for the reservation with reference to the reservation information stored in the reservation processing unit 411 and the schedule managed by the schedule management unit 412. These configurations and operations will be described later in detail (see FIG. 2).

  The remote person management equipment 420 provides information such as the use / use / working situation at the time of the current or near future dispatch, the reliability from the past to the present about each remote control device 200 or the remote operator in charge thereof. It is configured to perform information management of each remote operation device 200 and its remote operator, such as obtaining via a communication network, as necessary, regularly or irregularly, or when preparing a vehicle allocation plan. The vehicle information management facility 430 provides information about the current charging status, the use / use status at the time of current or near future dispatch, the parking position at the time of current or near future dispatch, etc. It is configured to perform vehicle information management, such as obtaining it via a communication network periodically or when preparing a vehicle allocation plan. The parking lot management facility 440 periodically or irregularly provides information on the parking lot such as a parking place or a waiting place where parking is possible at the end of the current or near future taxi for each autonomous driving vehicle 300. Alternatively, it is configured to execute information management of the parking lot, for example, through a communication network, as appropriate, when creating a vehicle allocation plan.

  Next, referring to the sequence chart of FIG. 2 in addition to FIG. 1, a series of processes including reservation processing, schedule management, vehicle allocation plan creation, etc. executed by the taxi service system configured as described above, This will be described together with further detailed configuration. In the sequence chart of FIG. 2, the locations where the processing is executed are arranged in order on the horizontal axis, and the processing executed sequentially from the upper side to the lower side is sequentially shown on the vertical axis according to the location of the horizontal axis. It is the chart which showed the process (for example, notification of the information to another place, control with respect to another place, etc.) which arranges and influences from one place to another place by the arrow extended in a horizontal direction. Further, the leftmost column shows a main process executed continuously from the upper side to the lower side as a single vertically extending flowchart (steps S10, S20,... S100).

  In FIG. 2, the horizontal axis shows a “customer” of an unmanned taxi who is a single user with the portable device 100, a “remote” who is a single remote operator who operates the remote control device 200, and one unit. The “car” that is the autonomous driving vehicle 300 and the “company” (or taxi company) where the management center 400 is arranged are arranged in order from the left.

In the initial state in FIG. 2, prior to actual taxi reservation, the following various information is grasped by the company as prior information or obtained information and registered in the control center 400. That is, for “customer”, its customer ID, CardNo (card number) that is the number of the ID card 102, its face or face photo, etc. are registered in the registration server 402 (see FIG. 1). As for “remote”, the remote person ID, its standby information, its face or face photo, etc. are registered in the remote person management equipment 420 (see FIG. 1). As for “car”, its vehicle ID, its parking location, usage status such as its charging state, etc. are registered in the vehicle information management facility 430 (see FIG. 1). The customer ID, remote person ID, and vehicle ID are issued in advance to the customer, remote person, and vehicle in this order from the company or the control center 400. For example, when a series of operations from a taxi reservation is started as follows, it is assumed that the customer is at home or at home, and the remote person is at a remote operation place where the remote control device 200 is arranged. Suppose the car is parked in a certain parking lot.

  In FIG. 2, first, when the operation of the taxi service system according to the present embodiment is started, acceptance of a reservation is started (step S10). At this time, the portable device 100 is used by the customer and a taxi is called via the unmanned taxi bulletin board 401 of the control center 400 (step S11). Specifically, with the mobile device 100, the customer ID, the time when the taxi wants to come (ie, the desired boarding time such as “Now” or “What time”, the time after what minutes or hours), Reservation information including information indicating a place where a taxi wants to come (that is, a desired boarding location), a destination (ie, a desired getting-off location), and the like is input and transmitted to the control center 400 via the Internet. In particular, when it is desired to come “immediately”, the GPS information acquired by the GPS device built in the portable device 100 is preferably transmitted as a part of the reservation information.

  Next, determination of an autonomous driving vehicle and a remote supervisor is performed (step S20). Here, the “remote monitor” is preferably the same person as the “remote operator” so that the automatic operation can be immediately switched to the remote operation in the event of an unexpected situation. However, when switching from automatic operation to remote operation, remote monitoring dedicated to remote operation without remote monitoring is performed separately from remote observer dedicated to remote monitoring that does not perform remote operation and is separately waiting during automatic driving or remote monitoring. It is also possible to operate the system in the presence of an operator. In addition, the remote monitoring can be executed semi-automatically or fully automatically by a remote monitor or a remote operator.

  Specifically, the determination in step S20 is a vehicle related to each autonomous driving vehicle 300 such as a charging state, a usage state, and a parking position, which is managed by the vehicle information management facility 430 by the unmanned taxi management system 410 in the company. Based on the information and the customer's request indicated by the reservation information that accepted the reservation, one of the most autonomous driving vehicles 300 registered is the most suitable for the customer to use. 300 is selected, and the selected vehicle is notified via the Internet (step S21). On the other hand, in the company, the remote person information management facility 410 managed by the remote person information management equipment 420, the remote person information related to each remote person such as the use state or working state of the remote person, reliability, and the reservation were accepted. Based on the customer's request indicated in the reservation information, one remote person most suitable for use with the customer is selected from the registered remote persons, and the selected remote person is selected. The selected remote control device 200 is notified of the selection via the Internet (step S22). Further, the unmanned taxi management system 410 estimates the travel time and the arrival time to the desired location of the passenger in the case of the determined vehicle and the remote person, and the estimated arrival time is determined for the customer. Notification is made via the Internet (step S23).

  Subsequently, the remote person notifies the company that he / she has approved the selection if he / she can perform the business after taking into account the expected remote monitoring time and the like. Specifically, approval information indicating approval is transmitted from the remote control device 200 to the control center 400 via the Internet. (Step S24). Here, if the approval is not obtained, the process from the remote person selection is repeated under the condition that the remote person is excluded. In preparation for the case where the approval is not obtained, the arrival time to the customer may be notified to the customer in step S23 after the approval in step S24 is obtained. If the arrival time is notified to the customer in step S23 before the approval in step S24 is obtained, there is an advantage that the customer can be notified that the vehicle can be dispatched more quickly.

  Subsequently, remote person information and customer information are communicated to the car. Specifically, remote person information managed by the remote person management facility 420 such as a remote person ID and a remote person's face photo is notified to the automatic driving vehicle 300 (step S25) and registered in the registration server 402 and the like. Customer information such as the customer's face, destination (desired destination), desired boarding date and time, desired location, etc. are delivered to the autonomous driving vehicle 300 (step S26). At the same time, the vehicle is authenticated by a remote person. Specifically, information such as a remote person's ID, a face photograph, etc. is obtained from the remote control device 200 at the remote person's origin for authentication that the remote monitoring operation of the approved taxi has been approved. 300 is notified (step S27). At that time, the remote person monitoring monitor 220 also transmits an image of a remote person sitting in the operation seat of the remote operation device 200, and comparison with the registration information is executed on the automatic driving vehicle 300 side.

  Notification of various information including personal information to the autonomous driving vehicle 300 in steps S25 to S27 via the Internet is preferably encrypted using an encryption key uniquely determined for each autonomous driving vehicle 300. It is done by information transmission.

  The processes from steps S10 to S20 described above are executed before the autonomous driving vehicle 300 actually used for taxi travels. The determination process of the autonomous driving vehicle and the remote supervisor in step S20 including the above steps S21 to S27 is an example of a vehicle allocation plan creation process for a certain reservation, which is executed by the vehicle allocation plan creation unit 413 of the unmanned taxi management system 410. The intermediate progress and final progress are appropriately reflected in the schedule managed by the schedule management unit 412.

  Subsequently, remote monitoring by the selected remote person is started (step S30), and automatic driving of the selected autonomous driving vehicle 300 toward the desired boarding place (ie, the destination here) is started. (Step S40). Specifically, remote monitoring by the remote operation device 200 is continuously executed by a remote person (step S41), and the automatic driving vehicle 300 is moved toward a passenger's desired boarding place by automatic driving (step S41). Step S42).

  Subsequently, the automatic driving vehicle 300 arrives at the desired boarding place indicated by the reservation information from the customer, which is the meeting place (step S50). Here, the customer gets on the vehicle and connects the ID card 102 to the self-driving vehicle 300 with information such as the customer ID, a photograph of the face, and a desired place to get off (that is, the destination here). Insert into Kid 311 and enter. In the self-driving vehicle 300, authentication is executed by comparing the information and reservation information of the customer previously notified in step S26 and the like based on the monitor information directly input from the customer in this way ( Step S51).

  When the authentication is completed, automatic driving in the autonomous driving vehicle 300 is executed (step S60). At this time, remote monitoring is continuously executed (step S61), and traveling toward the destination is continued (step S62).

  When arriving at the destination, the customer gets off (step S70). The self-driving vehicle 300 presents a billing amount to the customer about to get off, and the customer presses an approval button provided in the automatic clearing unit 312. The automatic clearing unit 312 executes clearing by debiting from a credit card linked to or not linked to the ID card 102 owned by the user, or clearing by cash (step S71). In any case, the ID card 102 inserted in the Card connection kid 311 is removed during traveling and the customer gets off. Subsequently, the autonomous driving vehicle 300 notifies the company control center 400 of the completion of taxi work via the communication network, and notifies the liquidation completion to the effect that the liquidation is completed. The latest vehicle information such as the above is notified (step S72). In response, the control center 400 of the company is based on the schedule managed by the schedule management unit 412 and the parking lot information managed by the parking lot management facility 440 for the autonomous driving vehicle 300 that has finished the taxi service. The location of the parking lot to be parked next is notified (step S73).

  Subsequently, the automatic driving vehicle 300 performs automatic driving again toward the notified parking lot (step S80). Specifically, remote monitoring by the remote person is continued after the passenger gets off (step S81), and the movement by the automatic driving is continued (step S82).

  Then, it arrives at the notified parking lot (step S90). At this time, the automatic driving vehicle 300 notifies the company control center 400 of the arrival (step S91). Thereby, a series of remote monitoring is completed (step S100). Specifically, the control center 400 notifies the remote person and the vehicle to end the remote monitoring at that time, and the remote person ends the remote monitoring in the remote operation device 200 (step S101). ).

  As described above, a series of taxi service processing using the autonomous driving vehicle 200 is completed. As described above, according to the present embodiment, the automatic driving state of the autonomous driving vehicle 300 can be remotely monitored (or redundantly monitored) by the remote operation device 200 via the monitor 201. In particular, during any automatic driving from the original standby location to the next standby location via taxi service, an unexpected situation such as a sensor failure or unexpected abnormality in the automatic operation vehicle 300 occurs. However, when the automatic driving function is hindered or automatic driving becomes impossible, the vehicle information displayed on the monitor 201 of the remote control device 200 is viewed (or viewed, etc.) via the communication network. However, the remote operator can perform driving by manual remote operation instead of automatic driving by the autonomous driving vehicle 300. Alternatively, in such a case, based on vehicle information acquired by the remote operation device 200, a semi-automatic or fully automatic operation function, which is constructed in the remote operation device 200, instead of remote operation by a remote operator's manual, is used. It is possible to perform driving by remote control.

  That is, even when automatic driving becomes impossible due to the occurrence of an unexpected situation, it is possible to reduce the possibility of the automatic driving vehicle 300 being unable to travel by so-called backup means, that is, remote operation instead of automatic driving. If remote monitoring is performed by the control center 400 or the remote control device 200 during the operation of the autonomous driving vehicle 300, it is possible to immediately determine whether or not a failure has occurred. Furthermore, when performing remote operation in the case of a failure found by remote monitoring, for example, as disclosed in the above-mentioned Patent Document 2, the handle 202, the accelerator 203, the brake 204, and the like provided in the remote operation device 200 are used. It is sufficient to perform remote operation with existing technology such as operation according to the situation where the autonomous driving vehicle 300 displayed on the monitor 201 is placed.

  Or, even in normal times when the automatic driving function of the autonomous driving vehicle 300 does not break down, the user is informed that “when automatic driving fails, it is possible to switch to remote operation and continue driving”. Since it can be known, it is possible to reduce anxiety given to the user and anxiety given to the user. That is, even if it does not become impossible to run actually or as a result, the occurrence of an unexpected situation occurs from the viewpoint of a user who is known to be capable of remote operation as a backup means as described above. The feeling of anxiety that it may or may not be able to run due to the vehicle will no longer be accompanied while riding a taxi or waiting for a taxi. No matter how much the autonomous driving technology has evolved, this advantage is deceived by this embodiment as long as the probability of not failing is less than 100% or unless the user believes it is 100%. Is much larger than the frequency and rate at which remote control is actually used.

  In addition, in the case of such an automatic driving vehicle 300, as long as the automatic driving function is normal, instead of driving by a taxi driver, it is necessary to travel by remote operation by a remote operator assigned to each taxi. Disappear. In other words, you can enjoy the benefits of personnel reduction by adopting automation technology as much as you can with automatic driving, and you can enjoy the benefits of personnel reduction by adopting automated technology in recent years, the benefits of automated driving or the benefits of unmanned taxis. Can be enjoyed extremely efficiently.

  As described above, according to the taxi service system of the present embodiment, a backup by remote control is established while enjoying the benefits of automation by automatic driving, and whether or not the vehicle can actually be run is determined. In addition, it is possible to give the user a greater sense of security due to the presence of the remote operation itself or the enhancement of the backup system.

  The present invention can be changed as appropriate without departing from the gist or concept of the invention which can be read from the claims and the entire specification, and a taxi service system using an autonomous driving vehicle with such a change is also applicable. It is included in the technical idea of the present invention.

DESCRIPTION OF SYMBOLS 100 Portable apparatus 200 Remote operation apparatus 201 Monitor 300 Self-driving vehicle 302 Remote operation equipment 303 Automatic operation equipment 320 Camera 400 Control center 410 Unmanned taxi management system 411 Reservation processing part 412 Schedule management part 413 Vehicle allocation plan preparation part

Claims (1)

A terminal device that is accommodated in a communication network and operated by a taxi user;
Self-driving vehicle used as a taxi that is accommodated in the communication network and can be driven automatically and can be driven by remote operation from a remote location via the communication network When,
A plurality of remote control devices housed in the communication network, each for executing the remote control;
It is accommodated in the communication network, and comprises a control center capable of communicating with each of the terminal device, the autonomous driving vehicle and the plurality of remote control devices via the communication network,
The control center
Reservation information input from the terminal device and indicating reservation information relating to the taxi is acquired via the communication network and stored;
A schedule management unit for managing a schedule of the autonomous driving vehicle and the plurality of remote control devices;
A vehicle allocation plan creation unit that creates a vehicle allocation plan for the reservation with reference to the stored reservation information and the managed schedule;
Each of the plurality of remote control devices includes vehicle information to be used for the remote control in the autonomous driving vehicle selected for each of them on at least one of the created dispatch plan and the managed schedule. , Having a monitor unit for obtaining and displaying via the communication network,
The self-driving vehicle arrives at the destination indicated by the reservation information after the user has boarded at the boarding place set based on at least one of the created dispatching plan and the managed schedule. A taxi service system using an autonomous driving vehicle, comprising: a clearing unit that performs clearing for the user.

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