WO2022189823A1 - 情報処理装置、及び情報処理方法 - Google Patents
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- WO2022189823A1 WO2022189823A1 PCT/IB2021/000177 IB2021000177W WO2022189823A1 WO 2022189823 A1 WO2022189823 A1 WO 2022189823A1 IB 2021000177 W IB2021000177 W IB 2021000177W WO 2022189823 A1 WO2022189823 A1 WO 2022189823A1
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- 230000010365 information processing Effects 0.000 title claims abstract description 41
- 238000003672 processing method Methods 0.000 title claims description 5
- 238000004891 communication Methods 0.000 claims abstract description 240
- 238000000034 method Methods 0.000 claims description 14
- 230000006870 function Effects 0.000 description 15
- 238000012545 processing Methods 0.000 description 10
- 238000010586 diagram Methods 0.000 description 8
- 238000012544 monitoring process Methods 0.000 description 4
- 101001093748 Homo sapiens Phosphatidylinositol N-acetylglucosaminyltransferase subunit P Proteins 0.000 description 2
- 230000005540 biological transmission Effects 0.000 description 2
- 238000004590 computer program Methods 0.000 description 2
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- 230000001413 cellular effect Effects 0.000 description 1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/06—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
- H04B7/0613—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission
- H04B7/0615—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission of weighted versions of same signal
- H04B7/0617—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission of weighted versions of same signal for beam forming
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- G—PHYSICS
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- G08G—TRAFFIC CONTROL SYSTEMS
- G08G1/00—Traffic control systems for road vehicles
- G08G1/16—Anti-collision systems
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- G08G1/163—Decentralised systems, e.g. inter-vehicle communication involving continuous checking
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- G—PHYSICS
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- G08G1/01—Detecting movement of traffic to be counted or controlled
- G08G1/0104—Measuring and analyzing of parameters relative to traffic conditions
- G08G1/0108—Measuring and analyzing of parameters relative to traffic conditions based on the source of data
- G08G1/0112—Measuring and analyzing of parameters relative to traffic conditions based on the source of data from the vehicle, e.g. floating car data [FCD]
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- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/06—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
- H04B7/0686—Hybrid systems, i.e. switching and simultaneous transmission
- H04B7/0695—Hybrid systems, i.e. switching and simultaneous transmission using beam selection
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- H—ELECTRICITY
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- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/08—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the receiving station
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- H04W4/30—Services specially adapted for particular environments, situations or purposes
- H04W4/40—Services specially adapted for particular environments, situations or purposes for vehicles, e.g. vehicle-to-pedestrians [V2P]
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- H04W4/02—Services making use of location information
- H04W4/029—Location-based management or tracking services
Definitions
- the present invention relates to an information processing device and an information processing method.
- Patent Document 1 discloses a communication device including a communication unit that performs inter-vehicle communication with a plurality of other vehicles existing in the vicinity of the own vehicle. This communication device further includes an acquisition unit that acquires information about a plurality of other vehicles, and a control unit that controls at least one of the directivity of the antenna unit based on the information acquired by the acquisition unit.
- Patent Document 1 controls the directivity of the antenna unit with respect to other vehicles detected by the radar device.
- the directivity of the antenna unit is not controlled for other vehicles until the radar device actually detects the other vehicle, even if the other vehicle affects the future running of the own vehicle. Therefore, there is a possibility that necessary information cannot be appropriately received.
- the present invention has been made in view of such problems, and its object is to provide an information processing device and an information processing device that can appropriately receive necessary information.
- An information processing apparatus includes a communication unit that performs data communication with a second mobile object existing around a first mobile object, and a controller 110 that controls data communication performed by the communication unit. , is equipped with The controller 110 identifies a target mobile body, which is a second mobile body whose communication quality with the first mobile body does not satisfy a predetermined standard, specifies a first future position where the first mobile body will travel in the future, Based on the relative positional relationship with the second future position where the body will run in the future, the directivity of the communication unit for wireless communication is controlled.
- FIG. 1 is a configuration diagram showing a communication network according to this embodiment.
- FIG. 2A is a diagram illustrating a normal mode of the communication unit;
- FIG. 2B is a diagram for explaining directivity modes of the communication unit.
- FIG. 3 is a flow chart showing the flow of processing for inter-vehicle communication in the communication network.
- FIG. 4 is a diagram illustrating a driving scene according to this embodiment.
- FIG. 5 is a diagram illustrating a target vehicle and directional beams.
- FIG. 6 is an explanatory diagram showing switching to the normal mode.
- FIG. 7 is a diagram for explaining driving scenes to which the present embodiment can be applied.
- FIG. 8 is an explanatory diagram showing roadside units and directional beams.
- a communication network according to the present embodiment will be described with reference to FIG.
- a communication network according to the present embodiment includes a vehicle A and a vehicle B.
- FIG. Vehicle A and vehicle B are examples of moving bodies (first moving body and second moving body). Vehicle A is the own vehicle, and vehicle B is another vehicle existing around the own vehicle. Although only one vehicle B is depicted in FIG. 1, a plurality of vehicles B may be used.
- Vehicles A and B may be vehicles with automated driving functions or vehicles without automated driving functions. Also, the vehicle A and the vehicle B may be vehicles capable of switching between automatic driving and manual driving. In this embodiment, the vehicle A and the vehicle B are described as vehicles having an automatic driving function.
- the communication network further includes a roadside device 300 and a base station 400.
- Vehicle A includes a communication unit 100 having a data communication function.
- Vehicle B includes a communication unit 200 having a data communication function.
- Each communication unit 100, 200 is composed of, for example, one or more antennas, a modem, an application processor, memory, and the like.
- the communication unit 100 and the communication unit 200 can communicate directly. Direct communication between the communication unit 100 and the communication unit 200 is hereinafter defined as direct communication. Direct communication may be expressed as vehicle-to-vehicle communication. In this embodiment, vehicle A and vehicle B can share a plurality of data such as vehicle information (vehicle A and vehicle B) through direct communication.
- the communication unit 100 and the communication unit 200 can also communicate with each other via the base station 400 and a network not shown (for example, a mobile phone network, etc.).
- Base station 400 is a fixed communication device that does not move, and is an access point that covers a network. Communication between the communication units 100 and 200 via the base station 400 and the network is defined as indirect communication as opposed to direct communication.
- Indirect communication Since direct communication does not go through the base station 400 and the network, it is possible to transmit data to the other party with low delay and a simple configuration. Indirect communication is used to transmit large amounts of data that cannot be transmitted by direct communication, or to transmit data that is repeatedly transmitted without changing information for a certain period of time. Indirect communication can also be used when direct communication is not possible.
- the individual communication units 100 and 200 can communicate with the roadside device 300.
- the roadside device 300 is, for example, a fixed communication device installed in road facilities on the shoulder of the road, and distributes distribution data including predetermined information to vehicles on the road.
- the roadside unit 300 is also called an RSU (roadside unit) or an ITS (intelligent transport systems) spot.
- the roadside device 300 shown in this embodiment corresponds to a transmitting station, and the communication units 100 and 200 correspond to receiving stations.
- the roadside device 300 and the communication units 100 and 200 perform downlink communication from the roadside device 300 to the communication units 100 and 200 .
- the roadside device 300 and the communication units 100 and 200 can also perform reverse uplink communication.
- the communication units 100 and 200 correspond to the transmitting station
- the roadside device 300 corresponds to the receiving station.
- Communication between the communication units 100 and 200 and the roadside device 300 is also called road-to-vehicle communication.
- the distribution data distributed from the roadside device 300 includes roadside device data indicating information on the roadside device 300 and traffic data indicating information on vehicles existing around the roadside device 300 .
- the information of the roadside device 300 includes position information of the roadside device 300 and the like.
- the vehicle information includes vehicle position information, speed information, traveling direction information, and the like.
- Vehicle A includes the communication unit 100, the GPS receiver 101, the map information acquisition unit 102, and the controller 110 described above.
- the communication unit 100, the GPS receiver 101, the map information acquisition unit 102, and the controller 110 constitute an information processing device that realizes the vehicle-to-vehicle communication shown in this embodiment.
- the GPS receiver 101 detects the location information of vehicle A on the ground by receiving radio waves from satellites.
- the position information of the vehicle A detected by the GPS receiver 101 includes latitude information, longitude information, and time information.
- the GPS receiver 101 outputs the detected position information of the vehicle A to the controller 110 .
- the method of detecting the position information of vehicle A is not limited to the GPS receiver 101 .
- a method called odometry may be used to estimate position.
- Odometry is a method of estimating the position of vehicle A by obtaining the amount and direction of movement of vehicle A according to the rotation angle and rotation angular velocity of vehicle A.
- FIG. GPS Global Positioning System
- GNSS Global Navigation Satellite System
- the map information acquisition unit 102 acquires map information indicating the structure of the road on which vehicle A travels.
- the map information acquisition unit 102 may own a map database that stores map information, or may acquire map information from an external map data server by cloud computing.
- the map information acquisition part 102 may acquire map information using vehicle-to-vehicle communication and road-to-vehicle communication.
- Map information includes node types that indicate intersections and branch points, node information that includes node positions, link types that are road sections that connect nodes, link lengths, the number of lanes, curvature, slopes, and other links. Contains information.
- the link information also includes road structure information such as the absolute position of lanes and the connection relationship between lanes.
- map information includes information such as traffic rules and road signs.
- the controller 110 is composed of, for example, a microcomputer.
- the controller 110 has, for example, a hardware processor such as a CPU (Central Processing Unit), a memory, and various interfaces.
- the memory and various interfaces are connected to the hardware processor via buses.
- a computer program is installed on the microcomputer to function as an information processing device.
- the microcomputer functions as a plurality of information processing circuits included in the information processing device.
- the controller 110 includes a communication control section 111 as an example of a plurality of information processing circuits.
- the communication control unit 111 controls wireless communication (data communication) performed by the communication unit 100 .
- the communication control unit 111 switches the operation mode of the communication unit 100, controls beams formed by the communication unit 100, and the like.
- the communication unit 100 has a normal mode and a directional mode as switchable operation modes. Operation modes of the communication unit 100 will be described with reference to FIGS. 2A and 2B.
- the normal mode is a mode in which wireless communication is performed within a preset range (area) without controlling the directivity of the communication unit 100 regarding wireless communication.
- the communication unit 100 specifically the antenna of the communication unit 100, forms a normal beam Bn over a predetermined range (area).
- the normal beam Bn is, for example, a beam that is evenly formed in all directions and does not have directivity in a specific direction.
- the normal beam Bn is formed in a circular range centered on the communication unit 100 and having a radius of a predetermined distance.
- the predetermined range formed by the normal beam Bn may be a circular range having a radius of a predetermined distance. It may be set to a predetermined range.
- the antenna of the communication unit 100 forms the normal beam Bn over a preset range.
- Vehicle A can communicate with vehicle B existing in the area where beam Bn is normally formed.
- An area in which communication can be performed with the communication unit 100 operating in the normal mode is called a normal communication area.
- the normal communication area basically corresponds to the area in which the normal beam Bn is formed.
- the normal communication area refers to an area in which communication with the vehicle B can be performed with communication quality equal to or higher than a certain level, and does not necessarily match the area (predetermined range) in which the normal beam Bn is formed.
- the directivity mode is a mode in which the directivity of the communication unit 100 regarding wireless communication can be controlled.
- directivity related to wireless communication is simply referred to as “directivity”.
- the antenna of communication unit 100 forms a directional beam Bd.
- the directional beam Bd is a beam formed toward a specific azimuth and has directivity with respect to the specific azimuth. Azimuth corresponds to the horizontal component of direction.
- the directional beam Bd is formed as a beam having a predetermined beam width Bd2 around a beam axis Bd1 having a predetermined azimuth angle.
- the azimuth angle of the beam axis Bd1 and the beam width Bd2 can be adjusted, respectively, so that the directivity of the communication unit 100 can be adjusted.
- the directional mode corresponds to an operation mode in which the antenna of communication unit 100 has directivity.
- Vehicle A can communicate with vehicle B existing in the area where the directional beam Bd is formed.
- the directional beam Bd is formed long in the direction along the beam axis Bd1, and its distance (axial distance) is generally longer than the radial distance of the beam Bn.
- the reception intensity in communication using the directional beam Bd is relatively higher than the reception intensity in communication using the normal beam Bn. Therefore, by using the directional beam Bd, it is possible to communicate with the vehicle B outside the normal communication area.
- the directional beam Bd is a beam that can perform data communication with the vehicle B that is located at a position where data communication cannot be performed with the normal beam Bn. That is, the directivity mode is a mode in which data communication can be performed with the vehicle B located at a position where data communication cannot be performed in the normal mode by controlling the directivity compared to the normal mode.
- Control of the directional beam Bd includes beamforming that adjusts the azimuth angle of the beam axis Bd1 and the beam width Bd2.
- the communication control unit 111 controls the directivity of the communication unit 100, that is, the directivity of the beam formed by the antenna of the communication unit 100 by beamforming.
- the communication unit 100 broadcasts the vehicle A position data including the current position information of the vehicle A, travel plan information, etc. to the surroundings of the vehicle A.
- a direct communication method is used for broadcast transmission.
- the direct communication system is, for example, the DSRC system (frequency: 5.9 GHz band) conforming to IEEE 802.11p, or the cellular V2X system conforming to the specifications of 3GPP Release 14 or later.
- the current position information is data that associates the latitude and longitude indicating the current position of vehicle A with the time when the position was obtained.
- the travel plan information is travel plan data including vehicle speed plan data in which the vehicle speed is associated with the future position where the vehicle A will travel in the future, and future travel route data.
- the future travel route data includes information on the route that the vehicle A will travel in the future.
- the future travel route data may be route information of a road on which the vehicle travels to a preset destination, or data in which a future position (latitude, longitude) and a scheduled passage time are associated based on vehicle speed plan data. good too.
- the travel plan information is data obtained by adding vehicle speed plan data to data conforming to SAE2735 (Dedicated Short Range Communications (DSRC) Message Set Dictionary) messages.
- SAE2735 Dedicated Short Range Communications (DSRC) Message Set Dictionary
- Table 1 shows an example of vehicle A position data that is broadcast.
- Vehicle A location data is package data including header and content data.
- the header of the vehicle A location data contains the identification number of the vehicle A, which is the transmission source, and identification information indicating the type of content included in the content data (for example, current location information, travel plan information, etc.). etc.) is stored.
- the content data stores current location information, which is data that associates latitude and longitude with the time when the location information was acquired, and travel plan information.
- Vehicle A position data which is package data including a header and content data, is generated by the communication control unit 111 based on data acquired from the GPS receiver 101 or the like and data prerecorded in the memory provided in the controller 110 . Vehicle A position data is transmitted from communication unit 100 and received by communication unit 200 of vehicle B.
- the communication unit 100 receives vehicle B position data transmitted from the communication unit 200 of vehicle B, and outputs the received vehicle B position data to the communication control unit 111 .
- the communication control unit 111 acquires vehicle B position data from the communication unit 100 .
- the fact that the communication unit 100 has received the vehicle B position data means that direct communication has been established between the vehicle A and the vehicle B.
- the communication control unit 111 uses the data processing function to specify future positions where vehicles A and B will travel in the future. Then, the communication control unit 111 controls the directivity of the communication unit 100 based on the relative positional relationship between the future position of the vehicle A and the future position of the vehicle B. FIG.
- vehicle B includes the communication unit 200, the GPS receiver 201, the map information acquisition unit 202, and the controller 210 described above.
- the communication unit 200, the GPS receiver 201, the map information acquisition unit 202, and the controller 210 constitute an information processing device that realizes the vehicle-to-vehicle communication shown in this embodiment.
- the functions of the GPS receiver 201 and the map information acquisition unit 202 are the same as the functions of the GPS receiver 101 and the map information acquisition unit 102.
- the controller 210 is composed of a microcomputer equipped with a hardware processor, memory, and various interfaces.
- the controller 210 includes a communication control section 211 as an example of a plurality of information processing circuits.
- the function of the communication control unit 211 is the same as that of the communication control unit 111, and includes a function of controlling wireless communication performed by the communication unit 100, and various processes necessary for performing wireless communication such as generation of vehicle B position data. It has a data processing function to
- the processing shown in the flowchart of FIG. 3 is executed by the controller 110 of the own vehicle A (corresponding to the vehicle A in FIG. 1).
- the operation mode of the communication unit 100 is initially set to the normal mode. Also, in the following description, it is assumed that the vehicle travels through an intersection as shown in FIG. Self-vehicle A is traveling on a road connected to an intersection indicated by node N1.
- the current position of the own vehicle A is a position (Xa, Xb) a first distance before the intersection. It is assumed that the route on which the vehicle A will travel in the future is a route that turns left at an intersection.
- three other vehicles B1, B2, and B3 are traveling on an intersecting road passing through the intersection indicated by node N1.
- the current position of the other vehicle B1 is the position (Xb1, Yb1) after passing through the intersection.
- the current position of the other vehicle B2 is the second distance before the intersection (Xb2, Yb2)
- the current position of the other vehicle B3 is the second distance before the intersection (Xb3, Yb3).
- the second distance is less than the third distance
- the third distance is substantially the same as the first distance. It is assumed that the routes on which the other vehicles B1, B2, and B3 will travel in the future are routes that go straight through the crossroads.
- the controller 110 identifies the future position where the vehicle A will travel in the future (S10).
- the controller 110 acquires, for example, vehicle speed plan data included in the vehicle A position data, and identifies the future position from this vehicle speed plan data.
- the controller 110 may acquire future travel route data included in the vehicle A position data and identify the future position based on the future travel route.
- the controller 110 determines whether or not the driving scene of the vehicle A is in a situation that requires caution.
- a situation to watch out for is the scene of driving through an intersection, as shown in FIG.
- the controller 110 refers to map information acquired by the map information acquisition unit 102 . If the future position of the vehicle A corresponds to an intersection, or if the intersection is included in the future travel route of the vehicle A, the controller 110 determines that the driving scene of the vehicle A is in a situation requiring attention. (Yes in S12).
- the controller 110 switches the operation mode of the communication unit 100 from normal mode to directional mode.
- the controller 110 sweeps the directional beam Bd in the azimuth direction to scan a required range (S14).
- the range scanned by the directional beam Bd is centered on the current position and future position of the vehicle A.
- the directional beam Bd scans the front of the vehicle on the road connected to the intersection, the intersection, and the cross road passing through the intersection.
- there are other vehicles B1, B2, and B3 having routes passing through intersections included in the future route of the host vehicle A.
- the controller 110 acquires other vehicle B position data from each of the other vehicles B1, B2, and B3 (S16).
- the controller 110 identifies the target vehicle (S18). Specifically, when communication unit 100 receives a signal (other vehicle B position data), controller 110 detects the reception strength of the signal.
- the reception strength is a parameter for evaluating communication quality with other vehicles B1, B2, B3.
- the reception strength (dBm) is represented by a negative value of 0 or less, and the worse the communication quality, the smaller the value (increases on the negative side).
- the controller 110 identifies, as target vehicles, other vehicles whose reception strength is smaller than a predetermined reference value. That is, the controller 110 will specify the other vehicle whose communication quality does not satisfy the predetermined standard as the target vehicle.
- the controller estimates the amount of attenuation of the reception intensity based on the distances between the own vehicle A and the other vehicles B1, B2, and B3, and based on the estimated amount of attenuation, the communication quality does not satisfy a predetermined standard. Other vehicles may be judged. Also, evaluation of communication quality is not limited to reception strength, and may be performed by focusing on other factors.
- the controller 110 performs the following processing, and narrows down the target vehicle among the other vehicles B1, B2, and B3 whose communication quality does not satisfy a predetermined standard.
- the controller 110 identifies the future positions of the other vehicles B1, B2, and B3 from the vehicle speed plan data included in the other vehicle B position data. Alternatively, the controller 110 acquires future travel route data included in the other vehicle B position data, and identifies the future position based on the future travel route.
- the controller 110 determines whether the vehicle A will intersect with the other vehicles B1, B2, and B3 in the future. to judge. Specifically, the controller 110 determines that the future position of the vehicle A and the future positions of the other vehicles B1, B2, and B3 at the same time in the future match or are within a certain range. It is determined that A and other vehicles B1, B2, and B3 will intersect in the future. In the example shown in FIG. 4, the distance from the host vehicle A to the intersection and the distance from the other vehicle B3 to the intersection generally match.
- the controller 110 determines that the own vehicle A and the other vehicle B3 will intersect.
- the other vehicles B1 and B2 do not have the above relationship with the own vehicle A, so they judge that they will not intersect with the own vehicle A.
- the controller 110 determines that the vehicle B3 has the highest priority among the three other vehicles B1, B2, and B3. As a result, the controller 110 determines the other vehicle B3 with the highest priority as the final target vehicle.
- the method for judging future intersection may be a method other than comparing future positions.
- the controller 110 may determine future crossing by comparing travel route data representing routes to be traveled in the future.
- the controller 110 may determine future crossing based on the current position information of the other vehicles B1, B2, and B3. For example, if the difference between the distance from the current position of the host vehicle A to the intersection and the distance from the current position of the other vehicles B1, B2, and B3 to the intersection is equal to or less than a reference value, the controller 110 determines that the two vehicles do not intersect. Then judge.
- the controller 110 can identify the speeds of the other vehicles B1, B2, and B3 from changes in the current positions of the other vehicles B1, B2, and B3. Thereby, the controller 110 can obtain the relative velocities of the other vehicles B1, B2, and B3 with respect to the own vehicle A.
- the controller 110 may determine that the other vehicles B1, B2, and B3 intersect when the relative speeds of the other vehicles B1, B2, and B3 with respect to the own vehicle A are smaller than a predetermined determination value (for example, zero).
- the controller 110 predicts the future travel routes of the other vehicles B1, B2 and B3 based on the current positions of the other vehicles B1, B2 and B3, the speeds of the other vehicles B1, B2 and B3, and the map information.
- the controller 110 may compare the future travel route of the host vehicle A with the future travel routes of the other vehicles B1, B2, and B3 to determine whether they intersect.
- the controller 110 may use these techniques alone or in combination to compositely determine future intersections. As a result, the controller 110 can specify the other vehicle B3, which has the highest priority among the other vehicles B1, B2, and B3 having a route passing through the intersection included in the future route of the own vehicle A, as the target vehicle. .
- the controller 110 starts angle control of the directional beam Bd (S20). As shown in FIG. 5, the controller 110 controls the directional beam Bd so that the directional beam Bd is directed toward another vehicle B3, which is the target vehicle. That is, the controller 110 adjusts the beam axis Bd1 of the directional beam Bd to a predetermined azimuth angle.
- the azimuth angle at which the beam axis Bd1 should be directed is specified by calculating the azimuth angle when the other vehicle B3 is observed from the own vehicle A based on the current position of the own vehicle A and the current position of the other vehicle B3. can be done.
- the directional beam Bd is adjusted to face the current position of the other vehicle B3.
- the controller 110 controls the directional beam Bd so as to follow the moving other vehicle B3.
- the current position of the other vehicle B3 is continuously identified using data communication with the other vehicle B3, and the azimuth angle of the directional beam Bd is controlled based on the latest current position. method.
- the controller 110 may feedback-control the azimuth angle of the directional beam Bd so as to search for the point where the reception intensity is maximum.
- the controller 110 starts data communication with the other vehicle B3 (S22).
- the controller 110 monitors the other vehicle B3 (S24). Monitoring of the other vehicle B3 includes monitoring of reception intensity and monitoring of the current position of the other vehicle B3.
- the controller 110 determines whether or not the other vehicle B3 satisfies the conditions for communication even with the normal beam Bn. Specifically, when the reception intensity rises to a certain level, or when the current position of the other vehicle B3 exists within the area of the normal beam Bn, the controller 110 determines that the above conditions are satisfied ( Yes in S26), the operation mode of the communication unit 100 is switched to the normal mode (S28). On the other hand, when the controller 110 determines that the conditions are not satisfied, the controller 110 continues monitoring the other vehicle B3 (S24).
- the controller 110 of the information processing device controls the directivity of the communication unit 100 based on the relative positional relationship between the future position of the own vehicle and the future position of the other vehicle.
- the controller 110 of the information processing device controls the directivity of the communication unit 100 based on the relative positional relationship between the future position of the own vehicle and the future position of the other vehicle.
- the directivity of the communication unit can be controlled toward the target of communication. As a result, data communication with the communication target can be performed satisfactorily, and necessary information can be appropriately received.
- the controller 110 of the information processing device identifies the future positions of the own vehicle and other vehicles from the future route data of the own vehicle and other vehicles. Since the route to be traveled in the future can be considered, the future position can be specified with high accuracy. As a result, it is possible to appropriately grasp other vehicles that may affect the future running of the own vehicle.
- another vehicle having a route passing through an intersection included in the future route of the own vehicle is exemplified as the target vehicle.
- This other vehicle is highly likely to affect the future running of the own vehicle, so it is preferable to treat it as a target vehicle. As a result, it is possible to appropriately grasp other vehicles that may affect the future running of the own vehicle.
- the controller 110 of the information processing device determines whether or not the own vehicle and the target vehicle will intersect in the future, and controls the directivity of the communication unit 100 based on the determination result.
- the target vehicle has a great influence on the future running of the own vehicle. By judging the crossing, it is possible to appropriately grasp other vehicles that may affect the future running of the own vehicle.
- the controller 110 of the information processing device controls the directivity of the communication unit 100 toward the target vehicle determined to cross. Since the self-vehicle can reliably perform data communication with other vehicles that will intersect in the future, it can appropriately receive necessary information.
- the crossing of the own vehicle and the target vehicle can be evaluated from the relative speed of the target vehicle with respect to the own vehicle. Therefore, by taking into consideration the relative speed of the target vehicle with respect to the own vehicle, it is possible to appropriately determine the crossing.
- the controller can determine that the host vehicle and the target vehicle will intersect on condition that the relative speed is smaller than a predetermined determination value.
- the communication unit 100 can adjust the directivity of the communication unit 100 by forming a beam having directivity. Thereby, the directivity of the communication unit 100 can be appropriately controlled.
- the communication unit 100 When the communication unit 100 operates in a normal mode without directivity, it may not be possible to perform good data communication with a communication target from which desired information on other vehicles can be obtained. However, by switching the operation mode of the communication unit 100 to the directivity mode, the directivity of the communication unit 100 can be controlled with respect to the desired communication target. As a result, data communication with the communication target can be performed satisfactorily, and necessary information can be appropriately received.
- the controller 110 of the information processing device acquires the future travel route of the target vehicle by scanning the surroundings of the own vehicle and performing data communication with the target vehicle. As a result, the route that the target vehicle will travel in the future can be grasped, so the future position of the target vehicle can be specified with high accuracy.
- the scene of driving through an intersection was exemplified as a situation to be aware of.
- the situation to be careful of is a scene in which there is another vehicle that may affect the future travel of the own vehicle, such as when the own vehicle and another vehicle intersect.
- it may be a scene in which the own vehicle A traveling in the driving lane La changes lanes to the overtaking lane Lb.
- the other vehicle B traveling in the overtaking lane Lb may cross with the own vehicle A, so there is a high possibility that it will affect future travel. Therefore, in the lane change scene, the other vehicle B, which has a route that runs in the overtaking lane Lb of the road on which the vehicle A is running, is specified as the target vehicle.
- the scene in which overtaking is performed may be a situation in which overtaking is performed using the oncoming lane instead of using the passing lane.
- the controller 110 determines that the own vehicle will overtake, it is preferable to perform processing to identify the target vehicle. For example, the controller 110 determines that the own vehicle will overtake when an operation signal permitting overtaking by a passenger is detected. Alternatively, based on the map information and the data of the preceding vehicle, the controller 110, on the condition that there is an obstacle ahead of the own vehicle in the driving lane or the presence of a preceding vehicle that is slower than the own vehicle, It may be determined autonomously that the host vehicle will overtake. In this way, when the host vehicle overtakes, the target vehicle can be specified at an appropriate timing by performing processing for specifying the target vehicle with the overtaking of the host vehicle as a trigger.
- situations that require attention are not limited to specific driving scenes.
- the other vehicles may affect the future running of the own vehicle.
- the controller 110 sweep-controls the directional beam Bd to scan the entire surroundings of the host vehicle, thereby determining whether or not there is another vehicle located outside the normal communication area. As a result, it is possible to appropriately grasp other vehicles that may affect the future running of the own vehicle.
- the controller 110 controls the directional beam Bd so that the directional beam Bd is directed toward the target vehicle.
- the gist of the subject vehicle communicating with the subject vehicle is to acquire information about the subject vehicle that intersects with the subject vehicle.
- inter-vehicle communication with the target vehicle may not be possible depending on the communication environment, such as when there is an obstacle between the target vehicle and the vehicle. be.
- the controller 110 may control the directional beam Bd toward the roadside device 300 .
- the roadside device 300 transmits distribution data including information about the target vehicle by analyzing the distribution data. It is possible to determine whether Further, it is possible to acquire the position information of the roadside device 300 to which the directional beam Bd should be directed from the distributed data.
- the controller 110 may control the directivity of the communication unit 100 toward the roadside device 300 that transmits distribution data containing information about the target vehicle determined to cross.
- the controller 110 may treat the roadside device 300 that transmits distribution data including information about the target vehicle as the target vehicle.
- the directivity of the communication unit 100 is controlled based on the relative positional relationship between the future position of the host vehicle and the future position of the other vehicle, similar to the information processing apparatus. be able to.
- the relative positional relationship it is possible to grasp the other vehicle (second moving body) that will affect the future running of the own vehicle (first moving body).
- the directivity of the communication unit can be controlled toward the target of communication. As a result, data communication with the communication target can be performed satisfactorily, and necessary information can be appropriately received.
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- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Chemical & Material Sciences (AREA)
- Analytical Chemistry (AREA)
- Traffic Control Systems (AREA)
- Mobile Radio Communication Systems (AREA)
Abstract
Description
100 通信部
101 GPS受信機
102 地図情報取得部
110 コントローラ
111 通信制御部
B 車両、他車両(第2移動体、情報処理装置)
200 通信部
201 GPS受信機
202 地図情報取得部
210 コントローラ
211 通信制御部
300 路側機
400 基地局
Claims (13)
- 第1移動体に搭載され、前記第1移動体の周囲に存在する第2移動体との間でデータ通信を行う通信部と、
前記通信部によって行われるデータ通信を制御するコントローラと、を備え、
前記コントローラは、
前記第1移動体との間の通信品質が所定の基準を満たさない前記第2移動体である対象移動体を特定し、
前記第1移動体が将来走行する第1将来位置を特定し、
前記対象移動体が将来走行する第2将来位置を特定し、
前記第1将来位置と前記第2将来位置との相対位置関係に基づいて、前記通信部の無線通信に関する指向性を制御する
情報処理装置。 - 前記コントローラは、
前記第1移動体が将来走行する経路を含む第1将来経路データを取得し、前記第1将来経路データに基づいて前記第1将来位置を特定し、
前記第2移動体が将来走行する経路を含む第2将来経路データを取得し、前記第2将来経路データに基づいて前記第2将来位置を特定する
請求項1記載の情報処理装置。 - 前記対象移動体は、
前記通信部の通常通信エリアの外に位置する前記第2移動体、
前記第1移動体が走行する道路の追い越し車線を走行する経路を有する前記第2移動体、又は
前記第1移動体が将来走行する経路に含まれる交差点を通過する経路を有する前記第2移動体である
請求項2記載の情報処理装置。 - 前記コントローラは、
前記相対位置関係に基づいて、前記第1移動体と前記対象移動体とが将来交錯するか否かを判断し、
交錯の判断結果に基づいて、前記通信部の無線通信に関する指向性を制御する
請求項1から3いずれか一項記載の情報処理装置。 - 前記コントローラは、
前記第1移動体と交錯すると判断された前記対象移動体に向けて、前記通信部の無線通信に関する指向性を制御する
請求項4記載の情報処理装置。 - 前記コントローラは、
前記第1移動体に対する前記対象移動体の相対速度に基づいて、前記第1移動体と前記対象移動体とが将来交錯するか否かを判断する
請求項4又は5記載の情報処理装置。 - 前記コントローラは、
前記第1移動体に対する前記対象移動体の相対速度が所定の判定値よりも小さい場合に、前記第1移動体と前記対象移動体とが将来交錯すると判断する
請求項6記載の情報処理装置。 - 前記コントローラは、
前記第1移動体が追い越しを行うか否かを判定し、
前記第1移動体が追い越しを行うと判定した場合に、前記対象移動体を特定する処理を行う
請求項1から4いずれか一項記載の情報処理装置。 - 前記通信部は、
指向性を有するビームを形成することで、前記通信部の無線通信に関する指向性を調整可能であり、
前記コントローラは、
前記通信部によって形成されるビームの指向性を制御することで、前記通信部の無線通信に関する指向性を制御する
請求項1から8いずれか一項記載の情報処理装置。 - 前記通信部は、
切り替え可能な動作モードとして、無線通信に関する指向性を制御することができる指向性モードと、無線通信に関する指向性を制御せずに予め設定されたエリアに対して無線通信を行う通常モードとを有し、
通常通信エリアは、前記通常モードで動作する前記通信部とデータ通信を行うことができるエリアである
請求項3記載の情報処理装置。 - 前記通信部は、
切り替え可能な動作モードとして、無線通信に関する指向性を制御することができる指向性モードと、無線通信に関する指向性を制御しない通常モードとを有し、
前記コントローラは、
前記通信部の動作モードを前記通常モードから前記指向性モードに切り替えた後、前記通信部の無線通信に関する指向性を制御して前記第1移動体の周囲をスキャンすることにより、前記対象移動体を特定する
請求項1から9いずれか一項記載の情報処理装置。 - 前記通信部は、前記第1移動体が走行する道路周辺に設けられた路側機とデータ通信が可能であり、
前記コントローラは、
前記交錯すると判断された前記対象移動体に関する情報を含む配信データを送信する前記路側機に向けて、前記通信部の無線通信に関する指向性を制御する
請求項4記載の情報処理装置。 - 第1移動体に搭載され、第2移動体を含む通信対象との間でデータ通信を行う通信部と、
前記通信部によって行われるデータ通信を制御するコントローラと、を備える情報処理装置の情報処理方法において、
前記第1移動体との間の通信品質が所定の基準を満たさない前記第2移動体である対象移動体を特定し、
前記第1移動体が将来走行する第1将来位置を特定し、
前記対象移動体が将来走行する第2将来位置を特定し、
前記第1将来位置と前記第2将来位置との相対位置関係に基づいて、前記通信部の無線通信に関する指向性を制御する
情報処理方法。
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