JP6610422B2 - Driving assistance device - Google Patents

Driving assistance device Download PDF

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JP6610422B2
JP6610422B2 JP2016097977A JP2016097977A JP6610422B2 JP 6610422 B2 JP6610422 B2 JP 6610422B2 JP 2016097977 A JP2016097977 A JP 2016097977A JP 2016097977 A JP2016097977 A JP 2016097977A JP 6610422 B2 JP6610422 B2 JP 6610422B2
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宏之 川島
正信 鈴木
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Denso Corp
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Description

本発明は、車両の運転を支援する運転支援装置に関する。   The present invention relates to a driving support device that supports driving of a vehicle.

従来、車両が合流道路(例えば支線)から被合流道路(例えば本線)に合流する際に、被合流道路を走行中の車両との衝突を抑制するための技術が種々提案されている。例えば、特許文献1に記載のように、合流道路と被合流道路との合流地点に向かう車両が自動運転車両であるか否かなどを路側システムによって検出し、合流地点を先に通過できる優先順位を各車両に対して設定する技術が提案されている。   Conventionally, various techniques for suppressing a collision with a vehicle traveling on a merged road when the vehicle merges from a merged road (for example, a branch line) to a merged road (for example, main line) have been proposed. For example, as described in Patent Document 1, a priority order that allows a roadside system to detect whether or not a vehicle heading for a merged point between a merged road and a merged road is an autonomous driving vehicle, and can pass through the merged point first. A technique for setting the value for each vehicle has been proposed.

特開2015−102893号公報JP2015-102893A

ところが、特許文献1に記載のような路側システムにおける各種センサ類は、合流地点の近くに設けられる場合が多く、合流地点から離れた地点を走行中の車両に係る情報は処理に反映されない。もちろん、各種センサ類を合流道路及び被合流道路沿いに一定間隔で延々と設けたり、各種センサ類の解像度又は出力を大幅に増強すれば、合流地点から離れた地点を走行中の車両に係る情報も処理に反映可能となるが、コストがかかり現実的ではない。   However, the various sensors in the roadside system as described in Patent Document 1 are often provided near the joining point, and information relating to a vehicle traveling at a point away from the joining point is not reflected in the processing. Of course, if various sensors are provided at regular intervals along the merging road and the merging road, or if the resolution or output of the various sensors is greatly increased, information related to vehicles traveling at a point away from the merging point Can also be reflected in the processing, but it is expensive and not practical.

本発明は、こうした問題にかんがみてなされたものであり、合流道路における被合流道路との合流地点から離れた地点を走行中の車両においても、どの車両の前方に合流すべきか(すなわち、被合流道路においてどの車両の前方を走行すべきか)を容易に判断可能とする技術を提供することを目的としている。   The present invention has been made in view of such a problem, and even in a vehicle that is traveling on a merging road away from a merging point with a merged road, which vehicle should be merged in front (that is, the merged merged road) It is an object of the present invention to provide a technology that makes it easy to determine which vehicle on a road to travel ahead.

本発明の運転支援装置は、運転支援部(15,S20)と通信部(16,17,20)と、範囲取得部と(15,S6)、車両設定部(15,S14)と、を備える。
合流地点にて合流する2つの道路のうち、前記合流地点にて車線がなくなる道路を合流道路として、前記合流地点にて車線がなくならない道路を被合流道路として、運転支援部は、制御対象としての対象車両が合流道路を走行しているときに当該対象車両における目標走行速度を算出する処理を実行する。通信部は、前記被合流道路を走行する車両と通信を行う。
The driving support device of the present invention includes a driving support unit (15, S20), a communication unit (16, 17, 20), a range acquisition unit (15, S6), and a vehicle setting unit (15, S14). .
Of the two roads that merge at the merge point, the road that does not have a lane at the merge point is defined as a merge road, the road that does not have a lane at the merge point is defined as a merged road, and the driving support unit is controlled. When the target vehicle is traveling on the junction road, processing for calculating the target travel speed of the target vehicle is executed. The communication unit communicates with a vehicle traveling on the merged road.

範囲取得部は、前記被合流道路を走行する車両のうち、前記対象車両と同時に前記合流地点に到達する可能性のある車両を検出するための検出範囲を取得する。車両設定部は、前記範囲取得部が取得した検出範囲に、前記通信部が通信可能な車両が存在する場合、当該通信可能な車両のうちの少なくとも1台を、当該車両の前方に前記対象車両が合流すべき被合流車両として設定する。前記運転支援部は、前記被合流車両が設定されたとき、当該被合流車両の前方に前記対象車両を合流させるための前記目標走行速度を算出する。   A range acquisition part acquires the detection range for detecting the vehicle which may reach | attain the said confluence | merging point simultaneously with the said object vehicle among the vehicles which drive | work the said to-be-merged road. When there is a vehicle communicable by the communication unit in the detection range acquired by the range acquisition unit, the vehicle setting unit sets at least one of the communicable vehicles to the target vehicle in front of the vehicle. Is set as a merged vehicle to be merged. When the joined vehicle is set, the driving support unit calculates the target travel speed for joining the target vehicle in front of the joined vehicle.

このように、範囲取得部は、対象車両と同時に合流地点に到達する可能性のある車両を検出するための検出範囲を取得し、車両設定部は、その検出範囲における前記通信可能な車両を、被合流車両として設定する。従って、対象車両が合流道路における被合流道路との合流地点から離れた地点を走行中であっても、適切な位置に前記検出範囲が設定されることにより、車両設定部は被合流車両を容易に設定することができる。被合流車両とは、その車両の前方に対象車両が合流すべき車両である。適切な位置とは、検出範囲が、対象車両の合流に影響する可能性があるとみなされる車両を含み、かつ、対象車両の合流に影響しないとみなされる車両を含まない位置である。よって、対象車両がどの車両の前方に合流すべきかが、容易に判断可能となる。   In this way, the range acquisition unit acquires a detection range for detecting a vehicle that may reach the junction at the same time as the target vehicle, and the vehicle setting unit selects the communicable vehicle in the detection range, Set as merged vehicle. Therefore, even if the target vehicle is traveling at a point on the merging road that is away from the merging point with the merging road, the vehicle setting unit easily sets the merging vehicle by setting the detection range at an appropriate position. Can be set to A joined vehicle is a vehicle to which a target vehicle should join in front of the vehicle. An appropriate position is a position whose detection range includes vehicles that are considered to possibly affect the merging of target vehicles and does not include vehicles that are considered not to affect the merging of target vehicles. Therefore, it can be easily determined which vehicle the target vehicle should join in front of.

なお、この欄及び特許請求の範囲に記載した括弧内の符号は、一つの態様として後述する実施形態に記載の具体的手段との対応関係を示すものであって、本発明の技術的範囲を限定するものではない。   In addition, the code | symbol in the parenthesis described in this column and a claim shows the correspondence with the specific means as described in embodiment mentioned later as one aspect, Comprising: The technical scope of this invention is shown. It is not limited.

第1実施形態の運転支援装置の構成を示すブロック図である。It is a block diagram which shows the structure of the driving assistance device of 1st Embodiment. その運転支援装置における合流処理を示すフローチャートである。It is a flowchart which shows the confluence | merging process in the driving assistance device. その合流処理における検出範囲の変化の一例を示す説明図である。It is explanatory drawing which shows an example of the change of the detection range in the confluence | merging process. 合流地点までの距離に応じた前記検出範囲の変化を示すグラフである。It is a graph which shows the change of the said detection range according to the distance to a merge point. 前記合流処理における優先順位の付与方法を示す説明図である。It is explanatory drawing which shows the provision method of the priority in the said confluence | merging process. 前記合流処理における合流動作処理を詳細に示すフローチャートである。It is a flowchart which shows the merge operation process in the said merge process in detail. 前記合流処理に応じた被合流車両の処理を示すフローチャートである。It is a flowchart which shows the process of the to-be-merged vehicle according to the said merge process. 第2実施形態における合流処理を詳細に示すフローチャートである。It is a flowchart which shows the confluence | merging process in 2nd Embodiment in detail.

以下、図面を参照しながら、発明を実施するための形態を説明する。
[1.第1実施形態]
[1−1.構成]
図1に示す運転支援装置10は、車両に搭載されており、当該装置が搭載された車両である自車両を自動的に走行させる自動運転を行う。なお、自動運転には、自車両の加速、制動、及び操舵等の運転操作を全て自動的に行い、自車両を完全に自動的に走行させるもの(以下、完全自動運転)が含まれる。このような自動運転により、例えば、自車両を指定された目的地まで完全に自動で走行させることができる。また、自動運転には、自車両の加速及び制動を自動的に行い、走行速度(以下、単に速度という)のみを自動的に制御した状態で自車両を走行させるものが含まれる。このような自動運転により、例えば、先行車両との間の車間距離を維持した状態で自車両を走行させるACCを実現できる。
Hereinafter, embodiments for carrying out the invention will be described with reference to the drawings.
[1. First Embodiment]
[1-1. Constitution]
A driving support device 10 shown in FIG. 1 is mounted on a vehicle, and performs an automatic driving in which the host vehicle that is the vehicle on which the device is mounted automatically runs. Note that the automatic driving includes one that automatically performs all driving operations such as acceleration, braking, and steering of the host vehicle and causes the host vehicle to run completely automatically (hereinafter, fully automatic driving). By such automatic driving, for example, the host vehicle can run completely automatically to a designated destination. In addition, the automatic driving includes one that automatically accelerates and brakes the host vehicle and causes the host vehicle to travel in a state in which only the traveling speed (hereinafter simply referred to as speed) is automatically controlled. By such automatic driving, for example, it is possible to realize ACC that causes the host vehicle to travel while maintaining the inter-vehicle distance from the preceding vehicle.

すなわち、運転支援装置10が実行する自動運転は、少なくとも自車両の加速及び制動を行う制御であれば、次のレベル1〜4のいずれのレベルであってもよい。自動運転に関する技術は、自動化のレベルに応じて、レベル1(安全運転支援システム)、レベル2,3(準自動走行システム)、レベル4(完全自動走行システム)に分類されている。この内容は、例えば、内閣府により2015年5月に発表された、「戦略的イノベーション創造プログラム自動走行システム」に記載されている。また、前述のACCとは、Adaptive Cruise Control の略である。また、先行車両とは、自車両と同方向に走行する車両であって、自車両の前方に位置し、自車両に隣り合う(換言すれば、自車両と先行車両との間に他の車両が存在しない)車両である。更に、自動運転には、外部に設置されたサーバから指示された自車両の速度、又は、自車両の速度及び進路に従い、自車両を自動的に走行させるものが含まれてもよい。   That is, the automatic driving performed by the driving support device 10 may be any of the following levels 1 to 4 as long as it is at least a control for accelerating and braking the host vehicle. Technologies related to automatic driving are classified into level 1 (safe driving support system), level 2 and 3 (semi-automatic driving system), and level 4 (fully automatic driving system) according to the level of automation. This content is described in, for example, “Strategic Innovation Creation Program Automated Driving System” announced in May 2015 by the Cabinet Office. The aforementioned ACC is an abbreviation for Adaptive Cruise Control. The preceding vehicle is a vehicle that travels in the same direction as the own vehicle, and is located in front of the own vehicle and adjacent to the own vehicle (in other words, another vehicle between the own vehicle and the preceding vehicle). There is no vehicle. Furthermore, the automatic driving may include one that automatically causes the host vehicle to travel according to the speed of the host vehicle instructed from a server installed outside, or the speed and course of the host vehicle.

運転支援装置10は、図1に示すように、周辺監視センサ11と、位置検出部12と、車両状態入力部13と、地図データ入力部14と、走行制御部15と、車車間通信機16と、広域無線通信機17と、車両制御部18と、ユーザI/F19と、信号発生部20とを有する。なお、I/Fはインタフェースの略である。   As shown in FIG. 1, the driving support device 10 includes a periphery monitoring sensor 11, a position detection unit 12, a vehicle state input unit 13, a map data input unit 14, a travel control unit 15, and an inter-vehicle communication device 16. A wide area radio communication device 17, a vehicle control unit 18, a user I / F 19, and a signal generation unit 20. Note that I / F is an abbreviation for interface.

周辺監視センサ11は、自車両周辺に存在する物体を検出する部位である。具体的には、自車両周辺の物体の位置及び形状や、自車両と物体との距離や、道路形状等を認識する。周辺監視センサ11は、自車両周辺を撮影するカメラを有していてもよい。また、周辺監視センサ11は、自車両周辺の検出領域に向けて電波やレーザ光を発信し、その反射波を受信することにより物体を検出する測距センサを有していてもよい。   The periphery monitoring sensor 11 is a part that detects an object existing around the host vehicle. Specifically, the position and shape of an object around the host vehicle, the distance between the host vehicle and the object, the road shape, and the like are recognized. The periphery monitoring sensor 11 may have a camera that captures the periphery of the host vehicle. In addition, the periphery monitoring sensor 11 may include a distance measuring sensor that detects an object by transmitting a radio wave or a laser beam toward a detection region around the host vehicle and receiving the reflected wave.

位置検出部12は、GNSSの測位衛星からの信号や、ジャイロセンサ及び車速センサ等による検出結果に基づいて自車両の位置を測位し、これを走行制御部15に出力する。なお、GNSSとは、Global Navigation Satellite Systemの略である。   The position detection unit 12 measures the position of the host vehicle based on a signal from a GNSS positioning satellite, detection results by a gyro sensor, a vehicle speed sensor, and the like, and outputs this to the travel control unit 15. GNSS is an abbreviation for Global Navigation Satellite System.

車両状態入力部13は、車両の状態を表す各種情報を走行制御部15に入力する。車両の状態とは、例えば、自車両の速度や加速度、角速度等の自車両の挙動を計測するセンサによる計測値等が考えられる。   The vehicle state input unit 13 inputs various information representing the vehicle state to the travel control unit 15. As the state of the vehicle, for example, a measured value by a sensor that measures the behavior of the host vehicle such as the speed, acceleration, and angular velocity of the host vehicle can be considered.

地図データ入力部14は、DVD−ROMやHDD等の不揮発性の記憶媒体から地図データを入力する部位である。地図データには、道路の結節点に対応するノードデータや、ノード間の道路区間に対応するリンクデータや、ノード及びリンクの属性データ等が含まれる。   The map data input unit 14 is a part for inputting map data from a nonvolatile storage medium such as a DVD-ROM or HDD. The map data includes node data corresponding to road nodal points, link data corresponding to road sections between nodes, node and link attribute data, and the like.

車車間通信機16は、他の車両に搭載された通信装置との間で無線通信(以下、車車間通信)を行う。車車間通信は、例えば、ARIB STD−T109(換言すれば、700MHz帯高度道路交通システム)等により行われる。   The inter-vehicle communication device 16 performs wireless communication (hereinafter referred to as inter-vehicle communication) with a communication device mounted on another vehicle. The inter-vehicle communication is performed by, for example, ARIB STD-T109 (in other words, 700 MHz band intelligent road traffic system) or the like.

広域無線通信機17は、車車間通信による通信範囲よりも広い通信範囲で無線通信を行う。具体的には、例えば、外部に設置されたサーバを介して、携帯電話等に用いられる無線通信網を利用して無線通信を行ってもよい。また、例えば、広域無線通信機17は、道路脇に多数設けられた路側機との間でDSRCやV2X等による無線通信を行うよう構成されてもよい。また、広域無線通信機17は、路側機を経由して、道路を走行する車両に搭載された通信装置と無線通信を行ってもよい。これらの通信手段は、1台の無線機で実現されていてもよく、独立した複数の無線機で実現されていてもよい。以下、広域無線通信機17により行われる無線通信を、広域無線通信という。   The wide area wireless communication device 17 performs wireless communication in a communication range wider than the communication range by vehicle-to-vehicle communication. Specifically, for example, wireless communication may be performed using a wireless communication network used for a mobile phone or the like via an external server. Further, for example, the wide area wireless communication device 17 may be configured to perform wireless communication using DSRC, V2X, or the like with a large number of roadside devices provided beside the road. Moreover, the wide area radio | wireless communication apparatus 17 may perform radio | wireless communication with the communication apparatus mounted in the vehicle which drive | works a road via a roadside machine. These communication means may be realized by one wireless device or may be realized by a plurality of independent wireless devices. Hereinafter, wireless communication performed by the wide area wireless communication device 17 is referred to as wide area wireless communication.

車両制御部18は、自車両の操舵装置やアクセルや変速機やブレーキ等を作動させるアクチュエータを制御する。
ユーザI/F19は、ディスプレイやスピーカ等を有し、自車両に乗車している者(以下、乗員)に対し、各種情報を報知する。また、ユーザI/F19は、タッチパネルやキースイッチ等の操作部を有し、ドライバ等の乗員からの各種操作を受け付ける。
The vehicle control unit 18 controls an actuator that operates a steering device, an accelerator, a transmission, a brake, and the like of the host vehicle.
User I / F19 has a display, a speaker, etc., and notifies various information with respect to the person (henceforth a passenger | crew) boarding the own vehicle. In addition, the user I / F 19 has an operation unit such as a touch panel and a key switch, and accepts various operations from an occupant such as a driver.

信号発生部20は、例えばLEDやレーザ装置等といった、可視光通信を行うための光源となる装置である。信号発生部20は、例えば、LED等のヘッドライト等であってもよい。   The signal generator 20 is a device serving as a light source for performing visible light communication, such as an LED or a laser device. The signal generator 20 may be a headlight such as an LED, for example.

走行制御部15は、CPUと、RAM、ROM、フラッシュメモリ等の半導体メモリ(以下、メモリ)とを有する周知のマイクロコンピュータを中心に構成される。走行制御部15の各種機能は、CPUが非遷移的実体的記録媒体に格納されたプログラムを実行することにより実現される。この例では、メモリが、プログラムを格納した非遷移的実体的記録媒体に該当する。また、このプログラムの実行により、プログラムに対応する方法が実行される。なお、走行制御部15を構成するCPUの数は1つでも複数でもよい。また、走行制御部15の機能を実現する手法はソフトウェアに限るものではなく、その一部又は全部の要素を、論理回路やアナログ回路等を組み合わせたハードウェアを用いて実現してもよい。   The traveling control unit 15 is configured around a known microcomputer having a CPU and a semiconductor memory (hereinafter referred to as a memory) such as a RAM, a ROM, and a flash memory. Various functions of the travel control unit 15 are realized by the CPU executing a program stored in a non-transitional tangible recording medium. In this example, the memory corresponds to a non-transitional tangible recording medium that stores a program. Further, by executing this program, a method corresponding to the program is executed. The number of CPUs constituting the travel control unit 15 may be one or more. Further, the method of realizing the function of the traveling control unit 15 is not limited to software, and some or all of the elements may be realized using hardware that combines a logic circuit, an analog circuit, and the like.

走行制御部15は、周辺監視センサ11により検出された自車両周辺の物体や道路形状や、自車両や自車両周辺を走行する他の車両(以下、周辺車両)の走行状態や、地図データ等に基づき車両制御部18を制御し、自動運転を行う。   The travel control unit 15 includes objects and road shapes around the host vehicle detected by the surrounding monitoring sensor 11, travel states of the host vehicle and other vehicles (hereinafter referred to as surrounding vehicles) traveling around the host vehicle, map data, and the like. Based on the above, the vehicle control unit 18 is controlled to perform automatic driving.

なお、走行状態とは、車両の位置及び速度等である。自車両の走行状態は、位置検出部12により測位された自車両の位置と、車両状態入力部13から入力されたセンサの計測値とに基づき把握される。また、周辺車両の走行状態は、周辺監視センサ11により検出されてもよいし、車車間通信により取得した周辺車両の車両情報に含まれていてもよい。車両情報には、該車両情報の送信元の装置が搭載された車両に固有に割り当てられた識別情報と、該車両の走行状態とが含まれる。また、運転支援装置10から送信される車両情報には、更に、自動運転が行われているか否かを示す情報が含まれる。自車両の運転中、走行制御部15は、車車間通信により自車両の車両情報を定期的に同報送信すると共に、車車間通信により周辺車両から同報送信された車両情報を受信する。   The traveling state is the position and speed of the vehicle. The traveling state of the host vehicle is grasped based on the position of the host vehicle measured by the position detection unit 12 and the measured value of the sensor input from the vehicle state input unit 13. In addition, the running state of the surrounding vehicle may be detected by the surrounding monitoring sensor 11 or may be included in the vehicle information of the surrounding vehicle acquired by inter-vehicle communication. The vehicle information includes identification information uniquely assigned to the vehicle on which the device that transmitted the vehicle information is mounted, and the running state of the vehicle. Further, the vehicle information transmitted from the driving support device 10 further includes information indicating whether or not automatic driving is being performed. During driving of the host vehicle, the traveling control unit 15 periodically broadcasts vehicle information of the host vehicle by inter-vehicle communication and receives vehicle information broadcast from surrounding vehicles by inter-vehicle communication.

ACCが行われている場合には、走行制御部15は操舵装置を制御せず、ドライバによる操舵に従い自車両の進路が定められる。無論、走行制御部15は、車車間通信により得られた先行車両や周辺車両の走行状態や地図データ等を更に加味してACCを行ってもよい。   When ACC is being performed, the traveling control unit 15 does not control the steering device, and the course of the host vehicle is determined according to steering by the driver. Of course, the traveling control unit 15 may perform the ACC by further taking into account the traveling state of the preceding vehicle and the surrounding vehicle obtained by inter-vehicle communication, map data, and the like.

また、走行制御部15は、自動運転中にドライバにより運転操作が行われた場合には、自動運転を終了し、以後、ドライバによる運転操作に従い自車両が運転される(換言すれば、手動運転が行われる)ようにしてもよい。   In addition, when the driving operation is performed by the driver during the automatic driving, the traveling control unit 15 ends the automatic driving, and thereafter the vehicle is driven according to the driving operation by the driver (in other words, the manual driving is performed). May be performed).

[1−2.処理]
次に、運転支援装置10において実行される処理について説明する。ここで、合流地点にて合流する2つの道路のうち、前記合流地点にて車線がなくなる道路を合流道路といい、前記合流地点にて車線がなくならない道路を被合流道路という。被合流道路の具体例として、高速道路の本線や高架道路等の主要道路を挙げることができる。また、合流道路の具体例として、主要道路に合流する側道や支線を挙げることができる。
[1-2. processing]
Next, the process performed in the driving assistance apparatus 10 is demonstrated. Here, of two roads that merge at the merge point, a road that has no lane at the merge point is referred to as a merge road, and a road that does not have a lane at the merge point is referred to as a merged road. Specific examples of merged roads include main roads such as main roads and elevated roads. Moreover, as a specific example of the merge road, a side road and a branch line that merge with the main road can be cited.

図2に示す合流処理は、例えば次のような場合に実行される。図3に例示する道路では、本線91が車線境界線92によって2車線に区画され、そのうちの左側の車線に支線94が合流している。図2に示す合流処理は、運転支援装置10が搭載された車両51が、例えば、図3に示すような支線94を走行して本線91に合流する際に、その運転支援装置10の走行制御部15によって実行される。   The merge process shown in FIG. 2 is executed in the following case, for example. In the road illustrated in FIG. 3, the main line 91 is divided into two lanes by a lane boundary line 92, and a branch line 94 joins the left lane. The merging process shown in FIG. 2 is performed when the vehicle 51 on which the driving assistance device 10 is mounted travels along a branch line 94 as shown in FIG. This is executed by the unit 15.

この合流処理では、先ず、S1にて、合流地点までの車両51からの残距離が検出される。ここで、図3の例では、支線94の終端部は所定距離に亘って本線91と並行に配置され、車線区画線95によって本線91の左側車線と区画されている。支線94のうち、車線区画線95と隣接する部分は、加速車線97となっている。この例では、前記残距離を検出するための合流地点は車線区画線95のどの位置に設定することも可能であるが、S1では、本線91における交通状態に応じた適宜の位置、例えば矢印Pで示す位置に、合流地点が設定される。なお、被合流道路と合流道路との形態によっては、合流地点が一意に決定される場合もある。S1では、位置検出部12が検出した自車両の位置と、地図データ入力部14から入力された地図データとに基づき、自車両(すなわち車両51)から合流地点までの残距離が検出される。   In this joining process, first, at S1, the remaining distance from the vehicle 51 to the joining point is detected. Here, in the example of FIG. 3, the end portion of the branch line 94 is disposed in parallel with the main line 91 over a predetermined distance, and is divided from the left lane of the main line 91 by the lane line 95. A portion of the branch line 94 adjacent to the lane marking 95 is an acceleration lane 97. In this example, the junction point for detecting the remaining distance can be set at any position on the lane marking 95, but at S1, an appropriate position according to the traffic condition on the main line 91, for example, the arrow P A junction point is set at the position indicated by. Depending on the form of the merged road and the merged road, the merge point may be uniquely determined. In S <b> 1, the remaining distance from the own vehicle (that is, the vehicle 51) to the junction is detected based on the position of the own vehicle detected by the position detection unit 12 and the map data input from the map data input unit 14.

続くS2では、本線91及び支線94の交通状況が把握される。この交通状況は、本線91の交通状況も支線94の交通状況も周辺監視センサ11を介して把握されてもよいが、本線91の交通状況は、本線91を走行中の車両と広域無線通信を行うことによって把握されてもよい。交通状況としては、少なくとも、本線91における車両の平均速度Vmと、本線91における平均車間距離dmとが把握される。   In subsequent S2, the traffic situation of the main line 91 and the branch line 94 is grasped. Although the traffic situation of the main line 91 and the traffic situation of the branch line 94 may be grasped via the peripheral monitoring sensor 11, the traffic situation of the main line 91 is based on the wide area wireless communication with the vehicle traveling on the main line 91. It may be grasped by doing. As the traffic situation, at least the average speed Vm of the vehicle on the main line 91 and the average inter-vehicle distance dm on the main line 91 are grasped.

続くS3では、支線94における自車両の速度範囲、すなわち最大速度Vmaxと最低速度Vminとが算出される。この算出においては、支線94における制限速度の他、運転支援装置10が実行可能な自動運転の速度範囲や、S2にて把握された支線94の交通状況が適宜参照されてもよい。   In the subsequent S3, the speed range of the host vehicle on the branch line 94, that is, the maximum speed Vmax and the minimum speed Vmin are calculated. In this calculation, in addition to the speed limit on the branch line 94, the speed range of automatic driving that can be executed by the driving support device 10 and the traffic situation of the branch line 94 grasped in S2 may be referred to as appropriate.

このようにしてS3にて自車両の速度範囲が算出されると、その速度範囲に基づき、S5では、自車両が合流地点に到達する時間tの範囲が次式によって算出される。
t=r/Vmax〜r/Vmin
なお、rは、S1にて検出された残距離である。
Thus, when the speed range of the own vehicle is calculated in S3, based on the speed range, in S5, the range of the time t for which the host vehicle reaches the junction is calculated by the following equation.
t = r / Vmax to r / Vmin
Note that r is the remaining distance detected in S1.

このように、自車両が合流地点に到達する時間tの範囲がS5にて算出されると、自車両と同時に合流地点に到達し得る車両を本線91において検出する範囲(以下、検出範囲)が、合流地点からの距離rmとして次式によってS6にて算出される。   As described above, when the range of the time t for the host vehicle to reach the junction is calculated in S5, a range (hereinafter referred to as a detection range) for detecting a vehicle that can reach the junction at the same time as the host vehicle is detected. The distance rm from the meeting point is calculated in S6 by the following equation.

rm=Vm×t=r×Vm/Vmax〜r×Vm/Vmin
なお、検出範囲の幅Δrmは、次式のようになる。
Δrm=r×Vm×(1/Vmin−1/Vmax)
このため、自車両としての車両51が図3にA,B,C,Dと順次示すように合流地点に近づくに従って、その車両51に対応した検出範囲も検出範囲A,検出範囲B,検出範囲C,検出範囲Dとして矢印で示したように変化する。すなわち、残距離rが小さくなるに従って、検出範囲の幅Δrmは小さくなり、検出範囲の位置は合流地点に近づく。
rm = Vm × t = r × Vm / Vmax to r × Vm / Vmin
The detection range width Δrm is expressed by the following equation.
Δrm = r × Vm × (1 / Vmin−1 / Vmax)
For this reason, as the vehicle 51 as the own vehicle approaches the joining point as indicated by A, B, C, and D in FIG. 3, the detection range corresponding to the vehicle 51 is also the detection range A, the detection range B, and the detection range. C and detection range D change as indicated by arrows. That is, as the remaining distance r becomes smaller, the width Δrm of the detection range becomes smaller, and the position of the detection range approaches the joining point.

続くS7では、S1にて検出された残距離が一定値以上であるか否かが判断される。なお、この一定値は、運転支援装置10の製造時に固定値に設定されてもよく、気象状態,交通状況(例えば道路の混雑状態),道路の形状等に応じて随時一定値が設定されてもよい。S7にて、残距離が一定値未満(すなわちNo)であると判断された場合は、S8にて、ユーザI/F19を介してドライバへ自動合流が不可である旨の通知がなされた後、処理が終了する。   In subsequent S7, it is determined whether or not the remaining distance detected in S1 is a certain value or more. This fixed value may be set to a fixed value when the driving support device 10 is manufactured, and is set as needed depending on weather conditions, traffic conditions (for example, road congestion), road shape, and the like. Also good. If it is determined in S7 that the remaining distance is less than a certain value (that is, No), in S8, a notification that automatic merging is not possible is made to the driver via the user I / F 19, The process ends.

また、本線91における平均車間距離dmに基づき、検出範囲において検出可能な車両が1台未満となる条件を、自動合流が不可能となる条件とすると、当該条件は、
dm>Δrm=r×Vm×(1/Vmin−1/Vmax)
なる式で表される。従って、残距離rが次式を満たす場合、自動合流が不可能となる。
Further, when the condition that the number of vehicles that can be detected in the detection range is less than one based on the average inter-vehicle distance dm on the main line 91 is a condition that automatic merging is impossible, the condition is:
dm> Δrm = r × Vm × (1 / Vmin−1 / Vmax)
It is expressed by the following formula. Therefore, when the remaining distance r satisfies the following equation, automatic merging is impossible.

r<dm/(Vm×(1/Vmin−1/Vmax))
S7では、残距離rがこの式を満たす場合に否定判断されてもよい。すなわち、前式の右辺は、前記一定値として使用されてもよい。
r <dm / (Vm × (1 / Vmin−1 / Vmax))
In S7, a negative determination may be made when the remaining distance r satisfies this equation. That is, the right side of the previous equation may be used as the constant value.

ここで、具体的な数値を用いて計算する。例えば、Vmax=40km/h=11.1m/s、Vmin=30km/h=8.3m/s、Vm=80km/h=22.2m/s、dm=5m+60m=65mであると仮定する。なお、この仮定における車間距離dmは、自車両が割り込むための空間を5mとして、その値に安全を確保するための車間距離60mを足した値である。この車間距離は、車両密度に換算すると15台/kmとなる。   Here, calculation is performed using specific numerical values. For example, it is assumed that Vmax = 40 km / h = 11.1 m / s, Vmin = 30 km / h = 8.3 m / s, Vm = 80 km / h = 22.2 m / s, and dm = 5 m + 60 m = 65 m. In addition, the inter-vehicle distance dm in this assumption is a value obtained by adding the inter-vehicle distance 60 m for ensuring safety to the value where the space for the own vehicle to interrupt is 5 m. This inter-vehicle distance is 15 vehicles / km in terms of vehicle density.

すると、r<65/(22.2×(1/8.3−1/11.1))=96mとなる。
この具体例に応じたrとrmとの関係を図4に示す。なお、本実施形態では、当該車両の前方に自車両が合流すべき車両のことを被合流車両というが、図4では、本線91を走行する車両全てを、便宜上、仮に被合流車両として、合流地点までの距離を示している。すなわち、図4における横軸は前記rmに対応する。また、図4では、自車両のことを合流車両と表現しており、図4における縦軸はrに対応する。図4における点線と実線との間に挟まれた矢印の範囲が検出範囲であり、自車両が合流地点の約100m程度手前に達するまで自動合流が可能であることが分かる。
Then, r <65 / (22.2 × (1 / 8.3-1 / 11.1)) = 96 m.
FIG. 4 shows the relationship between r and rm according to this specific example. In the present embodiment, a vehicle to which the host vehicle should join in front of the vehicle is referred to as a joined vehicle. However, in FIG. 4, all vehicles traveling on the main line 91 are temporarily joined as joined vehicles for convenience. The distance to the point is shown. That is, the horizontal axis in FIG. 4 corresponds to the rm. In FIG. 4, the host vehicle is expressed as a merged vehicle, and the vertical axis in FIG. 4 corresponds to r. The range of the arrow sandwiched between the dotted line and the solid line in FIG. 4 is the detection range, and it can be seen that automatic merging is possible until the own vehicle reaches about 100 m before the merging point.

続くS10では、S6にて算出された検出範囲に、候補車両が存在するか否かが判断される。候補車両とは、被合流車両の候補となり得る車両であり、具体的には、車車間通信機16,広域無線通信機17,及び信号発生部20による通信が可能な車両である。なお、候補車両は、このような車両のうち、少なくとも速度を自動的に制御する処理を実行中の車両であってもよい。この時点では、候補車両と自車両との距離は車車間通信が可能なほど接近していない場合がある。そこで、広域無線通信機17及びサーバを経由した広域無線通信によって、本線91を走行中の各車両と通信が試みられることにより、前記各車両が前記候補車両に該当するか否かが判断される。   In subsequent S10, it is determined whether or not there is a candidate vehicle in the detection range calculated in S6. A candidate vehicle is a vehicle that can be a candidate for a merged vehicle. Specifically, the candidate vehicle is a vehicle that can communicate with the inter-vehicle communication device 16, the wide-area wireless communication device 17, and the signal generation unit 20. The candidate vehicle may be a vehicle that is executing a process of automatically controlling at least the speed among such vehicles. At this time, the distance between the candidate vehicle and the host vehicle may not be close enough to allow inter-vehicle communication. Therefore, it is determined whether or not each vehicle corresponds to the candidate vehicle by attempting communication with each vehicle traveling on the main line 91 by wide-area wireless communication via the wide-area wireless communication device 17 and the server. .

候補車両が検出範囲に存在しない場合は、S10にてNoと判断されて処理は前述のS1へ移行する。一方、候補車両が検出範囲に存在する場合は、S10にてYesと判断されて、処理はS11へ移行する。S11では、S10にて存在すると判断された候補車両に対して、優先順位が付与される。この優先順位とは、被合流車両としてのふさわしさを示す順位である。この優先順位は、例えば次のような基準により付与される。   If the candidate vehicle does not exist in the detection range, it is determined No in S10, and the process proceeds to S1 described above. On the other hand, when a candidate vehicle exists in the detection range, it is judged as Yes in S10, and a process transfers to S11. In S11, a priority is given to the candidate vehicle determined to exist in S10. This priority order is an order indicating the suitability as a merged vehicle. This priority order is given by the following criteria, for example.

基準1:被合流道路における合流道路側の車線に、前記候補車両が複数連続して存在する場合、前記連続して存在する候補車両のうち後方の後方車両に対して、前記連続して存在する候補車両のうち前方の候補車両よりも高い優先順位を設定する。なお、被合流道路における合流道路側の車線とは、図3の例では本線91の左側車線に相当する。また、被合流道路が片側1車線の場合、その車線が合流道路側の車線に相当する。   Criteria 1: When a plurality of candidate vehicles are continuously present in the lane on the merged road side in the merged road, the candidate vehicles are continuously present with respect to the rear vehicle behind the candidate vehicles continuously present. Among the candidate vehicles, a higher priority is set than the candidate vehicle ahead. The lane on the merged road side in the merged road corresponds to the left lane of the main line 91 in the example of FIG. When the merged road is one lane on one side, the lane corresponds to the lane on the merged road side.

基準2:被合流道路における合流道路側の車線と、その隣接車線とに前記候補車両が存在する場合、合流道路側の車線に存在する候補車両に高い優先順位を設定する。
基準3:被合流道路における合流道路側の車線に、前記候補車両が複数存在する場合、周辺の車両の密度(以下、車両密度)が低い候補車両ほど高い優先順位を設定する。なお、車両密度としては、当該候補車両とその候補車両に対して1つ前方の車両との車間距離、当該候補車両とその候補車両に対して1つ後方の車両との車間距離、当該候補車両が走行中の車線に隣接する車線における周辺車両台数、等に応じた値が挙げられる。なお、周辺車両台数とは、その候補車両から所定距離以内に存在する車両の台数である。本基準における車両密度としては、前記3種類のパラメータのうちいずれを採用してもよく、複数組み合わせてもよいが、本実施形態では、当該候補車両とその候補車両に対して1つ前方の車両との車間距離の逆数を車両密度とする。
Criterion 2: When the candidate vehicle exists in the lane on the merged road side and the adjacent lane in the merged road, a high priority is set for the candidate vehicle existing in the lane on the merged road side.
Criteria 3: When a plurality of candidate vehicles exist in the lane on the merged road side in the merged road, a higher priority is set for candidate vehicles having lower density of surrounding vehicles (hereinafter, vehicle density). Note that the vehicle density includes an inter-vehicle distance between the candidate vehicle and one vehicle ahead of the candidate vehicle, an inter-vehicle distance between the candidate vehicle and one vehicle behind the candidate vehicle, and the candidate vehicle. Is a value corresponding to the number of surrounding vehicles in the lane adjacent to the lane in which the vehicle is traveling. The number of surrounding vehicles is the number of vehicles existing within a predetermined distance from the candidate vehicle. As the vehicle density in the present standard, any of the above three types of parameters may be adopted, or a plurality of parameters may be combined. In the present embodiment, the candidate vehicle and the vehicle one vehicle ahead of the candidate vehicle are used. The reciprocal of the inter-vehicle distance is taken as the vehicle density.

基準4:前記合流地点までの距離が近い候補車両ほど高い優先順位を設定する。
以上の基準1〜4を、当該順に優先的に適用した場合、例えば図5に矢印で例示するような検出範囲に対しては、次のような優先順位が設定される。なお、図5では、本線91を走行する車両のうち、前述のように通信可能な車両(すなわち候補車両)には符号52を付すと共にハッチングを施しており、通信不可能な車両にはハッチングを付さずに符号53を付している。
Criterion 4: A higher priority is set for candidate vehicles that are closer to the junction.
When the above criteria 1 to 4 are preferentially applied in that order, for example, the following priorities are set for the detection ranges illustrated by arrows in FIG. In FIG. 5, among vehicles traveling on the main line 91, vehicles that can communicate as described above (that is, candidate vehicles) are indicated by reference numeral 52 and hatched, and vehicles that cannot communicate are hatched. The code | symbol 53 is attached | subjected without attaching.

図5に示すように、検出範囲に候補車両としての車両52A〜52Dが存在する場合、基準1により、車両52Aの優先順位が最も高くなる。基準2により、車両52B及び車両52Cの方が車両52Dよりも優先順位が高くなる。基準3により、車両52Bの方が車両52Cよりも優先順位が高くなる。基準4によれば、車両52Dの優先順位が最も高いが、基準1,2,3,4の順に優先的に適用されるとすると、車両52Dの優先順位は最も低くなる。なお、検出範囲に候補車両が1台しか存在しない場合は、その候補車両の優先順位が1番に設定される。   As shown in FIG. 5, when vehicles 52 </ b> A to 52 </ b> D as candidate vehicles exist in the detection range, the priority of vehicle 52 </ b> A is the highest according to criterion 1. According to the criterion 2, the priority order of the vehicle 52B and the vehicle 52C is higher than that of the vehicle 52D. According to the standard 3, the vehicle 52B has a higher priority than the vehicle 52C. According to the standard 4, the priority of the vehicle 52D is the highest, but if the priority is applied in the order of the standards 1, 2, 3, and 4, the priority of the vehicle 52D is the lowest. When only one candidate vehicle exists in the detection range, the priority order of the candidate vehicle is set to the first.

図2に戻って、このように、S11にて候補車両に優先順位が付与されると、続くS12では、優先順位が付与された候補車両があるか否かが判断される。最初にこのS12に処理が移行したときは、S11にて優先順位が付与された直後であるので、Yesと判断されて処理はS14へ移行する。S14では、優先順位の最も高い候補車両が被合流車両に選定されて、処理はS15へ移行する。S15では、被合流車両に選定された旨の通知が、広域無線通信によって当該被合流車両に送信される。続くS16では、S14にて選定された対象の被合流車両がロストされたか否かが判断される。なお、ここでいうロストとは、文字通り対象の被合流車両が検出できなくなった場合のみならず、S15にて送信された通知に対して対象の被合流車両から自車両の割り込みを拒否する旨の通知が返信された場合も含む。   Returning to FIG. 2, as described above, when the priority order is given to the candidate vehicle in S <b> 11, it is determined in S <b> 12 whether there is a candidate vehicle to which the priority order is given. When the process shifts to S12 for the first time, it is immediately after the priority is given in S11. Therefore, the determination is Yes and the process shifts to S14. In S14, the candidate vehicle with the highest priority is selected as the merged vehicle, and the process proceeds to S15. In S15, a notification to the effect that the vehicle has been selected as a merged vehicle is transmitted to the merged vehicle by wide area wireless communication. In subsequent S16, it is determined whether or not the target joined vehicle selected in S14 has been lost. The term “lost” as used herein means not only that the target joined vehicle cannot be detected literally but also that the target joined vehicle refuses to interrupt the subject vehicle in response to the notification transmitted in S15. This includes the case where a notification is returned.

対象の被合流車両がロストされた場合は、S16にてYesと判断されて処理は前述のS12へ移行する。すると、S12では、すでに被合流車両に選定された候補車両を除いて、優先順位を付与された候補車両があるか否かが判断され、S14では、すでに被合流車両に選定された候補車両を除いて、優先順位の最も高い候補車両が被合流車両に選定される。   When the target merged vehicle is lost, it is determined Yes in S16, and the process proceeds to S12 described above. Then, in S12, it is determined whether or not there is a candidate vehicle that has been given priority, except for candidate vehicles that have already been selected as merged vehicles. In S14, candidate vehicles that have already been selected as merged vehicles are determined. In addition, the candidate vehicle with the highest priority is selected as the merged vehicle.

一方、対象の被合流車両がロストされていない場合は、S16にてNoと判断されて処理はS17へ移行する。S17では、支線94における合流地点の近傍(例えば加速車線97の始端)に自車両が到達したか否かが判断される。合流地点の近傍まで自車両が到達していない場合は、S17にてNoと判断されて処理は前述のS16へ移行する。こうして、S16,S17の処理が繰り返されるうちに、合流地点の近傍まで自車両が到達すると、S17にてYesと判断されて処理はS20へ移行する。S20では、次のような合流動作処理が実行されることにより、被合流車両の前方(すなわち1台前)に自車両が合流(すなわち、自動合流)して、処理が終了する。   On the other hand, when the target merged vehicle is not lost, it is determined No in S16, and the process proceeds to S17. In S <b> 17, it is determined whether or not the host vehicle has reached the vicinity of the junction point on the branch line 94 (for example, the start end of the acceleration lane 97). If the host vehicle has not reached the vicinity of the meeting point, it is determined No in S17, and the process proceeds to S16 described above. Thus, if the host vehicle reaches the vicinity of the merge point while the processes of S16 and S17 are repeated, it is determined Yes in S17 and the process proceeds to S20. In S20, the following merging operation process is executed, so that the own vehicle merges (that is, automatically merges) in front of the merged vehicle (that is, one vehicle before), and the process ends.

以下、S20の合流動作処理について図6のフローチャートを用いて詳述するが、この種の合流動作処理は、種々出願等がなされており、他の周知の処理と置換されてもよい。図6に示す合流動作処理では、先ず、S21にて被合流車両の合流地点への到達時間が取得される。例えば、地図データに基づき合流地点が特定され、続いて、合流地点と被合流車両の走行状態とに基づき、被合流車両が合流地点に到達する到達時期が算出される。なお、前記到達時間を取得するために被合流車両の走行状態(例えば速度)を取得するためには、被合流車両と自車両との間で車車間通信が不可能な場合は、広域無線通信を介して前記速度等が取得される。   Hereinafter, the merging operation process of S20 will be described in detail with reference to the flowchart of FIG. 6, but this type of merging operation process has been filed with various applications and may be replaced with other known processes. In the merging operation process shown in FIG. 6, first, the arrival time of the merged vehicle at the merging point is acquired in S21. For example, a merging point is specified based on the map data, and then an arrival time at which the joined vehicle reaches the merging point is calculated based on the joining point and the traveling state of the joined vehicle. In addition, in order to acquire the traveling state (for example, speed) of the joined vehicle in order to obtain the arrival time, wide area wireless communication is possible when vehicle-to-vehicle communication is impossible between the joined vehicle and the host vehicle. The speed and the like are acquired via.

続くS22では、自車両における合流地点までの走行計画が作成され、S23にて、被合流車両の位置及び走行状態(例えば速度)が取得される。このS23における走行状態等の取得も、被合流車両と自車両との距離が車車間通信可能な距離よりも離れている場合は、広域無線通信を介してなされるが、前記距離が縮まると、車車間通信を介してなされる。続くS24では、S23にて取得された被合流車両に係る情報(例えば位置及び速度)に基づいて、自車両の速度が調整される。すなわち、自車両と被合流車両とが同時期に合流地点に到達するよう、自動運転により自車両の速度が調整される。   In subsequent S22, a travel plan to the junction point in the host vehicle is created, and in S23, the position and travel state (for example, speed) of the joined vehicle are acquired. The acquisition of the running state in S23 is also performed via wide area wireless communication when the distance between the joined vehicle and the host vehicle is greater than the distance that enables vehicle-to-vehicle communication. This is done via inter-vehicle communication. In subsequent S24, the speed of the host vehicle is adjusted based on information (for example, position and speed) related to the joined vehicle acquired in S23. That is, the speed of the own vehicle is adjusted by automatic driving so that the own vehicle and the joined vehicle reach the joining point at the same time.

続くS25では、自車両及び被合流車両が合流地点に十分に接近して、自車両において被合流車両が同定できたか否かが判断される。この同定できたか否かの判断は、種々の方法で実施することができるが、例えば次のようになされてもよい。   In subsequent S25, it is determined whether or not the own vehicle and the joined vehicle have sufficiently approached the joining point and the joined vehicle has been identified in the own vehicle. The determination as to whether or not the identification has been made can be carried out by various methods. For example, the determination may be made as follows.

自車両の走行制御部15は、信号発生部20の点灯状態を制御することで可視光通信を行い、被合流車両に対し、自車両の識別情報を送信する。これに対して被合流車両から返信された識別情報が、広域無線通信又は車車間通信により先に受信した識別情報と一致するか否かを判定することによってなされてもよい。   The traveling control unit 15 of the own vehicle performs visible light communication by controlling the lighting state of the signal generating unit 20, and transmits identification information of the own vehicle to the joined vehicle. On the other hand, the identification information returned from the merged vehicle may be determined by determining whether or not the identification information received earlier by the wide area wireless communication or the inter-vehicle communication matches.

S25にて被合流車両の同定ができなかった(すなわちNo)と判断された場合は、処理は前述のS23へ移行し、被合流車両の同定ができた(すなわちYes)と判断された場合は、処理はS26へ移行する。S26では、被合流車両の前走車両が自車両のACC先行車両にセットされる。なお、前走車両とは、被合流車両の1台前を走行する車両である。すると、図示省略した別ルーチンの処理により、走行制御部15は、周辺監視センサ11により被合流車両の前走車両を認識すると共に、その前走車両を先行車両とするACCを開始する。このACCは、少なくとも合流が完了するまで継続される。   If it is determined in S25 that the merged vehicle could not be identified (that is, No), the process proceeds to S23 described above, and if it is determined that the merged vehicle was identified (that is, Yes). The process proceeds to S26. In S26, the preceding vehicle of the merged vehicle is set to the ACC preceding vehicle of the own vehicle. The preceding vehicle is a vehicle that travels in front of the joined vehicle. Then, the traveling control unit 15 recognizes the preceding vehicle of the joined vehicle by the surrounding monitoring sensor 11 and starts ACC using the preceding vehicle as the preceding vehicle by processing of another routine (not shown). This ACC is continued at least until the merge is completed.

続くS27では、被合流車両の前方への合流可能か否かが判断される。具体的には、例えば、周辺監視センサ11により検出された被合流車両と前走車両との間に所定値以上の車間距離を確保できると予想される場合には、合流が可能とみなしてもよい。そして、合流が可能である(すなわちYes)とS27にて判断された場合は、S28にて、車車間通信を介して被合流車両に合流する旨の通知がなされた後、S29にて被合流車両の前方に合流する処理がなされる。そして、S29による合流の完了後は、当該合流が完了した旨、S30にて被合流車両に車車間通信を介して通知されて、処理が終了する。   In subsequent S27, it is determined whether or not the vehicle to be merged can be merged forward. Specifically, for example, if it is expected that a vehicle-to-vehicle distance of a predetermined value or more can be secured between the joined vehicle detected by the surrounding monitoring sensor 11 and the preceding vehicle, it can be considered that the joining is possible. Good. If it is determined in S27 that merging is possible (that is, Yes), in S28, a notification that merging with the merged vehicle is made via inter-vehicle communication, and then merged in S29. A process of joining the front of the vehicle is performed. Then, after completion of the merge at S29, the merged vehicle is notified to the merged vehicle at S30 via the inter-vehicle communication, and the process ends.

なお、S29にて実行される処理は、少なくとも速度調整が含まれればよい。すなわち、操舵状態は、ドライバに委ねられてもよく、走行制御部15によって自動制御されてもよい。例えば、速度調整及び操舵状態の自動制御がなされる場合は、自動運転により速度及び進路が調整され、自車両は、被合流車両と被合流車両の前走車両との間に位置する状態で、本線91の左側車線に進入する。なお、合流の際にACCが実行されている場合には、合流終了後も、当該ACCが継続されてもよい。   Note that the process executed in S29 only needs to include at least speed adjustment. That is, the steering state may be left to the driver, or may be automatically controlled by the travel control unit 15. For example, when the speed adjustment and the automatic control of the steering state are performed, the speed and the course are adjusted by the automatic driving, and the own vehicle is located between the joined vehicle and the preceding vehicle of the joined vehicle, Enter the left lane of main line 91. In addition, when ACC is performed at the time of joining, the said ACC may be continued even after the end of joining.

一方、S27にて割り込み合流が不可能(すなわちNo)と判断された場合は、処理はS31へ移行して、支線94の終端(すなわち加速車線97の終端)まで距離が十分であるか否かが判断される。終端までの距離が十分である(すなわちYes)とS31にて判断された場合は、S32にて速度調整がなされた後、処理は前述のS27へ移行する。一方、終端までの距離が十分ではない(すなわちNo)とS31にて判断された場合は、処理はS33へ移行する。S33では、走行制御部15は、自動運転により自車両を安全に停止させて、処理が終了する。   On the other hand, if it is determined in S27 that interrupt merging is impossible (that is, No), the process proceeds to S31, and whether or not the distance to the end of the branch line 94 (that is, the end of the acceleration lane 97) is sufficient. Is judged. If it is determined in S31 that the distance to the end is sufficient (that is, Yes), the speed adjustment is performed in S32, and then the process proceeds to S27 described above. On the other hand, if it is determined in S31 that the distance to the end is not sufficient (that is, No), the process proceeds to S33. In S33, the traveling control unit 15 stops the host vehicle safely by automatic driving, and the process ends.

ここで、被合流車両における処理の一例を、図7を用いて説明する。なお、図7に示す処理は、被合流車両の走行制御部15が、前記自車両(以下、合流車両ともいう)からS15の処理による通知を受信したときに実行する処理である。   Here, an example of processing in the merged vehicle will be described with reference to FIG. The process shown in FIG. 7 is a process that is executed when the traveling control unit 15 of the joined vehicle receives the notification of the process of S15 from the own vehicle (hereinafter also referred to as a joining vehicle).

図7に示すように、この処理では、先ず、S41にて、当該被合流車両が自動運転中であるか否かが判断される。なお、前述のように、この自動運転は、少なくとも被合流車両の速度が制御される運転状態であればよい。S41にて自動運転中でない(すなわちNo)と判断された場合は、処理はS42へ移行し、合流車両の合流を拒否する旨の通知が広域無線通信を介して合流車両へ送信され、処理が終了する。   As shown in FIG. 7, in this process, first, in S41, it is determined whether or not the joined vehicle is in automatic operation. Note that, as described above, this automatic operation may be an operation state in which at least the speed of the joined vehicle is controlled. If it is determined in S41 that automatic driving is not being performed (that is, No), the process proceeds to S42, and a notification that the merging vehicle is refused to be merged is transmitted to the merging vehicle via wide area wireless communication. finish.

一方、S41にて自動運転中である(すなわちYes)と判断された場合は、合流の要請があった旨、S43にてドライバに通知された後、処理はS44へ移行する。S44では、被合流車両のドライバが、合流車両の合流を許可する旨の指示を、ユーザI/F19等を介して所定時間以内に行ったか否かが判断される。S44にて、ドライバが前記許可する旨の指示を所定時間以内に行っていない(すなわちNo)と判断された場合は、処理は前述のS42へ移行する。一方、S44にて、ドライバが前記許可する旨の指示を所定時間以内に行った(すなわちYes)と判断された場合は、処理はS45へ移行する。S45では、合流車両の合流を許可する旨の通知が広域無線通信を介して合流車両へ送信される。さらに、S46の処理により合流地点まで自動運転が継続され、合流地点到達後はS47にて自動合流動作が開始されて、処理はS48へ移行する。   On the other hand, if it is determined in S41 that automatic driving is being performed (that is, Yes), after the driver is notified in S43 that there is a request for merging, the process proceeds to S44. In S44, it is determined whether or not the driver of the joined vehicle has given an instruction to permit joining of the joining vehicle within a predetermined time via the user I / F 19 or the like. If it is determined in S44 that the driver has not issued the permission instruction within a predetermined time (that is, No), the process proceeds to S42 described above. On the other hand, if it is determined in S44 that the driver has given the permission instruction within a predetermined time (that is, Yes), the process proceeds to S45. In S45, a notification to permit the joining of the joining vehicle is transmitted to the joining vehicle via wide area wireless communication. Further, the automatic operation is continued up to the joining point by the process of S46, and after reaching the joining point, the automatic joining operation is started in S47, and the process proceeds to S48.

S48では、前述のS30による通知を受信したか否かに基づいて、合流車両の合流が完了したか否かが判断される。S48にて、合流が完了していない(すなわちNo)と判断された場合は、処理はS49へ移行し、タイムアウトになったか否かが判断される。このS49の処理は、合流車両のドライバが合流に失敗して合流をあきらめたとみなすことができる程度の時間が、S45による通知の送信から経過したか否かを判断する処理である。タイムアウトになっておらず、S49にてNoと判断された場合は、処理は前述のS48へ移行し、タイムアウトになってS49にてYesと判断された場合は、処理はそのまま終了する。   In S48, it is determined whether or not the joining of the joining vehicle has been completed based on whether or not the notification in S30 described above has been received. If it is determined in S48 that the merging has not been completed (that is, No), the process proceeds to S49, and it is determined whether or not a timeout has occurred. The process of S49 is a process of determining whether or not a time period that can be considered that the driver of the joining vehicle has failed to join and has given up the joining has elapsed since the transmission of the notification in S45. If the time-out has not been reached and the determination in S49 is No, the process proceeds to the above-described S48. If the time-out has occurred and it is determined Yes in S49, the process ends.

S48,S49の処理が繰り返されている間に、S30による通知が受信された場合は、S48にてYesと判断されて処理はS50へ移行する。S50では、被合流車両の走行制御部15が備えたメモリに、合流車両を合流させた履歴が記録されて、処理が終了する。すなわち、S48にて肯定判断がなされたことは、被合流車両が合流車両の合流を許可して、かつ、その合流が無事に完了したことを示すので、その旨の履歴を記録するのである。このような履歴は、例えばカーディーラ等において読み取られることによって当該被合流車両のドライバにポイントが付与されるなど、合流車両を合流させたことに対する利益の付与に応用することができる。   If the notification by S30 is received while the processes of S48 and S49 are being repeated, it is determined Yes in S48 and the process proceeds to S50. In S50, the history of joining the joining vehicle is recorded in the memory provided in the traveling control unit 15 of the joined vehicle, and the process ends. That is, the fact that the affirmative determination is made in S48 indicates that the joined vehicle permits the joining of the joining vehicle and that the joining has been completed successfully, so that a history to that effect is recorded. Such a history can be applied, for example, to giving a benefit to the joining of the joining vehicles, for example, a point is given to the driver of the joined vehicle by being read by a card dealer or the like.

[1−3.効果]
以上詳述した第1実施形態によれば、以下の効果が得られる。
(1A)S6では、被合流車両を検出するための検出範囲が算出(すなわち取得)され、S10では、その検出範囲における通信可能な車両が被合流車両の候補車両として設定される。従って、合流車両が合流地点から離れた地点を走行中であっても、適切な位置に前記検出範囲が設定されることにより、被合流車両を容易に設定することができる。適切な位置とは、検出範囲が、合流車両の合流に影響する可能性があるとみなされる車両を含み、かつ、合流車両の合流に影響しないとみなされる車両を含まない位置である。このため、合流車両の走行制御部15及び合流車両のドライバは、どの車両の前方に合流すべきか容易に判断することができる。
[1-3. effect]
According to the first embodiment described in detail above, the following effects can be obtained.
(1A) In S6, a detection range for detecting the joined vehicle is calculated (that is, acquired), and in S10, a communicable vehicle in the detection range is set as a candidate vehicle for the joined vehicle. Therefore, even when the joining vehicle is traveling at a point away from the joining point, the joined vehicle can be easily set by setting the detection range at an appropriate position. An appropriate position is a position whose detection range includes vehicles that are considered to possibly affect the merging of merging vehicles and does not include vehicles that are considered not to affect the merging of merging vehicles. For this reason, the traveling control unit 15 of the merged vehicle and the driver of the merged vehicle can easily determine which vehicle should be merged ahead.

(1B)しかも、被合流車両は、自動運転中の車両に対して設定される。このため、当該自動運転の制御と連携して合流動作処理が実行され、かつ、その自動運転中の車両の前方に合流車両が合流することにより、合流の安全性を向上させることができる。   (1B) Moreover, the joined vehicle is set with respect to the vehicle during automatic driving. For this reason, the merging operation process is executed in cooperation with the control of the automatic driving, and the merging vehicle joins ahead of the vehicle during the automatic driving, so that the safety of the merging can be improved.

(1C)また、本実施形態では、前記候補車両が複数存在した場合、S11,S14の処理により、それらの候補車両は優先順位を付与されて優先順位の高い順に被合流車両として選定される。このため、合流の安全性を一層向上させ、又は、合流が実行されることによる交通に対する影響を一層良好に抑制することができる。   (1C) Also, in this embodiment, when there are a plurality of candidate vehicles, the candidate vehicles are given priority and are selected as merged vehicles in descending order of priority by the processing of S11 and S14. For this reason, the safety | security of a merge can be improved further or the influence with respect to the traffic by performing a merge can be suppressed more favorably.

(1D)例えば、基準1により被合流車両が選定された場合、合流車両は自動運転中の車両の間に割り込むことになり、しかも、連続して走行する自動運転中の車両における最後尾の車両の前に割り込むことになる。従って、合流の安全性を一層向上させ、しかも、合流が実行されることによる交通に対する影響を一層良好に抑制することができる。   (1D) For example, when the merged vehicle is selected according to the criterion 1, the merged vehicle will be interrupted between the vehicles that are automatically driven, and the last vehicle in the vehicle that is automatically driven to run continuously Will be interrupted before. Therefore, the safety of merging can be further improved, and the influence on traffic due to the merging being executed can be further suppressed.

(1E)また、基準2により被合流車両が選定された場合、被合流車両が合流道路側の車線に一旦車線変更してから合流動作処理が実行される場合に比べて、交通に対する影響を一層良好に抑制することができる。   (1E) In addition, when the merged vehicle is selected according to the criterion 2, the influence on the traffic is further enhanced as compared with the case where the merged vehicle is temporarily changed to the lane on the merged road side and then the merge operation process is executed. It can suppress well.

(1F)また、基準3により被合流車両が選定された場合、被合流車両の前方に合流車両が合流するための空間を作成するための処理が割愛又は簡略化されるので、交通に対する影響を一層良好に抑制することができる。   (1F) In addition, when a merged vehicle is selected according to criterion 3, the process for creating a space for the merged vehicle to merge in front of the merged vehicle is omitted or simplified, so the influence on traffic is reduced. It can suppress more favorably.

(1G)また、基準4により被合流車両が選定された場合、合流車両は早い時点で被合流道路に合流できる可能性が高くなり、交通に対する影響(例えば合流道路を走行する車両等に対する影響)を一層良好に抑制することができる。   (1G) In addition, when a merged vehicle is selected according to criterion 4, the merged vehicle is likely to be able to merge with the merged road at an early point in time, and has an effect on traffic (for example, an effect on a vehicle traveling on the merged road). Can be suppressed more satisfactorily.

(1H)本実施形態では、S15の処理によって被合流車両に合流する旨の通知を行い、許可された場合に合流動作処理がなされる。このため、合流の安全性を一層向上させることができる。   (1H) In the present embodiment, notification of joining the joined vehicle is performed by the process of S15, and the joining operation process is performed when permitted. For this reason, the safety of merging can be further improved.

(1I)また、本実施形態では、候補車両として複数の車両を検出し、候補として残しているので、対象としていた被合流車両が検出できなくなった場合や、当該被合流車両が合流を拒否した場合でも、即座に次の被合流車両を選定することができる。   (1I) Further, in the present embodiment, a plurality of vehicles are detected as candidate vehicles and left as candidates, so that the target merged vehicle cannot be detected or the merged vehicle refuses to merge. Even in this case, the next merged vehicle can be selected immediately.

(1J)本実施形態では、被合流車両の前方に合流車両を合流させるように、合流車両の速度が調整されるので、一層確実かつ安全に合流を行うことができる。
(1K)本実施形態では、検出範囲に候補車両が存在せず、かつ、合流地点までの残距離が一定値未満になった場合、S8にてドライバへ合流が不可能である旨報知している。このため、候補車両が検出できなかった場合に、合流動作処理が実行できないことをドライバに対して早めに通知することができる。
(1J) In the present embodiment, the speed of the merged vehicle is adjusted so that the merged vehicle is merged in front of the merged vehicle, so that the merge can be performed more reliably and safely.
(1K) In this embodiment, if there is no candidate vehicle in the detection range and the remaining distance to the junction is less than a certain value, the driver is notified that the junction is impossible in S8. Yes. For this reason, when a candidate vehicle cannot be detected, it is possible to notify the driver early that the merging operation process cannot be executed.

(1L)本実施形態では、検出範囲に候補車両が存在せず、かつ、合流地点までの残距離が前記一定値以上である場合、S1〜S7の処理が繰り返し実行され、直近に算出された検出範囲に候補車両が存在する場合は、その候補車両に対してS11以降の処理がなされる。このため、道路状況が混雑している中で、本線91と支線94との状況を把握して、交通状況が刻々と変化する場合にも対応することができる。また、合流地点までの距離に応じて検出範囲が随時変化するので、合流に一層適した被合流車両を選定することができる。   (1L) In this embodiment, when there is no candidate vehicle in the detection range and the remaining distance to the merging point is equal to or greater than the predetermined value, the processing of S1 to S7 is repeatedly executed and calculated most recently. When a candidate vehicle exists in the detection range, the process after S11 is made with respect to the candidate vehicle. For this reason, it is possible to grasp the situation of the main line 91 and the branch line 94 while the road situation is congested and cope with the case where the traffic situation changes every moment. Moreover, since the detection range changes at any time according to the distance to the merging point, it is possible to select a joined vehicle that is more suitable for merging.

[1−4.特許請求の範囲の要素との対応]
なお、前記実施形態において、車車間通信機16及び広域無線通信機17及び信号発生部20が通信部に対応し、ユーザI/F19が報知部に対応する。また、走行制御部15が運転支援部,自車取得部,被合流取得部,範囲取得部,車両設定部,順位設定部,及び可否判断部に対応する。なお、走行制御部15による処理のうち、S20が運転支援部に対応し、S1及びS3が自車取得部に対応し、S2が被合流取得部に対応し、S6が範囲取得部に対応し、S14が車両設定部に対応し、S11が順位設定部に対応し、S16が可否判断部に対応する。
[1-4. Correspondence with Claimed Elements]
In the embodiment, the inter-vehicle communication device 16, the wide area wireless communication device 17, and the signal generation unit 20 correspond to the communication unit, and the user I / F 19 corresponds to the notification unit. Further, the traveling control unit 15 corresponds to a driving support unit, a vehicle acquisition unit, a merged acquisition unit, a range acquisition unit, a vehicle setting unit, a rank setting unit, and an availability determination unit. Of the processes performed by the travel control unit 15, S20 corresponds to the driving support unit, S1 and S3 correspond to the own vehicle acquisition unit, S2 corresponds to the merged acquisition unit, and S6 corresponds to the range acquisition unit. , S14 corresponds to the vehicle setting unit, S11 corresponds to the order setting unit, and S16 corresponds to the availability determination unit.

[2.第2実施形態]
[2−1.第1実施形態との相違点]
第2実施形態は、基本的な構成は第1実施形態と同様であるため、共通する構成については説明を省略し、相違点を中心に説明する。なお、第1実施形態と同じ符号は、同一の構成を示すものであって、先行する説明を参照する。
[2. Second Embodiment]
[2-1. Difference from the first embodiment]
Since the basic configuration of the second embodiment is the same as that of the first embodiment, the description of the common configuration will be omitted, and the description will focus on the differences. Note that the same reference numerals as those in the first embodiment indicate the same configuration, and the preceding description is referred to.

前述した第1実施形態では、S20における合流動作処理が、図6に詳細に示したように、本線91における車両密度に関わらず一定であった。これに対し、第2実施形態では、本線91における車両密度に応じて処理を異ならせた点で、第1実施形態と相違する。なお、ブロック図等に示される構成は第1実施形態と同様となるので、説明を省略する。   In the first embodiment described above, the merging operation process in S20 is constant regardless of the vehicle density on the main line 91, as shown in detail in FIG. On the other hand, the second embodiment is different from the first embodiment in that the processing is changed according to the vehicle density on the main line 91. Note that the configuration shown in the block diagram and the like is the same as that of the first embodiment, and thus description thereof is omitted.

[2−2.処理]
第2実施形態における合流処理は、図8に示すように、S201〜S207を備えた点で、図2に示した処理とは以下のように異なる。先ず、S10にて候補車両が存在しない(すなわちNo)と判断された場合、処理はS201へ移行し、S2の処理で把握されている本線の交通状況に基づいて、本線91における車両密度が所定値A以上であるか否かが判断される。車両密度が所定値A未満となる閑散時には、S201にてNoと判断され、処理はS203へ移行する。S203では、周辺監視センサ11等の自律センサを用いた周知の合流動作処理が実行され、処理が終了する。一方、S201にて車両密度が所定値A以上(すなわちYes)と判断された場合は、処理はS1へ移行する。
[2-2. processing]
The merge process in the second embodiment differs from the process shown in FIG. 2 as follows in that it includes S201 to S207 as shown in FIG. First, if it is determined in S10 that there is no candidate vehicle (that is, No), the process proceeds to S201, and the vehicle density on the main line 91 is predetermined based on the traffic situation of the main line grasped in the process of S2. It is determined whether or not the value is equal to or greater than A. When the vehicle density is less than the predetermined value A, it is determined No in S201, and the process proceeds to S203. In S203, a well-known merging operation process using an autonomous sensor such as the periphery monitoring sensor 11 is executed, and the process ends. On the other hand, when it is determined in S201 that the vehicle density is equal to or greater than the predetermined value A (that is, Yes), the process proceeds to S1.

また、前述のS17にて、支線94における合流地点の近傍に自車両が到達した(すなわちYes)と判断された場合は、処理はS205へ移行し、前記車両密度が所定値B未満であるか否かが判断される。なお、所定値Aが閑散時を判断するための閾値であったのに対し、所定値Bは渋滞時を判断するための閾値であり、B>Aである。   If it is determined in S17 described above that the host vehicle has reached the vicinity of the merge point on the branch line 94 (that is, Yes), the process proceeds to S205, and is the vehicle density less than the predetermined value B? It is determined whether or not. Note that the predetermined value A is a threshold for determining when it is quiet, while the predetermined value B is a threshold for determining when there is traffic, and B> A.

車両密度が所定値B以上となる渋滞時には、S205にてNoと判断され、処理はS207へ移行する。S207では、渋滞時用に用意された合流動作処理が実行され、処理が終了する。なお、S207では、手動運転に切り換えられてもよい。一方、S205にて車両密度がB未満(すなわちYes)と判断された場合は、第1実施形態と同様にS20の処理による合流動作が実行される。   When there is a traffic jam in which the vehicle density is equal to or greater than the predetermined value B, No is determined in S205 and the process proceeds to S207. In S207, a merging operation process prepared for a traffic jam is executed, and the process ends. In S207, the operation may be switched to manual operation. On the other hand, when it is determined in S205 that the vehicle density is less than B (that is, Yes), the merging operation by the process of S20 is executed as in the first embodiment.

[2−3.効果]
以上詳述した第2実施形態によれば、前述した第1実施形態の効果(1A)〜(1L)に加え、以下の効果が得られる。
[2-3. effect]
According to the second embodiment described in detail above, the following effects are obtained in addition to the effects (1A) to (1L) of the first embodiment described above.

(2A)閑散時には、候補車両が存在した場合は、第1実施形態と同様にS1〜S20の処理が実行されることにより、被合流車両の前方に安全に合流することができる。また、閑散時であっても候補車両が存在しない場合は、S203による自律センサを用いた合流動作処理が実行されるので、処理負荷を軽減することができる。   (2A) When there is a candidate vehicle at a quiet time, the processes of S1 to S20 are executed in the same manner as in the first embodiment, so that the vehicle can be safely merged in front of the merged vehicle. Further, when there is no candidate vehicle even in a quiet time, the merge operation process using the autonomous sensor in S203 is executed, so that the processing load can be reduced.

(2B)渋滞時には、別途用意された渋滞時用の合流動作処理又は手動運転への切り替え処理がS207によって実行されるので、一層確実かつ安全に合流を行うことができる。   (2B) When there is a traffic jam, the merge operation processing for traffic jam prepared separately or the switching process to manual operation is executed in S207, so that the merge can be performed more reliably and safely.

[3.他の実施形態]
以上、本発明を実施するための形態について説明したが、本発明は上述の実施形態に限定されることなく、種々変形して実施することができる。
[3. Other Embodiments]
As mentioned above, although the form for implementing this invention was demonstrated, this invention is not limited to the above-mentioned embodiment, It can implement in various deformation | transformation.

(3A)第1,第2実施形態では、本線91における車両の平均速度Vm等に応じて検出範囲が設定されたが、これに限定されるものではない。例えば、本線91(すなわち、被合流道路)において無作為抽出された1台の車両の速度に応じて検出範囲が設定されてもよい。また、被合流道路を走行中の車両が、その車両の合流地点への到達予定時刻をカーナビゲーション装置等によって取得している場合、当該到達予定時刻を広域無線通信等を介して受信することにより、その到達予定時刻に応じて検出範囲が設定されてもよい。   (3A) In the first and second embodiments, the detection range is set according to the average speed Vm of the vehicle on the main line 91, but the present invention is not limited to this. For example, the detection range may be set according to the speed of one vehicle randomly extracted on the main line 91 (that is, the merged road). In addition, when the vehicle traveling on the merged road has acquired the estimated arrival time of the vehicle at the junction point by using a car navigation device or the like, by receiving the estimated arrival time via wide area wireless communication or the like The detection range may be set according to the scheduled arrival time.

(3B)第1,第2実施形態では、S11における優先順位の付与に当たり、基準1〜4を順次優先的に適用しているが、これに限定されるものではない。例えば、基準同士の優先順位は変えてもよく、前記基準の一部のみが採用されてもよい。更に、基準1〜4とは全く他の基準が採用されてもよい。   (3B) In the first and second embodiments, the standards 1 to 4 are sequentially applied preferentially when the priority order is assigned in S11. However, the present invention is not limited to this. For example, the priorities of the standards may be changed, and only a part of the standards may be adopted. In addition, standards other than the standards 1 to 4 may be adopted.

(3C)第1,第2実施形態では、検出範囲に候補車両が存在せず、かつ、合流地点までの残距離が一定値未満になった場合に合流が不可能である旨報知しているが、これに限定されるものではない。例えば、自車両が合流地点に到達するまでの残時間が一定値以下になった場合に合流が不可能である旨報知してもよい。また、検出範囲がある条件になった場合に合流が不可能である旨報知してもよい。ある条件とは、例えば、検出範囲の幅が本線91における平均車間距離以下となった、検出範囲の幅がACCも含めた自動追従制御に必要な車間距離に自車長を加えた距離以下となった、等の条件である。   (3C) In the first and second embodiments, notification is made that merging is not possible when there is no candidate vehicle in the detection range and the remaining distance to the merging point is less than a certain value. However, the present invention is not limited to this. For example, it may be notified that merging is impossible when the remaining time until the host vehicle reaches the merging point is a certain value or less. Moreover, you may alert | report that joining is impossible when a detection range becomes a certain condition. A certain condition is, for example, that the width of the detection range is equal to or less than the average inter-vehicle distance on the main line 91, and the width of the detection range is equal to or less than the distance obtained by adding the vehicle length to the inter-vehicle distance necessary for the automatic tracking control including ACC. It is the condition that became.

(3D)検出範囲は、前述の計算式による方法以外にも、種々の方法で取得されることができる。例えば、運転支援部が算出し得る走行速度の範囲等に対応してマップやテーブルから検出範囲が読み出されてもよい。その場合、前記走行速度の範囲等と検出範囲との対応関係をより多様に設定することができる。   (3D) The detection range can be acquired by various methods other than the method based on the above-described calculation formula. For example, the detection range may be read from a map or table corresponding to a range of travel speeds that can be calculated by the driving support unit. In that case, it is possible to set various correspondence relationships between the travel speed range and the detection range.

(3E)運転支援部は、適切な走行速度を算出するものであればよく、例えば、速度を上げろとか下げろとかドライバに指示するだけのものであってもよい。その場合や、第1又は第2実施形態において操舵がドライバに委ねられる場合は、どの車両が被合流車両であるかドライバに表示又は音声によって告知されるのが望ましい。   (3E) The driving support unit only needs to calculate an appropriate traveling speed, and may be, for example, a unit that simply instructs the driver to increase or decrease the speed. In that case, or when steering is left to the driver in the first or second embodiment, it is desirable to notify the driver by display or voice of which vehicle is the joined vehicle.

(3F)第1又は第2実施形態における処理の一部は、クラウド等によってなされてもよい。その場合、例えば検出範囲がクラウドにて算出されるのであれば、当該算出された検出範囲を受信することによって取得する部位が、範囲取得部として車両に設けられる。また、被合流道路における平均速度や平均車間距離は、道路交通情報センタ等のセンタや路側機等を介して取得されてもよく、その場合、道路交通情報センタ等のセンタや路側機等から平均速度等の情報を受信する部位が、被合流取得部として車両に設けられる。   (3F) Part of the processing in the first or second embodiment may be performed by a cloud or the like. In that case, for example, if the detection range is calculated in the cloud, a part to be acquired by receiving the calculated detection range is provided in the vehicle as a range acquisition unit. In addition, the average speed and the average inter-vehicle distance on the merged road may be acquired via a center such as a road traffic information center or a roadside machine. In this case, the average speed may be obtained from a center such as a road traffic information center or a roadside machine. A part that receives information such as speed is provided in the vehicle as a merged acquisition unit.

(3G)前記実施形態における1つの構成要素が有する複数の機能を、複数の構成要素によって実現したり、1つの構成要素が有する1つの機能を、複数の構成要素によって実現したりしてもよい。また、複数の構成要素が有する複数の機能を、1つの構成要素によって実現したり、複数の構成要素によって実現される1つの機能を、1つの構成要素によって実現したりしてもよい。また、前記実施形態の構成の一部を省略してもよい。また、前記実施形態の構成の少なくとも一部を、他の前記実施形態の構成に対して付加又は置換してもよい。なお、特許請求の範囲に記載した文言のみによって特定される技術思想に含まれるあらゆる態様が本発明の実施形態である。   (3G) A plurality of functions of one constituent element in the embodiment may be realized by a plurality of constituent elements, or a single function of one constituent element may be realized by a plurality of constituent elements. . Further, a plurality of functions possessed by a plurality of constituent elements may be realized by one constituent element, or one function realized by a plurality of constituent elements may be realized by one constituent element. Moreover, you may abbreviate | omit a part of structure of the said embodiment. Further, at least a part of the configuration of the embodiment may be added to or replaced with the configuration of the other embodiment. In addition, all the aspects included in the technical idea specified only by the wording described in the claim are embodiment of this invention.

(3H)上述した運転支援装置の他、当該運転支援装置を構成要素とするシステム、当該運転支援装置としてコンピュータを機能させるためのプログラム、このプログラムを記録した半導体メモリ等の非遷移的実態的記録媒体、運転支援方法など、種々の形態で本発明を実現することもできる。   (3H) In addition to the above-described driving support device, a system including the driving support device as a constituent element, a program for causing a computer to function as the driving support device, and a non-transitory actual recording such as a semiconductor memory storing the program The present invention can also be realized in various forms such as a medium and a driving support method.

10…運転支援装置 11…周辺監視センサ 12…位置検出部
13…車両状態入力部 15…走行制御部 16…車車間通信機
17…広域無線通信機 18…車両制御部 19…ユーザI/F
20…信号発生部
DESCRIPTION OF SYMBOLS 10 ... Driving assistance device 11 ... Perimeter monitoring sensor 12 ... Position detection part 13 ... Vehicle state input part 15 ... Traveling control part 16 ... Inter-vehicle communication device 17 ... Wide area wireless communication device 18 ... Vehicle control part 19 ... User I / F
20: Signal generator

Claims (24)

合流地点にて合流する2つの道路のうち、前記合流地点にて車線がなくなる道路を合流道路として、前記合流地点にて車線がなくならない道路を被合流道路として、制御対象としての対象車両が前記合流道路を走行しているときに当該対象車両における目標走行速度を算出する処理を実行する運転支援部(15,S20)と、
前記被合流道路を走行する車両と通信を行う通信部(16,17,20)と、
前記被合流道路を走行する車両のうち、前記対象車両と同時に前記合流地点に到達する可能性のある車両を検出するための検出範囲を取得する範囲取得部(15,S6)と、
前記範囲取得部が取得した検出範囲に、前記通信部が通信可能な車両が存在する場合、当該通信可能な車両のうちの少なくとも1台を、当該車両の前方に前記対象車両が合流すべき被合流車両として設定する車両設定部(15,S14)と、
前記対象車両が前記合流道路を走行しているとき、前記合流地点までの前記対象車両からの距離と、前記運転支援部が算出し得る前記目標走行速度の範囲とを取得する自車取得部(15,S1,S3)と、
前記検出範囲に前記通信可能な車両が存在せず、かつ、前記自車取得部が取得した前記距離が所定値未満の場合、ドライバに合流が不可能である旨報知する報知部(19)と、
を備え、
前記運転支援部は、前記被合流車両が設定されたとき、当該被合流車両の前方に前記対象車両を合流させるための前記目標走行速度を算出する運転支援装置。
Of the two roads that merge at the merge point, a road that does not have a lane at the merge point is a merge road, a road that does not have a lane at the merge point is a merged road, and the target vehicle as a control target is the road A driving support unit (15, S20) that executes a process of calculating a target traveling speed of the target vehicle when traveling on a junction road;
A communication unit (16, 17, 20) for communicating with a vehicle traveling on the merged road;
A range acquisition unit (15, S6) for acquiring a detection range for detecting a vehicle that may reach the junction at the same time as the target vehicle among vehicles traveling on the merged road;
When a vehicle in which the communication unit can communicate exists in the detection range acquired by the range acquisition unit, at least one of the communicable vehicles is connected to the target vehicle to be joined in front of the vehicle. A vehicle setting unit (15, S14) for setting as a merge vehicle;
When the target vehicle is traveling on the merging road, a host vehicle acquisition unit that acquires a distance from the target vehicle to the merging point and a range of the target travel speed that can be calculated by the driving support unit ( 15, S1, S3),
A notification unit (19) for notifying the driver that the vehicle cannot be merged when the communicable vehicle does not exist in the detection range and the distance acquired by the own vehicle acquisition unit is less than a predetermined value; ,
With
The said driving assistance part is a driving assistance device which calculates the said target travel speed for making the said target vehicle merge before the said to-be-merged vehicle, when the said to-be-merged vehicle is set.
記被合流道路を走行する少なくとも1台の車両の速度を取得する被合流取得部(15,S2)を、
に備え、
前記範囲取得部は、前記自車取得部が取得した距離及び目標走行速度の範囲と前記被合流取得部が取得した速度とに応じて、前記検出範囲を取得する
請求項1に記載の運転支援装置
Before Symbol the merging acquisition unit for acquiring the speed of the at least one vehicle traveling on the merging road (15, S2),
With a further,
The driving support according to claim 1, wherein the range acquisition unit acquires the detection range according to a range of the distance and target travel speed acquired by the host vehicle acquisition unit and a speed acquired by the joined flow acquisition unit. apparatus
前記検出範囲に、前記通信部が通信可能な車両が複数存在する場合、その複数の車両をそれぞれ候補車両として、前記被合流車両としてふさわしい順位を優先順位として、前記候補車両のそれぞれに対して前記優先順位を設定する順位設定部(15,S11)を、
更に備え、
前記車両設定部は、前記候補車両のうち前記順位設定部が最も高い優先順位を設定した候補車両を、前記被合流車両として設定する
請求項1又は2に記載の運転支援装置。
When there are a plurality of vehicles that can communicate with the communication unit in the detection range, the plurality of vehicles are set as candidate vehicles, and a rank suitable for the merged vehicle is set as a priority, and the vehicle is set in the detection range. An order setting unit (15, S11) for setting priorities
In addition,
The driving support device according to claim 1, wherein the vehicle setting unit sets, as the merged vehicle, a candidate vehicle that has the highest priority set by the rank setting unit among the candidate vehicles.
前記順位設定部は、前記被合流道路における前記合流道路側の車線における前記候補車両の有無、又は、前記合流道路側の車線に複数連続して存在する前記候補車両の有無、又は、前記候補車両のそれぞれにおける周辺の車両の密度、又は、前記候補車両のそれぞれから前記合流地点までの距離の、少なくともいずれか1つを参照して前記優先順位を設定する
請求項3に記載の運転支援装置。
The rank setting unit includes the presence / absence of the candidate vehicle in the lane on the merged road side in the merged road, or the presence / absence of the candidate vehicle continuously present in the lane on the merged road side, or the candidate vehicle. The driving support device according to claim 3, wherein the priority order is set with reference to at least one of a density of surrounding vehicles in each of the vehicle and a distance from each of the candidate vehicles to the junction.
前記順位設定部は、前記被合流道路における前記合流道路側の車線に、前記候補車両が複数連続して存在する場合、前記連続して存在する候補車両のうち、より後方の候補車両に対して、より前方の候補車両よりも高い優先順位を設定する
請求項4に記載の運転支援装置。
In the case where a plurality of candidate vehicles are continuously present in the lane on the merged road side in the merged road, the rank setting unit selects a candidate vehicle that is behind the candidate vehicle that is present continuously. The driving support device according to claim 4, wherein a higher priority is set than a candidate vehicle ahead.
前記順位設定部は、前記被合流道路における前記合流道路側の車線に、前記候補車両が複数存在する場合、周辺の車両の密度が低い候補車両ほど高い優先順位を設定する
請求4に記載の運転支援装置。
5. The driving according to claim 4, wherein when there are a plurality of candidate vehicles in the lane on the merging road in the merged road, the rank setting unit sets a higher priority as a candidate vehicle having a lower density of surrounding vehicles. Support device.
前記順位設定部は、前記合流地点までの距離が短い候補車両ほど高い優先順位を設定する
請求項4に記載の運転支援装置。
The driving support apparatus according to claim 4, wherein the rank setting unit sets a higher priority for a candidate vehicle having a shorter distance to the junction.
前記被合流車両の前方に前記対象車両が合流可能か否かを判断する可否判断部(15,S16)を、
更に備え、
当該被合流車両の前方に前記対象車両が合流可能でないと前記可否判断部が判断した場合、前記順位設定部が設定した優先順位が当該被合流車両の次に高い前記候補車両を、前記車両設定部は前記被合流車両として設定し直す
請求項3〜7のいずれか1項に記載の運転支援装置。
A determination unit (15, S16) for determining whether or not the target vehicle can be merged in front of the merged vehicle;
In addition,
When the availability determination unit determines that the target vehicle is not capable of joining ahead of the joined vehicle, the candidate vehicle having the next highest priority set by the rank setting unit is set to the vehicle setting. The driving support device according to any one of claims 3 to 7, wherein the unit is reset as the merged vehicle.
前記運転支援部は、前記被合流車両の前方に前記対象車両を合流させるように、前記対象車両の走行速度を調整する
請求項1〜のいずれか1項に記載の運転支援装置。
The driving support device according to any one of claims 1 to 8 , wherein the driving support unit adjusts a traveling speed of the target vehicle so that the target vehicle joins ahead of the joined vehicle.
合流地点にて合流する2つの道路のうち、前記合流地点にて車線がなくなる道路を合流道路として、前記合流地点にて車線がなくならない道路を被合流道路として、制御対象としての対象車両が前記合流道路を走行しているときに当該対象車両における目標走行速度を算出する処理を実行する運転支援部(15,S20)と、
前記被合流道路を走行する車両と通信を行う通信部(16,17,20)と、
前記被合流道路を走行する車両のうち、前記対象車両と同時に前記合流地点に到達する可能性のある車両を検出するための検出範囲を取得する範囲取得部(15,S6)と、
前記範囲取得部が取得した検出範囲に、前記通信部が通信可能な車両が存在する場合、当該通信可能な車両のうちの少なくとも1台を、当該車両の前方に前記対象車両が合流すべき被合流車両として設定する車両設定部(15,S14)と、
を備え、
前記運転支援部は、前記被合流車両が設定されたとき、当該被合流車両の前方に前記対象車両を合流させるための前記目標走行速度を算出し、
前記検出範囲に、前記通信部が通信可能な車両が複数存在する場合、その複数の車両をそれぞれ候補車両として、前記被合流車両としてふさわしい順位を優先順位として、前記候補車両のそれぞれに対して前記優先順位を設定する順位設定部(15,S11)を、
更に備え、
前記車両設定部は、前記候補車両のうち前記順位設定部が最も高い優先順位を設定した候補車両を、前記被合流車両として設定し、
前記順位設定部は、前記被合流道路における前記合流道路側の車線における前記候補車両の有無、又は、前記合流道路側の車線に複数連続して存在する前記候補車両の有無、又は、前記候補車両のそれぞれにおける周辺の車両の密度、又は、前記候補車両のそれぞれから前記合流地点までの距離の、少なくともいずれか1つを参照して前記優先順位を設定し、
前記順位設定部は、前記合流地点までの距離が短い候補車両ほど高い優先順位を設定する
運転支援装置。
Of the two roads that merge at the merge point, a road that does not have a lane at the merge point is a merge road, a road that does not have a lane at the merge point is a merged road, and the target vehicle as a control target is the road A driving support unit (15, S20) that executes a process of calculating a target traveling speed of the target vehicle when traveling on a junction road;
A communication unit (16, 17, 20) for communicating with a vehicle traveling on the merged road;
A range acquisition unit (15, S6) for acquiring a detection range for detecting a vehicle that may reach the junction at the same time as the target vehicle among vehicles traveling on the merged road;
When a vehicle in which the communication unit can communicate exists in the detection range acquired by the range acquisition unit, at least one of the communicable vehicles is connected to the target vehicle to be joined in front of the vehicle. A vehicle setting unit (15, S14) for setting as a merge vehicle;
With
The driving support unit calculates the target travel speed for joining the target vehicle in front of the joined vehicle when the joined vehicle is set ,
When there are a plurality of vehicles that can communicate with the communication unit in the detection range, the plurality of vehicles are set as candidate vehicles, and a rank suitable for the merged vehicle is set as a priority, and the vehicle is set in the detection range. An order setting unit (15, S11) for setting priorities
In addition,
The vehicle setting unit sets, as the merged vehicle, a candidate vehicle in which the rank setting unit sets the highest priority among the candidate vehicles.
The rank setting unit includes the presence / absence of the candidate vehicle in the lane on the merged road side in the merged road, or the presence / absence of the candidate vehicle continuously present in the lane on the merged road side, or the candidate vehicle. The priority order is set with reference to at least one of the density of surrounding vehicles in each of the above, or the distance from each of the candidate vehicles to the junction point,
The ranking setting unit is a driving support device that sets a higher priority for a candidate vehicle having a shorter distance to the junction .
前記対象車両が前記合流道路を走行しているとき、前記合流地点までの前記対象車両からの距離と、前記運転支援部が算出し得る前記目標走行速度の範囲とを取得する自車取得部(15,S1,S3)と、
前記被合流道路を走行する少なくとも1台の車両の速度を取得する被合流取得部(15,S2)と、
を更に備え、
前記範囲取得部は、前記自車取得部が取得した距離及び目標走行速度の範囲と前記被合流取得部が取得した速度とに応じて、前記検出範囲を取得する
請求項10に記載の運転支援装置。
When the target vehicle is traveling on the merging road, a host vehicle acquisition unit that acquires a distance from the target vehicle to the merging point and a range of the target travel speed that can be calculated by the driving support unit ( 15, S1, S3),
A merged acquisition unit (15, S2) for acquiring the speed of at least one vehicle traveling on the merged road;
Further comprising
The driving support according to claim 10 , wherein the range acquisition unit acquires the detection range according to a range of the distance and target travel speed acquired by the own vehicle acquisition unit and a speed acquired by the joined flow acquisition unit. apparatus.
前記被合流車両の前方に前記対象車両が合流可能か否かを判断する可否判断部(15,S16)を、
更に備え、
当該被合流車両の前方に前記対象車両が合流可能でないと前記可否判断部が判断した場合、前記順位設定部が設定した優先順位が当該被合流車両の次に高い前記候補車両を、前記車両設定部は前記被合流車両として設定し直す
請求項10又は請求項11に記載の運転支援装置。
A determination unit (15, S16) for determining whether or not the target vehicle can be merged in front of the merged vehicle;
In addition,
When the availability determination unit determines that the target vehicle is not capable of joining ahead of the joined vehicle, the candidate vehicle having the next highest priority set by the rank setting unit is set to the vehicle setting. The driving support device according to claim 10 or 11 , wherein the unit is reset as the merged vehicle.
前記運転支援部は、前記被合流車両の前方に前記対象車両を合流させるように、前記対象車両の走行速度を調整する
請求項1012のいずれか1項に記載の運転支援装置。
The driving support device according to any one of claims 10 to 12 , wherein the driving support unit adjusts a traveling speed of the target vehicle so that the target vehicle joins ahead of the joined vehicle.
前記範囲取得部が取得した検出範囲に、前記通信部が通信可能な車両が存在しなかった場合、
前記範囲取得部は、前記検出範囲を再度取得し、
前記車両設定部は、前記範囲取得部が直近に取得した検出範囲に、前記通信部が通信可能な車両が存在する場合、当該通信可能な車両を前記被合流車両として設定する
請求項1〜13のいずれか1項に記載の運転支援装置。
When there is no vehicle that the communication unit can communicate with in the detection range acquired by the range acquisition unit,
The range acquisition unit acquires the detection range again,
The vehicle setting unit sets the communicable vehicle as the merged vehicle when there is a vehicle communicable by the communication unit in the detection range most recently acquired by the range acquisition unit. The driving support device according to any one of the above.
合流地点にて合流する2つの道路のうち、前記合流地点にて車線がなくなる道路を合流道路として、前記合流地点にて車線がなくならない道路を被合流道路として、制御対象としての対象車両が前記合流道路を走行しているときに当該対象車両における目標走行速度を算出する処理を実行する運転支援部(15,S20)と、
前記被合流道路を走行する車両と通信を行う通信部(16,17,20)と、
前記被合流道路を走行する車両のうち、前記対象車両と同時に前記合流地点に到達する可能性のある車両を検出するための検出範囲を取得する範囲取得部(15,S6)と、
前記範囲取得部が取得した検出範囲に、前記通信部が通信可能な車両が存在する場合、当該通信可能な車両のうちの少なくとも1台を、当該車両の前方に前記対象車両が合流すべき被合流車両として設定する車両設定部(15,S14)と、
を備え、
前記運転支援部は、前記被合流車両が設定されたとき、当該被合流車両の前方に前記対象車両を合流させるための前記目標走行速度を算出し、
前記範囲取得部が取得した検出範囲に、前記通信部が通信可能な車両が存在しなかった場合、
前記範囲取得部は、前記検出範囲を再度取得し、
前記車両設定部は、前記範囲取得部が直近に取得した検出範囲に、前記通信部が通信可能な車両が存在する場合、当該通信可能な車両を前記被合流車両として設定する
運転支援装置。
Of the two roads that merge at the merge point, a road that does not have a lane at the merge point is a merge road, a road that does not have a lane at the merge point is a merged road, and the target vehicle as a control target is the road A driving support unit (15, S20) that executes a process of calculating a target traveling speed of the target vehicle when traveling on a junction road;
A communication unit (16, 17, 20) for communicating with a vehicle traveling on the merged road;
A range acquisition unit (15, S6) for acquiring a detection range for detecting a vehicle that may reach the junction at the same time as the target vehicle among vehicles traveling on the merged road;
When a vehicle in which the communication unit can communicate exists in the detection range acquired by the range acquisition unit, at least one of the communicable vehicles is connected to the target vehicle to be joined in front of the vehicle. A vehicle setting unit (15, S14) for setting as a merge vehicle;
With
The driving support unit calculates the target travel speed for joining the target vehicle in front of the joined vehicle when the joined vehicle is set ,
When there is no vehicle that the communication unit can communicate with in the detection range acquired by the range acquisition unit,
The range acquisition unit acquires the detection range again,
The vehicle setting unit is a driving support device that sets the communicable vehicle as the merged vehicle when a vehicle communicable with the communication unit is present in the detection range most recently acquired by the range acquisition unit.
前記対象車両が前記合流道路を走行しているとき、前記合流地点までの前記対象車両からの距離と、前記運転支援部が算出し得る前記目標走行速度の範囲とを取得する自車取得部(15,S1,S3)と、
前記被合流道路を走行する少なくとも1台の車両の速度を取得する被合流取得部(15,S2)と、
を更に備え、
前記範囲取得部は、前記自車取得部が取得した距離及び目標走行速度の範囲と前記被合流取得部が取得した速度とに応じて、前記検出範囲を取得する
請求項15に記載の運転支援装置。
When the target vehicle is traveling on the merging road, a host vehicle acquisition unit that acquires a distance from the target vehicle to the merging point and a range of the target travel speed that can be calculated by the driving support unit ( 15, S1, S3),
A merged acquisition unit (15, S2) for acquiring the speed of at least one vehicle traveling on the merged road;
Further comprising
The driving support according to claim 15 , wherein the range acquisition unit acquires the detection range according to a range of the distance and target travel speed acquired by the own vehicle acquisition unit and a speed acquired by the joined flow acquisition unit. apparatus.
前記検出範囲に、前記通信部が通信可能な車両が複数存在する場合、その複数の車両をそれぞれ候補車両として、前記被合流車両としてふさわしい順位を優先順位として、前記候補車両のそれぞれに対して前記優先順位を設定する順位設定部(15,S11)を、
更に備え、
前記車両設定部は、前記候補車両のうち前記順位設定部が最も高い優先順位を設定した候補車両を、前記被合流車両として設定する
請求項15又は16に記載の運転支援装置。
When there are a plurality of vehicles that can communicate with the communication unit in the detection range, the plurality of vehicles are set as candidate vehicles, and a rank suitable for the merged vehicle is set as a priority, and the vehicle is set in the detection range. An order setting unit (15, S11) for setting priorities
In addition,
The driving support device according to claim 15 or 16 , wherein the vehicle setting unit sets, as the merged vehicle, a candidate vehicle in which the priority setting unit sets the highest priority among the candidate vehicles.
前記順位設定部は、前記被合流道路における前記合流道路側の車線における前記候補車両の有無、又は、前記合流道路側の車線に複数連続して存在する前記候補車両の有無、又は、前記候補車両のそれぞれにおける周辺の車両の密度、又は、前記候補車両のそれぞれから前記合流地点までの距離の、少なくともいずれか1つを参照して前記優先順位を設定する
請求項17に記載の運転支援装置。
The rank setting unit includes the presence / absence of the candidate vehicle in the lane on the merged road side in the merged road, or the presence / absence of the candidate vehicle continuously present in the lane on the merged road side, or the candidate vehicle. The driving support device according to claim 17 , wherein the priority order is set with reference to at least one of a density of surrounding vehicles in each of the vehicle and a distance from each of the candidate vehicles to the junction.
前記順位設定部は、前記被合流道路における前記合流道路側の車線に、前記候補車両が複数連続して存在する場合、前記連続して存在する候補車両のうち、より後方の候補車両に対して、より前方の候補車両よりも高い優先順位を設定する
請求項18に記載の運転支援装置。
In the case where a plurality of candidate vehicles are continuously present in the lane on the merged road side in the merged road, the rank setting unit selects a candidate vehicle that is behind the candidate vehicle that is present continuously. The driving support device according to claim 18 , wherein a higher priority is set than a candidate vehicle ahead.
前記順位設定部は、前記被合流道路における前記合流道路側の車線に、前記候補車両が複数存在する場合、周辺の車両の密度が低い候補車両ほど高い優先順位を設定する
請求項18に記載の運転支援装置。
The order setting unit, the lane of the merging road side of the merging road, if said candidate vehicle there are a plurality of claim 18, the density of the surrounding of the vehicle to set the higher priority lower candidate vehicle Driving assistance device.
前記被合流車両の前方に前記対象車両が合流可能か否かを判断する可否判断部(15,S16)を、
更に備え、
当該被合流車両の前方に前記対象車両が合流可能でないと前記可否判断部が判断した場合、前記順位設定部が設定した優先順位が当該被合流車両の次に高い前記候補車両を、前記車両設定部は前記被合流車両として設定し直す
請求項1720のいずれか1項に記載の運転支援装置。
A determination unit (15, S16) for determining whether or not the target vehicle can be merged in front of the merged vehicle;
In addition,
When the availability determination unit determines that the target vehicle is not capable of joining ahead of the joined vehicle, the candidate vehicle having the next highest priority set by the rank setting unit is set to the vehicle setting. The driving support device according to any one of claims 17 to 20 , wherein the unit is reset as the merged vehicle.
前記通信部は、前記被合流車両に対して、当該被合流車両の前方に前記対象車両が合流する旨の通知を行う
請求項15に記載の運転支援装置。
The driving support device according to claim 15 , wherein the communication unit notifies the joined vehicle that the target vehicle joins ahead of the joined vehicle.
前記検出範囲に、前記通信部が通信可能な車両が複数存在する場合、その複数の車両をそれぞれ候補車両として、前記被合流車両としてふさわしい順位を優先順位として、前記候補車両のそれぞれに対して前記優先順位を設定する順位設定部(15、S11)を、
更に備え、
前記車両設定部は、前記候補車両のうち前記順位設定部が最も高い優先順位を設定した候補車両を前記被合流車両として設定し、前記通知に対して、前記対象車両が合流するのを拒否する旨の返信が前記被合流車両からなされた場合、前記順位設定部が設定した優先順位が当該被合流車両の次に高い前記候補車両を、被合流車両として設定し直す
請求項22に記載の運転支援装置。
When there are a plurality of vehicles that can communicate with the communication unit in the detection range, the plurality of vehicles are set as candidate vehicles, and a rank suitable for the merged vehicle is set as a priority, and the vehicle is set in the detection range. An order setting unit (15, S11) for setting priorities
In addition,
The vehicle setting unit sets, as the merged vehicle, a candidate vehicle for which the rank setting unit has set the highest priority among the candidate vehicles, and rejects the target vehicle from joining the notification. 23. The driving according to claim 22 , wherein, when a reply to the effect is made from the joined vehicle, the candidate vehicle having the next highest priority set by the rank setting unit is set again as the joined vehicle. Support device.
前記運転支援部は、前記被合流車両の前方に前記対象車両を合流させるように、前記対象車両の走行速度を調整する
請求項1523のいずれか1項に記載の運転支援装置。
The driving support device according to any one of claims 15 to 23 , wherein the driving support unit adjusts a traveling speed of the target vehicle so that the target vehicle joins ahead of the joined vehicle.
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