JP4039241B2 - Vehicle travel control device - Google Patents

Description

なお、目標減速度Ｘgsは減速時に正値となる。
このように、本実施形態においては、車両前方にある道路の曲率半径が最小となる目標ノード地点までの車間距離Ｌn、及び当該目標ノード地点での曲率半径Ｒnを検出し、それらに応じて目標減速度Ｘgsを算出するため、適切な目標減速度を設定することができる。
【００２７】
次にステップＳ９に移行して、前記車間距離センサ２２で検出される先行車候補との車間距離Ｌx及び相対速度ｄＬx等に基づいて、その先行車候補は運転者の減速操作に影響を与える先行車であるか否かを判定する。具体的には、まず、車間距離センサ２２で検出された車間距離Ｌx及び横距離Ｌyと、操舵角センサ１９で検出された操舵角θと、前記ステップＳ２で算出された走行速度Ｖとに基づいて、先行車候補が自車線内にあるか否かを判定する。先行車候補が自車線内にある場合、先行車候補との車間距離Ｌx及び相対速度ｄＬxに基づき、下記（６）式に従って先行車候補との接近傾向の大きさを示す存在判断指数Ａsを算出し、その存在判断指数Ａsが判断しきい値Ａso（例えば、“０”）より小さいときには、先行車候補は運転者の減速操作に影響を与える先行車である、つまり運転者は先行車の走行状態に応じて自車を減速させていると判定し、後述する制御開始判断閾値Ｘgsstartを大きく補正することを示す先行車判断フラグＦpcarを“１”のセット状態とする。なお、存在判断指数Ａsは、先行車との接近傾向が大きいほど小さく、つまり負の方向へ大きくなり、逆に先行車との接近傾向が小さいほど大きく、つまり正の方向へ大きくなる。また、判断しきい値Ａsoは、定数に限られるものではなく、例えば路面μに応じて変化させてもよい。
【００２８】
Ａs＝ Ｋap・（Ｌx ― Ｌc） ＋ Ｋad・ｄＬx ………（６）
ここで、Ｋap、Ｋadは重み係数である。また、Ｌcは車間距離基準値であり、前記ステップＳ２で算出された走行速度Ｖに定数Ｋv1を乗じ、その乗算結果に定数Ｋv2を加えて算出される。
このように、本実施形態では、少なくともレーザーレーダ、ミリ波レーダ、画像処理装置のいずれか１つを用いて、先行車候補との相対速度ｄＬxや車間距離Ｌxを検出し、その検出結果に基づいて先行車を検出するため、先行車を精度よく安価に検出することができる。
【００２９】
次いで、先行車候補が自車線内にある状態で、存在判断指数Ａsが判断しきい値Ａso以上であるときには、先行車候補は運転者の減速操作に影響を与える先行車でない、つまり運転者は先行車の走行状態と関係なくカーブ状態に応じて自車を減速させていると判定し、先行車判断フラグＦpcarを“０”のリセット状態とする。
【００３０】
このように、本実施形態においては、先行車候補との接近傾向の大きさを示す存在判断指数Ａsを算出し、存在判断指数Ａsが判断しきい値Ａsoより小さいとき、つまり先行車候補との接近傾向が大きいときだけ、先行車判断フラグＦpcarを“１”のセット状態として、後述する制御開始判断閾値Ｘgsstartを大きく補正するため、運転者が先行車の走行状態に応じて自車を減速させているときだけ、減速制御の開始タイミングが遅くされ、運転者がカーブ状態に応じて自車を減速させているときまで、減速制御の開始タイミングが遅くされてしまうことはなく、運転者の違和感が抑制防止される。
【００３１】
これに対して、他車線に先行車候補がある場合等、上記条件を満たさない場合には先行車判断フラグＦpcarが“０”のリセット状態とされる。
このように、本実施形態にあっては、先行車候補が自車線内にあることが検出されているときだけ、制御開始判断閾値Ｘgsstart大きく設定することを示す先行車判断フラグＦpcarをセット状態とするため、例えば、他車線に先行車候補があるとき等、運転者が先行車の走行状態に応じて自車を減速させていないとき、つまり運転者がカーブ状態に応じて自車を減速させているときまで、減速制御の開始タイミングが遅くされてしまうことはなく、運転者の違和感が効果的に防止される。
【００３２】
次にステップＳ１０に移行して、運転者の減速操作に影響を与える先行車があるときには、制動力制御の開始タイミングが遅くなるように制御開始判断閾値Ｘgsstartを大きく設定する。具体的には、前記ステップＳ９で設定された先行車判断フラグが“１”のセット状態であるときには、（ Ｘgsstarto、Ｘgsstarto− Ａs、Ｘgsstartmax ）の中間値を制御開始判断閾値Ｘgsstartとする。ここで、Ｘgsmaxはリミット値であり、制動力制御の開始タイミングを遅くすることに起因して、制動力制御の効果が損なわれることがない範囲に設定する。なお、存在判断指数Ａsは負値であるため、通常、Ｘgsstartoが最小値、Ｘgsstartmaxが最大値、Ｘgsstarto−Ａsが中間値となる。
【００３３】
これに対して、前記ステップＳ９で設定された先行車判断フラグＦpcarが“０”のリセット状態であるときには、補正前制御開始判断閾値Ｘgsstartoを制御開始判断閾値Ｘgsstartとする。
次にステップＳ１１に移行して、制動力制御の開始タイミングを遅くするときには、警報の開始タイミングが遅くなるように警報開始判断閾値Ｘgswarnを大きく設定し、その警報開始判断閾値Ｘgswarnに基づいて警報作動フラグｆlgwarnを設定する。具体的には、まずこの演算処理が前回実行されたときに設定された警報作動フラグｆlgwarnが“０”のリセット状態である場合、前記ステップＳ８で算出した目標減速度Ｘgsが所定のしきい値（以下、警報開始判断閾値とも呼ぶ。）Ｘgswarn以上であるときには、警報作動フラグｆlgwarnを“１”のセット状態とする。
【００３４】
ここで、警報開始判断閾値Ｘgswarnとしては、先行車判断フラグＦpcarが“０”のリセット状態であるときには、所定の警報開始判断閾値Ｘgswarnoとされ、先行車判断フラグＦpcarが“１”のセット状態であるときには、（ Ｘgswarno、Ｘgswarno− Ａs、Ｘgswarnmax ）の中間値とされる。ここで、Ｘgswarnmaxはリミット値であり、警報の開始タイミングを遅くすることに起因して、警報の効果が損なわれることがない範囲に設定する。
【００３５】
このように、本実施形態では、運転者の減速操作に影響を与える先行車があるとき、つまり減速制御の開始タイミングを遅らせるときには、警報の開始タイミングも遅らせるため、警報が適切なタイミングで行われる。
次いで、この演算処理が前回実行されたときに設定された警報作動フラグｆlgwarnが“１”のセット状態である場合、目標減速度Ｘgsが（Ｘgswarn−Ｋhwarn）以上であるときには、警報作動フラグｆlgwarnを“１”のセット状態とする。ここで、Ｋhwarnは警報のハンチングを防ぐための定数であり、例えば０．０３ｇ等に設定される。
【００３６】
これに対して、前記ステップＳ８で算出した目標減速度Ｘgsが（Ｘgswarn−Ｋhwarn）より小さい場合等、上記条件を満たさない場合には警報作動フラグｆlgwarnを“０”のリセット状態とする。
次にステップＳ１２に移行して、前記ステップＳ８で算出した目標減速度Ｘgs等に基づいて制動力制御の開始判断をする制御開始判断を行う。具体的には、この演算処理が前回実行されたときに設定された作動状態フラグｆlggensokuが“０”のリセット状態である場合、前記ステップＳ８で算出された目標減速度Ｘgsが前記ステップＳ１０で設定された制御開始判断閾値Ｘgsstart以上であるときには、制動力制御が行われていることを示す作動状態フラグｆlggensokuを“１”のセット状態とする。
【００３７】
次いで、この演算処理が前回実行されたときに設定された作動状態フラグｆlggensokuが“１”のセット状態である場合、前記ステップＳ８で算出した目標減速度Ｘgsが（Ｘgsstart−Ｋh）以上であるときには、作動状態フラグｆlggensokuを“１”のセット状態とする。ここで、Ｋhは制動力制御のハンチングを防ぐための定数である。
【００３８】
これに対して、前記ステップＳ８で算出した目標減速度Ｘgsが（Ｘgsstart−Ｋh）より小さいとき場合等、上記条件を満たさない場合には作動状態フラグｆlggensokuが“０”のリセット状態とされる。
なお、前記ステップＳ１０やＳ１１で用いられるしきい値Ｘgswarn、Ｘgsgensokuは、固定値に限られるものではなく、例えばヘッドライトの作動状態等に基づいて車両周辺の明るさを判断するようにして、車両周辺が暗く運転者がスピード感を大きく感じるときには、当該明るさに応じて変わる変動値を用いてもよい。
【００３９】
次にステップＳ１３に移行して、各車輪５ＦＬ〜５ＲＲのホイールシリンダ６ＦＬ〜６ＲＲに供給する制動流体圧を算出する。具体的には、作動状態フラグｆlggensokuが“１”のセット状態であるか否かを判定し、セット状態である場合には制動力制御を実行するようになっており、先ず前記ステップＳ１２で算出した目標減速度Ｘgsにブレーキ諸元等から定まる定数Ｋｂを乗じて目標制動流体圧Ｐcを算出し、当該目標制動流体圧Ｐcと運転者の制動操作によるマスタシリンダ圧Ｐmとのうち、大きい方を前輪用目標制動流体圧Ｐsfとすると共に、その前輪用目標制動流体圧Ｐsfに基づいて、最適な前後制動力配分となるように後輪用目標制動流体圧Ｐsrを算出する。
【００４０】
これに対して、作動状態フラグｆlggensokuが“０”のリセット状態である場合には制動力制御を実行しないようになっており、運転者の制動操作によるマスタシリンダ圧Ｐmを前輪用目標制動流体圧Ｐsfとすると共に、その前輪用目標制動流体圧Ｐsfに基づいて、最適な前後制動力配分となるように後輪用目標制動流体圧Ｐsrを算出する。
【００４１】
次にステップＳ１４に移行して、駆動輪５ＲＬ、５ＲＲを駆動する駆動トルクを算出する。具体的には、作動状態フラグｆlggensokuが“１”のセット状態である場合には、前記ステップＳ１で読み込んだアクセル開度Ａccに応じて算出される目標駆動トルクｆ（Ａcc）から、前記ステップＳ１４で算出した目標制動流体圧Ｐcによって発生が予測される制動トルクｇ（Ｐc）を差し引いて目標駆動トルクＴrqdsを算出する。
【００４２】
これに対して、作動状態フラグｆlggensokuが“０”のリセット状態である場合には、アクセル開度Ａccに応じて算出される目標駆動トルクｆ（Ａcc）を目標駆動トルクＴrqdsとする。
次にステップＳ１５に移行して、前記ステップＳ１４で算出した各車輪５ＦＬ〜５ＲＲの目標制動流体圧Ｐsf、Ｐsrを前記制動流体圧制御回路７に向けて出力すると共に、前記ステップＳ１４で算出した駆動輪５ＲＬ、５ＲＲの目標駆動トルクＴrqdsを前記駆動トルクコントロールユニット１２に向けて出力し、また警報作動フラグｆlgwarnが“１”のセット状態であるときには、ディスプレイやスピーカで警報動作を行わせる制御信号を警報装置２１に向けて出力してから、メインプログラムに復帰する。
【００４３】
次に、本実施形態の動作について具体的状況に基づいて説明する。
まず、図８（ａ）に示すように、自車がカーブに進入したときに、減速を開始していない先行車が自車線内の自車近傍にあったとする。すると、制駆動力コントロールユニット８で行われる演算処理では、まずステップＳ１で、前記各センサ等から各種データが読み込まれ、ステップＳ２で、車両の走行速度Ｖが算出され、ステップＳ３で、自車前方の各ノード地点における道路の曲率半径Ｒnが算出され、ステップＳ４で、自車を最も減速すべき地点である目標ノード地点が算出され、ステップＳ５で、道路の路面摩擦係数Ｋμが算出され、ステップＳ６で、当該路面摩擦係数Ｋμに基づいて目標ノード地点における許容横加速度Ｙglimtが算出され、ステップＳ７で、当該許容横加速度Ｙglimtを超えないように目標車速Ｖrが算出される。ここで、自車から目標ノード地点までの距離が十分に大きいとすると、ステップＳ８で、当該目標車速Ｖr等に基づいて目標減速度Ｘgsが小さく算出され、またステップＳ９で、先行車が運転者の減速操作に影響を与えると判定されると、先行車判断フラグＦpcarが“１”のセット状態とされ、ステップＳ１０で、制御開始判断閾値Ｘgsstartが大きく設定され、またステップＳ１１で、警報開始判断閾値Ｘgswarnが大きく設定され、当該警報開始判断閾値Ｘgswarnが前記目標減速度Ｘgsより大きいと、警報作動フラグｆlgwarnが“０”のリセット状態とされ、また前記制御開始判断閾値Ｘgsstartが目標減速度Ｘgsより大きいと、ステップＳ１２で、作動状態フラグｆlggensokuが“０”のリセット状態とされ、ステップＳ１３で、運転者の制動操作によるマスタシリンダ圧Ｐmが前輪用目標制動流体圧Ｐsfとされ、その前輪用目標制動流体圧Ｐsfに基づいて、最適な前後制動力配分となるように後輪用目標制動流体圧Ｐsrが算出され、ステップＳ１４で、アクセル開度Ａccに応じて算出される目標駆動トルクｆ（Ａcc）が目標駆動トルクＴrqdsとされ、ステップＳ１５で、目標制動流体圧Ｐsf、Ｐsrが前記制動流体圧制御回路７に向けて出力され、目標駆動トルクＴrqdsが前記駆動トルクコントロールユニット１２に向けて出力される。
【００４４】
このように、本実施形態にあっては、自車のカーブ進入時に、減速を開始していない先行車があるときには、減速制御の開始タイミングを遅くするため、自車が先に減速してしまうことが防止され、先行車から取り残されるように感じさせることなく、運転者に違和感を与えてしまうことが防止される。
ちなみに、自車前方の道路のカーブ情報のみに応じて減速制御を行う従来の方法では、自車のカーブ進入時に、減速を開始していない先行車があるときには、自車の減速制御が行われると、先行車との車間距離が徐々に大きくなっていき、当該先行車から取り残されるように感じさせ、運転者に違和感を与えてしまう。
【００４５】
上記フローが繰り返されるうちに、図８（ｂ）に示すように、先行車が減速を開始して、先行車との車間距離等が減少傾向にあるとする。すると、制駆動力コントロールユニット８で行われる演算処理では、前記ステップＳ１〜Ｓ７を経て、前記ステップＳ８で、目標減速度Ｘgsが大きく算出され、前記ステップＳ９及びＳ１０を経て、前記ステップＳ１１で、再び警報開始判断閾値Ｘgswarnが大きく設定されるが、前記目標減速度Ｘgsが当該警報開始判断閾値Ｘgswarnより大きいと、警報作動フラグｆlgwarnが“１”のセット状態とされ、また前記目標減速度Ｘgsが制御開始判断閾値Ｘgsstartより大きいと、ステップＳ１２で、作動状態フラグｆlggensokuが“１”のセット状態とされ、ステップＳ１３で、前記目標減速度Ｘgsにブレーキ諸元等から定まる定数Ｋｂを乗じて目標制動流体圧Ｐcが算出され、当該目標制動流体圧Ｐcと運転者の制動操作によるマスタシリンダ圧Ｐmとのうち、大きい方が前輪用目標制動流体圧Ｐsfとされ、その前輪用目標制動流体圧Ｐsfに基づいて、最適な前後制動力配分となるように後輪用目標制動流体圧Ｐsrが算出され、ステップＳ１４で、前記アクセル開度Ａccに応じて算出される目標駆動トルクｆ（Ａcc）から、前記目標制動流体圧Ｐcによって発生が予測される制動トルクｇ（Ｐc）を差し引いて目標駆動トルクＴrqdsが算出され、ステップＳ１５で、目標制動流体圧Ｐsf、Ｐsrが前記制動流体圧制御回路７に向けて出力され、目標駆動トルクＴrqdsが前記駆動トルクコントロールユニット１２に向けて出力され、またディスプレイやスピーカで警報動作を行わせる制御信号が警報装置２１に向けて出力される。
【００４６】
このように、本実施形態にあっては、制御開始判断閾値Ｘgsstartを大きく設定することで、減速制御の開始タイミングだけを変えるため、減速制御が開始されてからは、安全性が損なわれない範囲で目標減速度Ｘgsが大きく算出され、自車が適切に減速されて、減速制御の制御効果は維持される。
ちなみに、カーブ進入時に、先行車から取り残される感じを与えないように追従走行制御に切り換える方法では、先行車の運転者が脇見運転等でカーブの存在に気づかないとき等、先行車が十分な減速をせずにカーブに進入したときに自車の安全性が損なわれる恐れがある。
【００４７】
次に、本発明の車両用走行制御装置の第２実施形態について説明する。
この実施形態は、目標車速Ｖrを大きく補正することで、減速制御の開始タイミングを変えるものであり、前記第１実施形態の制駆動力コントロールユニット８で行われる演算処理が、前記第１実施形態の図２のものから、図９のものに変更されている。
【００４８】
この図９の演算処理は、前記第１実施形態の図２の演算処理と同等のステップを多く含んでおり、同等のステップには同等の符号を付して、その詳細な説明を省略する。この図９の演算処理では、図２の演算処理のステップＳ６〜Ｓ１０に代えてステップＳ１６〜Ｓ２０が設けられている。
このうち、まずステップＳ１６では、前記ステップＳ５で設定した路面摩擦係数Ｋμと選択スイッチ２３で設定された旋回横加速度設定値Ｙgselectとに基づいて許容横加速度Ｙglimtを設定する。具体的には、路面摩擦係数Ｋμに旋回横加速度設定値Ｙgselectを乗じて許容横加速度Ｙglimtを設定する。ここで、旋回横加速度設定値Ｙgselectとしては、０．３ｇ〜０．８ｇまで、０．０５ｇ刻みで設定させるものや、０．４ｇ相当である「長」、０．６ｇ相当である「中」、０．８ｇ相当である「短」の三段階で設定させるものを適用する。
【００４９】
このように、本実施形態にあっては、運転者が選択した許容横加速度Ｙglimtと道路の曲率半径Ｒnとに基づいて、当該許容横加速度Ｙglimtを超えないように目標車速Ｖrを算出するため、路面状態から定まる限界旋回速度に制限するだけでなく、運転者の意図に応じた限界速度に制限することができる。
次にステップＳ１７に移行して、前記第１実施形態のステップＳ９と同様の処理を行う。なお、本実施形態においては、第１実施形態と同様に、先行車候補との接近傾向の大きさを示す存在判断指数Ａsを算出し、存在判断指数Ａsが判断しきい値Ａsoより小さいとき、、つまり先行車候補との接近傾向が大きいときだけ、先行車判断フラグＦpcarを“１”のセット状態として、後述する許容横加速度Ｙglimtを大きく補正するため、運転者が先行車の走行状態に応じて自車を減速させているときだけ、減速制御の開始タイミングが遅くされ、運転者がカーブ状態に応じて自車を減速させているときまで、減速制御の開始タイミングが遅くされてしまうことはなく、運転者の違和感が抑制防止される。
【００５０】
また、第１実施形態と同様に、先行車候補が自車線内にあることが検出されているときだけ、許容横加速度Ｙglimt大きく設定することを示す先行車判断フラグＦpcarをセット状態とするため、例えば、他車線に先行車候補があるとき等、運転者が先行車の走行状態に応じて自車を減速させていないとき、つまり運転者がカーブ状態に応じて自車を減速させているときまで、減速制御の開始タイミングが遅くされてしまうことはなく、運転者の違和感が効果的に防止される。
【００５１】
次にステップＳ１８に移行して、運転者の減速操作に影響を与える先行車があるときには、制動力制御の開始タイミングが遅くなるように許容横加速度Ｙglimtを大きく補正する。具体的には、先行車判断フラグＦpcarが“１”のセット状態であるときには、（Ｙglimt、Ｙglimt―Ｋy・Ａs、Ｙglilmtmax）の中間値を新たな許容横加速度Ｙglimtとする。ここで、Ｙglimtmaxはリミット値であり、許容横加速度Ｙglimtを大きくすることに起因して、安全性が損なわれることがない範囲に設定する。なお、存在判断指数Ａsは負値であるため、通常、Ｙglimtが最小値、Ｙglimtmaxが最大値、Ｙglimt−Ｋy*Ａsが中間値となる。また、Ｋyは定数である。
【００５２】
このように、本実施形態にあっては、目標車速Ｖrの算出に用いる許容横加速度Ｙglimtを大きくすることで目標車速Ｖrを大きく補正するため、目標車速Ｖrの補正量に物理的な意味を持たせて、目標車速Ｖrを適切に補正することができる。
これに対して、前記ステップＳ１７で設定された先行車判断フラグＦpcarが“０”のリセット状態であるときには、前記ステップＳ１６で設定された許容横加速度Ｙglimtを新たな許容横加速度Ｙglimtとする。
【００５３】
次にステップＳ１９に移行して、前記第１実施形態のステップＳ７と同様の処理を行う。
次にステップＳ２０に移行して、前記第１実施形態のステップＳ８と同様の処理を行う。
次に、本実施形態の動作について具体的状況に基づいて説明する。
【００５４】
まず、図８（ａ）に示すように、自車がカーブに進入したときに、減速を開始していない先行車が自車線内の自車近傍にあったとする。すると、制駆動力コントロールユニット８で行われる演算処理では、第１実施形態と同様に、まずステップＳ１〜Ｓ５を経て、ステップＳ１６で、前記路面摩擦係数Ｋμと旋回横加速度設定値Ｙgselectとに基づいて許容横加速度Ｙglimtが設定され、ステップＳ１７で、先行車が運転者の減速操作に影響を与えると判定されると、先行車判断フラグＦpcarが“１”のセット状態とされ、ステップＳ１８で、許容横加速度Ｙglimtが大きく補正され、またステップＳ１９で、当該許容横加速度Ｙglimtを超えないように目標車速Ｖrが大きく算出される。ここで、自車から目標ノード地点までの距離が十分に大きいとすると、ステップＳ２０で、当該目標車速Ｖr等に基づいて目標減速度Ｘgsが小さく算出され、またステップＳ１１で、警報開始判断閾値Ｘgswarnが大きく設定され、当該警報開始判断閾値Ｘgswarnが前記目標減速度Ｘgsより大きいと、警報作動フラグｆlgwarnが“０”のリセット状態とされ、また前記制御開始判断閾値Ｘgsstartが目標減速度Ｘgsより大きいと、ステップＳ１２で、作動状態フラグｆlggensokuが“０”のリセット状態とされ、ステップＳ１３で、運転者の制動操作によるマスタシリンダ圧Ｐmが前輪用目標制動流体圧Ｐsfとされ、その前輪用目標制動流体圧Ｐsfに基づいて、最適な前後制動力配分となるように後輪用目標制動流体圧Ｐsrが算出され、ステップＳ１４で、アクセル開度Ａccに応じて算出される目標駆動トルクｆ（Ａcc）が目標駆動トルクＴrqdsとされ、ステップＳ１５で、目標制動流体圧Ｐsf、Ｐsrが前記制動流体圧制御回路７に向けて出力され、目標駆動トルクＴrqdsが前記駆動トルクコントロールユニット１２に向けて出力される。
【００５５】
このように、本実施形態にあっては、第１実施形態と同様に、自車のカーブ進入時に、減速を開始していない先行車があるときには、減速制御の開始タイミングを遅くするため、自車が先に減速してしまうことが防止され、先行車から取り残されるように感じさせることなく、運転者に違和感を与えてしまうことが防止される。
【００５６】
上記フローが繰り返されるうちに、図８（ｂ）に示すように、先行車が減速を開始して、先行車との車間距離等が減少傾向にあるとする。すると、制駆動力コントロールユニット８で行われる演算処理では、前記ステップＳ１〜Ｓ１９を経て、ステップＳ２０で、当該目標車速Ｖr等に基づいて目標減速度Ｘgsが大きく算出され、前記ステップＳ１１で、再び警報開始判断閾値Ｘgswarnが大きく設定されるが、前記目標減速度Ｘgsが当該警報開始判断閾値Ｘgswarnより大きいと、警報作動フラグｆlgwarnが“１”のセット状態とされ、また前記目標減速度Ｘgsが制御開始判断閾値Ｘgsstartより大きいと、ステップＳ１２で、作動状態フラグｆlggensokuが“１”のセット状態とされ、ステップＳ１３で、前記目標減速度Ｘgsにブレーキ諸元等から定まる定数Ｋｂを乗じて目標制動流体圧Ｐcが算出され、当該目標制動流体圧Ｐcと運転者の制動操作によるマスタシリンダ圧Ｐmとのうち、大きい方が前輪用目標制動流体圧Ｐsfとされ、その前輪用目標制動流体圧Ｐsfに基づいて、最適な前後制動力配分となるように後輪用目標制動流体圧Ｐsrが算出され、ステップＳ１４で、前記アクセル開度Ａccに応じて算出される目標駆動トルクｆ（Ａcc）から、前記目標制動流体圧Ｐcによって発生が予測される制動トルクｇ（Ｐc）を差し引いて目標駆動トルクＴrqdsが算出され、ステップＳ１５で、目標制動流体圧Ｐsf、Ｐsrが前記制動流体圧制御回路７に向けて出力され、目標駆動トルクＴrqdsが前記駆動トルクコントロールユニット１２に向けて出力され、またディスプレイやスピーカで警報動作を行わせる制御信号が警報装置２１に向けて出力される。
【００５７】
このように、本実施形態にあっては、許容横加速度Ｙglimtを大きく補正して目標車速Ｖrを大きく設定することで、減速制御の開始タイミングを変えるため、カーブに進入してからの走行速度Ｖが、安全性が損なわれない範囲で大きくなり、カーブ走行中も先行車から取り残されるように感じさせることなく、運転者に違和感を与えてしまうことが防止される。
【００５８】
ちなみに、自車前方の道路のカーブ情報のみに応じて減速制御を行う従来の方法では、カーブに進入してからも減速を開始せず、安全性が損なわれない範囲の速度で走行している先行車があるときには、自車の減速制御が行われると、先行車との車間距離が徐々に大きくなっていき、当該先行車から取り残されるように感じさせ、運転者に違和感を与えてしまう。
【００５９】
なお、上記実施の形態にあっては、カーナビゲーションシステム１５及びステップＳ３はカーブ情報検出手段及び前方カーブ情報検出手段に対応し、車輪速度センサ２０ＦＬ〜２０ＲＲ及びステップＳ２は車速検出手段に対応し、制駆動力コントロールユニット８、ステップＳ８及びＳ２０は減速手段に対応し、車間距離センサ２２、ステップＳ９及びＳ１７は先行車検出手段に対応し、ステップＳ１０及びＳ１９は減速制御開始遅延手段に対応し、ステップＳ７及びＳ１７は目標車速設定手段に対応し、ステップＳ８及びＳ２０は目標減速度設定手段に対応し、ステップＳ１０は減速制御開始閾値設定手段に対応し、ステップＳ９及びＳ１７は接近傾向検出手段及び先行車位置検出手段に対応し、操舵角センサ１９は操舵角検出手段に対応し、ステップＳ５は摩擦係数検出手段に対応し、選択スイッチ２３は許容横加速度設定手段に対応し、警報装置２１は報知手段に対応し、ステップＳ１５は報知開始遅延手段に対応する。
【００６０】
また、上記実施の形態は本発明の車両用走行制御装置の一例を示したものであり、装置の構成等を限定するものではない。
上記実施の形態では、目標減速度Ｘgsを目標車速Ｖr等に基づいて算出する例を示したが、これに限られるものではなく、例えば目標減速度Ｘgsを道路の勾配に基づいて補正するようにしてもよく、そのようにすれば、道路が上り勾配であるときに、目標減速度Ｘgsを小さく補正して減速度が大きくなりすぎることが防止でき、また、道路が下り勾配であるときに、目標減速度Ｘgsを大きく補正して減速度が不十分になることを防止できる。
【００６１】
また、目標減速度Ｘgsが（Ｘgsstart−Ｋh）より小さくなったときに減速制御を停止する例を示したが、これに限られるものではなく、例えばカーナビゲーションシステム１５で検出されたノード情報に基づいて、車両が目標ノード地点を通過したことが検出されてからは減速制御を停止するようにしてもよく、そのようにすれば、旋回が困難な地点に到達するまでの間だけ減速制御が継続されることとなり、運転者の意図に調和しやすく、乗員の違和感を抑制防止できる。
【図面の簡単な説明】
【図１】本発明の車両用走行制御装置を搭載した車両の一例を示す概略構成図である。
【図２】図１の制駆動力コントロールユニット内で実行される情報演算処理の第１実施形態を示すフローチャートである。
【図３】目標ノード地点を説明するための説明図である。
【図４】走行速度と許容横加速度算出係数との関係を説明するためのグラフである。
【図５】目標減速度の算出方法を説明するための説明図である。
【図６】操舵角と制御量制限値との関係を説明するためのグラフである。
【図７】操舵角と制御量制限値と走行速度との関係を説明するためのグラフである。
【図８】本発明の車両用走行制御装置を搭載した車両の動作を説明するための図である。
【図９】図９の制駆動力コントロールユニット内で実行される情報演算処理の第２実施形態を示すフローチャートである。
【符号の説明】
６ＦＬ〜６ＲＲはホイールシリンダ
７は制動流体圧制御回路
８は制駆動力コントロールユニット
９はエンジン
１０は自動変速機
１１はスロットルバルブ
１２は駆動トルクコントロールユニット
１３はＧＰＳ
１４は記憶媒体
１５はカーナビゲーションシステム
１６はマスタシリンダ圧センサ
１７はアクセル開度センサ
１８はステアリングホイール
１９は操舵角センサ
２０ＦＬ〜２０ＲＲは車輪速度センサ
２１は警報装置
２２は車間距離センサ
２３は選択スイッチ[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicular travel control device that detects road information ahead of a vehicle and performs vehicle travel control based on the road information.
[0002]
[Prior art]
Conventionally, as such a vehicular travel control device, road information ahead of the vehicle is detected, an appropriate speed is calculated based on the road information, and when the vehicle's curve approach speed is greater than the appropriate speed, the curve A technique for performing deceleration control when entering is known (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP-A-4-236699
[0004]
[Problems to be solved by the invention]
By the way, normally, when there is a preceding vehicle when entering a curve, the driver tends to decelerate the own vehicle according to the traveling state of the preceding vehicle. However, in the above conventional technique, the deceleration control is performed only according to the road information ahead of the host vehicle. For example, when there is a preceding vehicle that has not started deceleration when the host vehicle enters the curve, the deceleration is performed. When the control is performed, the inter-vehicle distance from the preceding vehicle gradually increases, which may cause the driver to feel left behind from the preceding vehicle, which may cause the driver to feel uncomfortable.
Accordingly, the present invention has been made paying attention to the unsolved problems of the above-described conventional technology, and it is an object to provide a vehicle travel control device that can prevent the driver from feeling uncomfortable. And
[0005]
[Means for Solving the Problems]
  In order to solve the above-described problems, a vehicle travel control device according to the present invention is a vehicle travel control device that performs deceleration control based on curve information of a road ahead of the host vehicle and the host vehicle speed.And has not started deceleratingWhen there is a preceding vehicle, the start timing of the deceleration control is delayed.
[0006]
【The invention's effect】
  Therefore, in the vehicle travel control device according to the present invention,And has not started deceleratingIn order to delay the start timing of the deceleration control when there is a preceding vehicle, for example, when there is a preceding vehicle that has not started deceleration when the vehicle enters the curve, the start timing of the deceleration control is delayed. It is possible to prevent the vehicle from decelerating first, and to prevent the driver from feeling uncomfortable without making the vehicle feel left behind.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of a vehicular travel control apparatus of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a schematic vehicle configuration diagram illustrating an example of a vehicle travel control apparatus according to the present embodiment. This vehicle is a rear wheel drive vehicle equipped with an automatic transmission and a conventional differential gear, and the braking device can control the braking force of the left and right wheels independently of the front and rear wheels.
[0008]
In the figure, reference numeral 1 is a brake pedal, 2 is a booster, 3 is a master cylinder, and 4 is a reservoir. Normally, the brake fluid pressure boosted by the master cylinder 3 depends on the amount of depression of the brake pedal 1 by the driver. The wheels 5FL to 5RR are supplied to the wheel cylinders 6FL to 6RR. Further, a braking fluid pressure control circuit 7 is interposed between the master cylinder 3 and each wheel cylinder 6FL-6RR. The braking fluid pressure control circuit 7 includes a braking fluid for each wheel cylinder 6FL-6RR. It is also possible to control the pressure individually.
[0009]
The brake fluid pressure control circuit 7 uses a brake fluid pressure control circuit used for, for example, anti-skid control and traction control. In this embodiment, the brake fluid pressures of the wheel cylinders 6FL to 6RR are independently set. It is configured so that the pressure can be increased or decreased. The brake fluid pressure control circuit 7 controls the brake fluid pressures of the wheel cylinders 6FL to 6RR in accordance with a brake fluid pressure command value from a braking / driving force control unit 8 described later.
[0010]
In addition, the vehicle controls the driving torque to the rear wheels 5RL and 5RR, which are driving wheels, by controlling the operating state of the engine 9, the selected transmission ratio of the automatic transmission 10, and the throttle opening of the throttle valve 11. A drive torque control unit 12 is provided. The operation state control of the engine 9 can be controlled, for example, by controlling the fuel injection amount and the ignition timing, and can also be controlled by controlling the throttle opening at the same time. The drive torque control unit 12 can independently control the drive torque of the rear wheels 5RL and 5RR that are drive wheels. However, the drive torque command value from the braking / driving force control unit 8 described above can be controlled. When input, the drive wheel torque is controlled with reference to the drive torque command value.
[0011]
Thus, in this embodiment, since the vehicle is decelerated using at least one of the output reduction of the engine 9, the gear ratio change of the automatic transmission 10, and the output increase of the wheel cylinder 6, the vehicle Can be decelerated appropriately.
Further, this vehicle includes a car navigation system 15 having a GPS 13 for detecting vehicle position information (Xo, Yo) and a storage medium 14 storing map information such as road shape. The car navigation system 15 refers to the map information stored in the storage medium 14 based on the position information (Xo, Yo) detected by the GPS 13, and the inter-vehicle distance to the node point on the road ahead of the vehicle Node information (Xn, Yn, Ln) consisting of Ln and the absolute coordinates (Xn, Yn) of the node point is calculated.
[0012]
Thus, in this embodiment, since node information is detected using the car navigation system 15, if it is a road where node information is stored, node information can be easily acquired regardless of a special external device. .
Further, an inter-vehicle distance sensor 22 that detects an inter-vehicle distance Lx and a relative speed dLy from the preceding vehicle candidate and a lateral distance Ly from the front-rear direction axis of the own vehicle to the preceding vehicle candidate is provided at the lower front portion of the vehicle. . The inter-vehicle distance sensor 22 detects, for example, the time from when the laser beam is swept to when the reflected light of the preceding vehicle is received and the scanning direction of the laser beam to detect the inter-vehicle distance Lx and the lateral distance Ly. Is detected, and the detected value of the inter-vehicle distance Lx is differentiated to calculate the relative speed dLx with the preceding vehicle, and the inter-vehicle distance Lx and the lateral distance Ly are calculated from the image of the laser radar, millimeter wave radar, and preceding vehicle. Apply an image processing device. The inter-vehicle distance sensor 22 may be applied in combination with the laser radar, the millimeter wave radar, the image processing device, and the like. In this case, the accuracy can be further improved and the detection area can be expanded. Can do.
[0013]
Further, the vehicle includes a master cylinder pressure sensor 16 that detects an output pressure of the master cylinder 3, that is, a so-called master cylinder pressure Pm, an accelerator opening sensor 17 that detects an accelerator pedal depression amount, that is, an accelerator opening Acc, a steering wheel. A steering angle sensor 19 for detecting the steering angle θ of the wheel 18 and wheel speed sensors 20FL to 20RR for detecting a rotation speed of each wheel 5FL to 5RR, that is, a so-called wheel speed Vwi (i = FL to RR) are arranged and detected. The signal is output to the braking / driving force control unit 8. If the vehicle running state data has left and right directions, the left direction is the positive direction. That is, the steering angle θ and the like have positive values when turning left.
[0014]
The steering wheel 18 of the vehicle is provided with a selection switch 23 for allowing the driver to select the turning lateral acceleration set value Ygselect, and a display or speaker for notifying that deceleration control is started is provided in the vehicle interior. The provided warning device 21 is arranged, and in response to a command from the braking / driving force control unit 8, the start of braking force control and the like are presented to the driver.
[0015]
Next, the logic of the arithmetic processing performed in the braking / driving force control unit 8 will be described with reference to the flowchart of FIG. This calculation process is executed by a timer interruption every predetermined sampling time ΔT every 10 msec., For example. In this flowchart, no communication step is provided, but information obtained by the arithmetic processing is updated and stored in the storage device as needed, and necessary information is read out from the storage device as needed.
[0016]
In this calculation process, first, in step S1, various data are read from each sensor, controller, and control unit. Specifically, each wheel speed Vwi, accelerator opening Acc, master cylinder pressure Pm, steering angle θ detected by each sensor, driving torque Tw from driving torque control unit 12, and inter-vehicle distance Lx from inter-vehicle distance sensor 22 The relative speed dLx, the lateral distance Ly, the vehicle position information (Xo, Yo) and the node information (Xn, Yn, Ln) of the node point are read from the car navigation system 15.
[0017]
Next, the process proceeds to step S2, and the running speed V of the vehicle is calculated from the average value of the front left and right wheel speeds VwFL and VwFR which are non-driven wheels among the wheel speeds Vwi read in step S1. When the ABS control device or the like is operating, the estimated vehicle speed estimated in the ABS control device may be used as the vehicle traveling speed V.
Next, the process proceeds to step S3, and the curvature radius Rn of the road at each node point is calculated based on the node information (Xn, Yn, Ln) read in step S1. Specifically, first, node information of the node point n-1 from the vehicle position is (Xn-1, Yn-1, Ln-1), and node information of the node point n is (Xn, Yn). , Ln), and (Xn + 1, Yn + 1, Ln + 1) as node information of the n + 1th node point, variables xa, ya, xb, yb are calculated according to the following equation (1).
[0018]
xa = K. (xn-xn-1)
ya = K. (yn-yn-1)
xb = K. (xn + 1-xn-1)
yb = K · (yn + 1−yn−1) (1)
However, Ko = (Xn-Xn-1)²+ (Yn-Yn-1)²
K = (Ln-Ln-1) / (Ko)^1/2
Next, based on the variables xa, ya, xb, yb calculated by the above equation (1), the variables XR, YR, R according to the following equation (2):_R, A is calculated.
[0019]
XR = (Ca · yb−Cb · ya) / A
YR = (Ca.xa-Cb.xb) / A
R_R= XR²+ YR²            ……… (2)
However, Ca = (xa²+ Ya²) / 2
Cb = (xb²+ Yb²) / 2
A = xb · yb-xb · ya
And when the variable A calculated by the above equation (2) is smaller than 0.01, or the variable R_RIs larger than 4000000 m, the curvature radius Rn of the road is calculated to be 2000 m at the n-th node point from the own vehicle position. Otherwise, the curvature radius Rn is calculated according to the following equation (3). . The curvature radius Rn of the road becomes a negative value when turning left.
[0020]
Rn = A / | A | ・ (R_R)^1/2  ……… (3)
Here, the curvature radius R of the road is obtained from the three node information._RHas been shown, but the radius of curvature R_RIs not limited, for example, the radius of curvature R_RA straight line connecting the preceding and following node points is calculated with respect to the point where the point is to be calculated, and the curvature radius R is calculated based on the slope of the straight line._RMay be calculated. Also, the coordinates of the node point are read from the car navigation system 15 and the curvature radius R is based on the coordinates._RThe radius of curvature R as node information is shown in the car navigation system 15._RMay be stored in advance, and the value may be read directly from the car navigation system 15.
[0021]
Next, the process proceeds to step S4, and a target node point that is a point at which the vehicle is to be most decelerated is calculated from the node points from which the node information is read in step S1. Specifically, as shown in FIG. 3, the radius of curvature R calculated in step S3 from among the node points ahead of the host vehicle._RIs the node point where is the minimum, and the one closest to the vehicle position is calculated. Thus, in this embodiment, since the node point where the curvature radius of the road ahead of the vehicle is minimum is detected, appropriate braking force control can be performed.
[0022]
Next, the process proceeds to step S5, where the road surface friction coefficient Kμ is calculated. Specifically, as described in Japanese Patent Application Laid-Open No. 2001-171504, the road surface friction coefficient Kμ is based on the relationship between the braking / driving force acting on the wheels 5FL to 5RR and the slip state of the wheels 5FL to 5RR. Is calculated.
The method of calculating the road surface friction coefficient Kμ is not limited to the above method, and an infrastructure device that detects the road surface friction coefficient Kμ or an infrastructure device that stores the road surface friction coefficient Kμ is installed at the curve entrance. Information on the road surface friction coefficient Kμ may be acquired from the infrastructure device. Further, the driver may be allowed to input with a manual switch or the like, for example, a “high g switch” to be operated when equivalent to 0.8 g, a “medium g switch” to be operated when equivalent to 0.6 g, 0 By providing a “low g switch” or the like that is operated when it is equivalent to 4 g and roughly setting it, the driver can easily input.
[0023]
Next, the process proceeds to step S6, where the allowable lateral acceleration Yglimt is calculated based on the road surface friction coefficient Kμ calculated in step S5. Specifically, the allowable lateral acceleration Yglimt is calculated by multiplying the road surface friction coefficient Kμ calculated in step S5 by an allowable lateral acceleration calculation coefficient Ks (for example, “0.8”). The allowable lateral acceleration calculation coefficient Ks is not limited to a fixed value. As shown in FIG. 4, when the traveling speed V is equal to or higher than a predetermined value, the allowable lateral acceleration calculation coefficient Ks is a function value that decreases as the traveling speed V increases. There may be.
[0024]
Next, the process proceeds to step S7, where the target vehicle speed Vr is calculated based on the allowable lateral acceleration Yglimt calculated in step S6. Specifically, the target vehicle speed Vr is calculated according to the following equation (4) based on the curvature radius Rn of the target node point calculated in step S4 and the allowable lateral acceleration Yglimt calculated in step S6.
Vr = (Yglimt · | Rn |)^1/2  ……… (4)
Thus, in the present embodiment, the allowable lateral acceleration Yglimt is calculated based on the road surface friction coefficient Kμ of the road ahead of the host vehicle, and based on the allowable lateral acceleration Yglimt and the curvature radius Rn of the road ahead of the host vehicle. Since the target vehicle speed Vr is calculated, an appropriate target vehicle speed Vr can be calculated.
[0025]
Next, the process proceeds to step S8, where the target deceleration Xgs is calculated based on the target vehicle speed Vr calculated in step S7. Specifically, as shown in FIG. 5, the target deceleration Xgs according to the following equation (5) based on the travel speed V calculated in step S2 and the inter-vehicle distance Ln to the target node point calculated in step S4. Is calculated.
[0026]

The target deceleration Xgs takes a positive value during deceleration.
As described above, in the present embodiment, the inter-vehicle distance Ln to the target node point where the curvature radius of the road ahead of the vehicle becomes the minimum and the curvature radius Rn at the target node point are detected, and the target is determined accordingly. In order to calculate the deceleration Xgs, an appropriate target deceleration can be set.
[0027]
Next, the process proceeds to step S9, where the preceding vehicle candidate affects the driver's deceleration operation based on the inter-vehicle distance Lx and the relative speed dLx with the preceding vehicle candidate detected by the inter-vehicle distance sensor 22. Determine if it is a car. Specifically, first, based on the inter-vehicle distance Lx and lateral distance Ly detected by the inter-vehicle distance sensor 22, the steering angle θ detected by the steering angle sensor 19, and the traveling speed V calculated in step S2. Then, it is determined whether the preceding vehicle candidate is in the own lane. When the preceding vehicle candidate is in the own lane, based on the inter-vehicle distance Lx and the relative speed dLx with the preceding vehicle candidate, the presence determination index As indicating the magnitude of the approaching tendency with the preceding vehicle candidate is calculated according to the following equation (6). When the presence determination index As is smaller than the determination threshold value Aso (for example, “0”), the preceding vehicle candidate is a preceding vehicle that affects the driver's deceleration operation, that is, the driver travels on the preceding vehicle. It is determined that the host vehicle is decelerating according to the state, and a preceding vehicle determination flag Fpcar indicating that a control start determination threshold value Xgsstart described later is largely corrected is set to “1”. Note that the presence determination index As is smaller as the approaching tendency to the preceding vehicle is larger, that is, is increased in the negative direction. Further, the determination threshold value Aso is not limited to a constant, and may be changed according to the road surface μ, for example.
[0028]
As = Kap · (Lx−Lc) + Kad · dLx (6)
Here, Kap and Kad are weighting factors. Lc is an inter-vehicle distance reference value, which is calculated by multiplying the traveling speed V calculated in step S2 by a constant Kv1, and adding the constant Kv2 to the multiplication result.
As described above, in this embodiment, at least one of laser radar, millimeter wave radar, and image processing device is used to detect the relative speed dLx and the inter-vehicle distance Lx with the preceding vehicle candidate, and based on the detection result. Since the preceding vehicle is detected, the preceding vehicle can be detected accurately and inexpensively.
[0029]
Next, when the preceding vehicle candidate is in the own lane and the presence determination index As is equal to or greater than the determination threshold value Aso, the preceding vehicle candidate is not a preceding vehicle that affects the driver's deceleration operation. It is determined that the host vehicle is decelerating according to the curve state regardless of the traveling state of the preceding vehicle, and the preceding vehicle determination flag Fpcar is set to a reset state of “0”.
[0030]
Thus, in the present embodiment, the presence determination index As indicating the magnitude of the approaching tendency with the preceding vehicle candidate is calculated, and when the presence determination index As is smaller than the determination threshold value Aso, that is, with the preceding vehicle candidate. Only when the approaching tendency is large, the preceding vehicle judgment flag Fpcar is set to “1” and the control start judgment threshold value Xgsstart described later is greatly corrected, so that the driver decelerates the own vehicle according to the traveling state of the preceding vehicle. The deceleration control start timing is delayed only when the driver is decelerating, and the deceleration control start timing is not delayed until the driver is decelerating the vehicle according to the curve state. Is suppressed and prevented.
[0031]
On the other hand, when there is a preceding vehicle candidate on another lane, or when the above condition is not satisfied, the preceding vehicle determination flag Fpcar is reset to “0”.
Thus, in the present embodiment, the preceding vehicle determination flag Fpcar indicating that the control start determination threshold value Xgsstart is set to be larger is set to the set state only when it is detected that the preceding vehicle candidate is in the own lane. Therefore, for example, when there is a preceding vehicle candidate in another lane, the driver does not decelerate the vehicle according to the traveling state of the preceding vehicle, that is, the driver decelerates the vehicle according to the curve state. Until this time, the start timing of the deceleration control is not delayed, and the driver's uncomfortable feeling is effectively prevented.
[0032]
Next, the process proceeds to step S10, and when there is a preceding vehicle that affects the driver's deceleration operation, the control start determination threshold value Xgsstart is set large so that the start timing of the braking force control is delayed. Specifically, when the preceding vehicle determination flag set in step S9 is set to “1”, an intermediate value of (Xgsstarto, Xgsstarto−As, Xgsstartmax) is set as a control start determination threshold value Xgsstart. Here, Xgsmax is a limit value, and is set within a range in which the effect of the braking force control is not impaired due to delaying the start timing of the braking force control. Since the existence determination index As is a negative value, Xgsstarto is normally a minimum value, Xgsstartmax is a maximum value, and Xgsstarto-As is an intermediate value.
[0033]
On the other hand, when the preceding vehicle determination flag Fpcar set in step S9 is in the reset state, the pre-correction control start determination threshold value Xgsstarto is set as the control start determination threshold value Xgsstart.
Next, when the process proceeds to step S11 and the braking force control start timing is delayed, the alarm start determination threshold value Xgswarn is set to be large so that the alarm start timing is delayed, and the alarm is activated based on the alarm start determination threshold value Xgswarn. Set the flag flgwarn. Specifically, when the alarm activation flag flgwarn set when this calculation process was executed last time is “0”, the target deceleration Xgs calculated in step S8 is a predetermined threshold value. (Hereinafter also referred to as an alarm start determination threshold value.) When Xgswarn or higher, the alarm operation flag flgwarn is set to “1”.
[0034]
Here, the alarm start determination threshold value Xgswarn is set to a predetermined alarm start determination threshold value Xgswarno when the preceding vehicle determination flag Fpcar is in a reset state of “0”, and the preceding vehicle determination flag Fpcar is set to “1”. In some cases, an intermediate value of (Xgswarno, Xgswarno-As, Xgswarnmax) is set. Here, Xgswarnmax is a limit value and is set in a range in which the effect of the alarm is not impaired due to the delay of the alarm start timing.
[0035]
As described above, in this embodiment, when there is a preceding vehicle that affects the driver's deceleration operation, that is, when the start timing of the deceleration control is delayed, the alarm start timing is also delayed, so the alarm is performed at an appropriate timing. .
Next, when the alarm operation flag flgwarn set when this calculation process was executed last time is set to “1”, when the target deceleration Xgs is equal to or greater than (Xgswarn−Khwarn), the alarm operation flag flgwarn is set. Set to “1”. Here, Khwarn is a constant for preventing alarm hunting, and is set to 0.03 g, for example.
[0036]
On the other hand, when the target condition Xgs calculated in step S8 is smaller than (Xgswarn−Khwarn) or the like does not satisfy the above condition, the alarm activation flag flgwarn is reset to “0”.
Next, the process proceeds to step S12, and a control start determination is performed to determine whether to start the braking force control based on the target deceleration Xgs calculated in step S8. Specifically, when the operation state flag flggensoku set when this calculation process was executed last time is “0”, the target deceleration Xgs calculated in step S8 is set in step S10. When it is equal to or greater than the control start determination threshold value Xgsstart, the operation state flag flggensoku indicating that the braking force control is being performed is set to “1”.
[0037]
Next, when the operation state flag flggensoku set when this calculation process was executed last time is “1”, the target deceleration Xgs calculated in step S8 is equal to or greater than (Xgsstart−Kh). The operating state flag flggensoku is set to “1”. Here, Kh is a constant for preventing hunting of the braking force control.
[0038]
On the other hand, when the above condition is not satisfied, such as when the target deceleration Xgs calculated in step S8 is smaller than (Xgsstart−Kh), the operation state flag flggensoku is set to a reset state of “0”.
Note that the threshold values Xgswarn and Xgsgensoku used in the steps S10 and S11 are not limited to fixed values. For example, the brightness around the vehicle is determined based on the operating state of the headlight, etc. When the periphery is dark and the driver feels a sense of speed, a variation value that changes according to the brightness may be used.
[0039]
Next, the process proceeds to step S13, and the braking fluid pressure supplied to the wheel cylinders 6FL to 6RR of the wheels 5FL to 5RR is calculated. Specifically, it is determined whether or not the operation state flag flggensoku is in the set state. If the operation state flag flggensoku is in the set state, the braking force control is executed, and is first calculated in step S12. The target braking fluid pressure Pc is calculated by multiplying the target deceleration Xgs by a constant Kb determined from the brake specifications, and the larger of the target braking fluid pressure Pc and the master cylinder pressure Pm by the driver's braking operation is calculated. Based on the front-wheel target braking fluid pressure Psf, the rear-wheel target braking fluid pressure Psr is calculated based on the front-wheel target braking fluid pressure Psf so as to achieve an optimal front-rear braking force distribution.
[0040]
On the other hand, when the operation state flag flggensoku is in the reset state of “0”, the braking force control is not executed, and the master cylinder pressure Pm by the driver's braking operation is set to the target braking fluid pressure for the front wheels. In addition to Psf, the rear wheel target braking fluid pressure Psr is calculated based on the front wheel target braking fluid pressure Psf so as to achieve an optimal front-rear braking force distribution.
[0041]
Next, the process proceeds to step S14, and the driving torque for driving the driving wheels 5RL and 5RR is calculated. Specifically, when the operation state flag flggensoku is set to “1”, the step S14 is calculated from the target driving torque f (Acc) calculated according to the accelerator opening Acc read in the step S1. The target driving torque Trqds is calculated by subtracting the braking torque g (Pc) that is predicted to be generated by the target braking fluid pressure Pc calculated in step (b).
[0042]
On the other hand, when the operation state flag flggensoku is in the reset state of “0”, the target drive torque f (Acc) calculated according to the accelerator opening Acc is set as the target drive torque Trqds.
Next, the process proceeds to step S15, and the target braking fluid pressures Psf and Psr of the wheels 5FL to 5RR calculated in step S14 are output to the braking fluid pressure control circuit 7, and the driving calculated in step S14 is performed. When the target driving torque Trqds of the wheels 5RL and 5RR is output to the driving torque control unit 12, and when the alarm operation flag flgwarn is set to “1”, a control signal for performing an alarm operation on a display or a speaker is generated. After output to the alarm device 21, the program returns to the main program.
[0043]
Next, the operation of the present embodiment will be described based on a specific situation.
First, as shown in FIG. 8A, when the host vehicle enters the curve, it is assumed that a preceding vehicle that has not started decelerating is in the vicinity of the host vehicle in the host lane. Then, in the calculation process performed by the braking / driving force control unit 8, first, in step S1, various data are read from the respective sensors, etc., the vehicle traveling speed V is calculated in step S2, and the own vehicle is determined in step S3. The radius of curvature Rn of the road at each node point ahead is calculated. In step S4, the target node point that is the point where the host vehicle is to be most decelerated is calculated. In step S5, the road surface friction coefficient Kμ is calculated. In step S6, the allowable lateral acceleration Yglimt at the target node point is calculated based on the road surface friction coefficient Kμ. In step S7, the target vehicle speed Vr is calculated so as not to exceed the allowable lateral acceleration Yglimt. Here, if the distance from the own vehicle to the target node point is sufficiently large, the target deceleration Xgs is calculated to be small based on the target vehicle speed Vr and the like in step S8, and the preceding vehicle is the driver in step S9. Is determined to affect the deceleration operation of the vehicle, the preceding vehicle determination flag Fpcar is set to “1”, the control start determination threshold value Xgsstart is set large in step S10, and the alarm start determination is performed in step S11. When the threshold value Xgswarn is set large and the alarm start determination threshold value Xgswarn is larger than the target deceleration Xgs, the alarm activation flag flgwarn is reset to “0”, and the control start determination threshold value Xgsstart is set lower than the target deceleration Xgs. If larger, the operation state flag flggensoku is reset to “0” in step S12, and in step S13, the master by the driver's braking operation is set. The cylinder pressure Pm is set as the front-wheel target braking fluid pressure Psf, and the rear-wheel target braking fluid pressure Psr is calculated based on the front-wheel target braking fluid pressure Psf so that the optimum front-rear braking force distribution is obtained, step S14. Thus, the target drive torque f (Acc) calculated according to the accelerator opening Acc is set as the target drive torque Trqds, and the target brake fluid pressures Psf and Psr are output to the brake fluid pressure control circuit 7 in step S15. Then, the target drive torque Trqds is output toward the drive torque control unit 12.
[0044]
Thus, in this embodiment, when there is a preceding vehicle that has not started deceleration when the vehicle enters the curve, the vehicle is decelerated first in order to delay the start timing of the deceleration control. This prevents the driver from feeling uncomfortable without feeling left behind from the preceding vehicle.
By the way, in the conventional method of performing deceleration control only according to the curve information of the road ahead of the host vehicle, when there is a preceding vehicle that has not started deceleration when the host vehicle enters the curve, the host vehicle deceleration control is performed. As a result, the distance between the preceding vehicle and the preceding vehicle gradually increases, causing the driver to feel left behind from the preceding vehicle, and the driver feels uncomfortable.
[0045]
While the above flow is repeated, it is assumed that the preceding vehicle starts to decelerate and the distance between the preceding vehicle and the like is decreasing as shown in FIG. Then, in the calculation process performed by the braking / driving force control unit 8, the target deceleration Xgs is largely calculated in the step S8 through the steps S1 to S7, and after the steps S9 and S10, in the step S11. The alarm start determination threshold value Xgswarn is again set to a large value. If the target deceleration Xgs is larger than the alarm start determination threshold value Xgswarn, the alarm activation flag flgwarn is set to “1”, and the target deceleration Xgs is If it is larger than the control start determination threshold value Xgsstart, the operation state flag flggensoku is set to "1" in step S12, and in step S13, the target deceleration Xgs is multiplied by a constant Kb determined from the brake specifications, etc. The fluid pressure Pc is calculated, and is greater than the target braking fluid pressure Pc and the master cylinder pressure Pm generated by the driver's braking operation. Is the front wheel target braking fluid pressure Psf, and based on the front wheel target braking fluid pressure Psf, the rear wheel target braking fluid pressure Psr is calculated so as to achieve an optimum front-rear braking force distribution. In step S14, A target driving torque Trqds is calculated by subtracting a braking torque g (Pc) that is predicted to be generated by the target braking fluid pressure Pc from a target driving torque f (Acc) calculated in accordance with the accelerator opening Acc. In S15, the target brake fluid pressures Psf and Psr are output toward the brake fluid pressure control circuit 7, the target drive torque Trqds is output toward the drive torque control unit 12, and an alarm operation is performed with a display or a speaker. A control signal to be output is output toward the alarm device 21.
[0046]
As described above, in the present embodiment, the control start determination threshold value Xgsstart is set to be large so that only the start timing of the deceleration control is changed. Therefore, the range in which the safety is not impaired after the deceleration control is started. Thus, the target deceleration Xgs is greatly calculated, the host vehicle is appropriately decelerated, and the control effect of the deceleration control is maintained.
By the way, with the method of switching to follow-up driving control so as not to feel left behind from the preceding vehicle when entering the curve, the preceding vehicle is sufficiently slowed down when the driver of the preceding vehicle does not notice the presence of a curve due to driving aside. There is a risk that the safety of the vehicle may be impaired when entering the curve without doing.
[0047]
Next, a second embodiment of the vehicle travel control apparatus of the present invention will be described.
In this embodiment, the start timing of the deceleration control is changed by largely correcting the target vehicle speed Vr, and the arithmetic processing performed by the braking / driving force control unit 8 of the first embodiment is the same as that of the first embodiment. 2 is changed to that of FIG.
[0048]
The arithmetic processing in FIG. 9 includes many steps equivalent to the arithmetic processing in FIG. 2 of the first embodiment, and the same steps are denoted by the same reference numerals and detailed description thereof is omitted. In the calculation process of FIG. 9, steps S16 to S20 are provided instead of steps S6 to S10 of the calculation process of FIG.
Among these, first, in step S16, the allowable lateral acceleration Yglimt is set based on the road surface friction coefficient Kμ set in step S5 and the turning lateral acceleration set value Ygselect set by the selection switch 23. Specifically, the allowable lateral acceleration Yglimt is set by multiplying the road surface friction coefficient Kμ by the turning lateral acceleration setting value Ygselect. Here, as the turning lateral acceleration set value Ygselect, a value set in increments of 0.05 g from 0.3 g to 0.8 g, “long” corresponding to 0.4 g, and “medium” corresponding to 0.6 g are used. , And those set in three stages of “short” equivalent to 0.8 g are applied.
[0049]
Thus, in the present embodiment, the target vehicle speed Vr is calculated based on the allowable lateral acceleration Yglimt selected by the driver and the curvature radius Rn of the road so as not to exceed the allowable lateral acceleration Yglimt. Not only the limit turning speed determined from the road surface state but also the limit speed according to the driver's intention can be limited.
Next, the process proceeds to step S17, and the same processing as in step S9 of the first embodiment is performed. In the present embodiment, as in the first embodiment, the presence determination index As indicating the magnitude of the approaching tendency with the preceding vehicle candidate is calculated, and when the presence determination index As is smaller than the determination threshold value Aso, That is, only when the approaching tendency with the preceding vehicle candidate is large, the preceding vehicle determination flag Fpcar is set to “1” and the allowable lateral acceleration Yglimt described later is greatly corrected, so that the driver responds to the traveling state of the preceding vehicle. The deceleration control start timing is delayed only when the host vehicle is decelerated, and the deceleration control start timing is delayed until the driver decelerates the host vehicle according to the curve state. In addition, the driver's uncomfortable feeling is suppressed and prevented.
[0050]
Similarly to the first embodiment, only when it is detected that the preceding vehicle candidate is in the own lane, the preceding vehicle determination flag Fpcar indicating that the allowable lateral acceleration Yglimt is set large is set in the set state. For example, when the driver is not decelerating the vehicle according to the traveling state of the preceding vehicle, such as when there is a preceding vehicle candidate in another lane, that is, when the driver is decelerating the vehicle according to the curve state Thus, the start timing of the deceleration control is not delayed, and the driver's uncomfortable feeling is effectively prevented.
[0051]
Next, the process proceeds to step S18, and when there is a preceding vehicle that affects the driver's deceleration operation, the allowable lateral acceleration Yglimt is largely corrected so that the start timing of the braking force control is delayed. Specifically, when the preceding vehicle determination flag Fpcar is set to “1”, the intermediate value of (Yglimt, Yglimt−Ky · As, Yglilmtmax) is set as a new allowable lateral acceleration Yglimt. Here, Yglimtmax is a limit value, and is set in a range in which safety is not impaired due to an increase in the allowable lateral acceleration Yglimt. Since the existence determination index As is a negative value, Yglimt is normally a minimum value, Yglimtmax is a maximum value, and Yglimt−Ky * As is an intermediate value. Ky is a constant.
[0052]
As described above, in the present embodiment, the target vehicle speed Vr is largely corrected by increasing the allowable lateral acceleration Yglimt used for calculating the target vehicle speed Vr. Therefore, the correction amount of the target vehicle speed Vr has a physical meaning. Thus, the target vehicle speed Vr can be appropriately corrected.
On the other hand, when the preceding vehicle determination flag Fpcar set in step S17 is in the reset state of “0”, the allowable lateral acceleration Yglimt set in step S16 is set as a new allowable lateral acceleration Yglimt.
[0053]
Next, the process proceeds to step S19, and the same process as step S7 of the first embodiment is performed.
Next, the process proceeds to step S20, and the same processing as in step S8 of the first embodiment is performed.
Next, the operation of the present embodiment will be described based on a specific situation.
[0054]
First, as shown in FIG. 8A, when the host vehicle enters the curve, it is assumed that a preceding vehicle that has not started decelerating is in the vicinity of the host vehicle in the host lane. Then, in the calculation process performed by the braking / driving force control unit 8, first, after steps S1 to S5, in step S16, based on the road surface friction coefficient Kμ and the turning lateral acceleration set value Ygselect, as in the first embodiment. When the allowable lateral acceleration Yglimt is set and it is determined in step S17 that the preceding vehicle affects the driver's deceleration operation, the preceding vehicle determination flag Fpcar is set to "1", and in step S18, The allowable lateral acceleration Yglimt is greatly corrected, and in step S19, the target vehicle speed Vr is calculated so as not to exceed the allowable lateral acceleration Yglimt. If the distance from the vehicle to the target node point is sufficiently large, the target deceleration Xgs is calculated to be small based on the target vehicle speed Vr and the like in step S20, and the alarm start determination threshold value Xgswarn is determined in step S11. Is set to be large and the alarm start determination threshold value Xgswarn is greater than the target deceleration Xgs, the alarm activation flag flgwarn is reset to “0”, and the control start determination threshold value Xgsstart is greater than the target deceleration Xgs. In step S12, the operating state flag flggensoku is reset to "0". In step S13, the master cylinder pressure Pm by the driver's braking operation is set to the front wheel target braking fluid pressure Psf, and the front wheel target braking fluid is set. Based on the pressure Psf, the rear-wheel target braking fluid pressure Psr is calculated so as to achieve the optimal front-rear braking force distribution. The target drive torque f (Acc) calculated according to the degree Acc is set as the target drive torque Trqds, and in step S15, the target brake fluid pressures Psf and Psr are output to the brake fluid pressure control circuit 7, and the target drive Torque Trqds is output toward the drive torque control unit 12.
[0055]
Thus, in the present embodiment, as in the first embodiment, when there is a preceding vehicle that has not started deceleration when the vehicle enters the curve, the start timing of the deceleration control is delayed. It is possible to prevent the vehicle from decelerating first, and to prevent the driver from feeling uncomfortable without feeling left behind from the preceding vehicle.
[0056]
While the above flow is repeated, it is assumed that the preceding vehicle starts to decelerate and the distance between the preceding vehicle and the like is decreasing as shown in FIG. Then, in the calculation process performed by the braking / driving force control unit 8, the target deceleration Xgs is largely calculated based on the target vehicle speed Vr and the like in step S20 through steps S1 to S19, and again in step S11. Although the alarm start determination threshold value Xgswarn is set to be large, if the target deceleration Xgs is larger than the alarm start determination threshold value Xgswarn, the alarm activation flag flgwarn is set to “1”, and the target deceleration Xgs is controlled. If it is larger than the start determination threshold value Xgsstart, the operation state flag flggensoku is set to "1" in step S12. In step S13, the target deceleration Xgs is multiplied by a constant Kb determined from the brake specifications and the like. The pressure Pc is calculated, and the larger one of the target brake fluid pressure Pc and the master cylinder pressure Pm by the driver's braking operation is the front. The wheel target braking fluid pressure Psf is calculated, and the rear wheel target braking fluid pressure Psr is calculated based on the front wheel target braking fluid pressure Psf so as to achieve the optimum front-rear braking force distribution. In step S14, the accelerator The target driving torque Trqds is calculated by subtracting the braking torque g (Pc) that is predicted to be generated by the target braking fluid pressure Pc from the target driving torque f (Acc) calculated according to the opening degree Acc, and in step S15 The target brake fluid pressures Psf and Psr are output toward the brake fluid pressure control circuit 7, the target drive torque Trqds is output toward the drive torque control unit 12, and the alarm operation is performed by a display or a speaker. A signal is output toward the alarm device 21.
[0057]
As described above, in the present embodiment, the allowable lateral acceleration Yglimt is largely corrected and the target vehicle speed Vr is set to be large so as to change the start timing of the deceleration control. However, it becomes large in a range where the safety is not impaired, and it is prevented that the driver feels uncomfortable without feeling left behind from the preceding vehicle even while driving on a curve.
[0058]
By the way, in the conventional method of performing deceleration control only according to the curve information of the road ahead of the host vehicle, the vehicle does not start deceleration even after entering the curve, and travels at a speed that does not impair safety. When there is a preceding vehicle, if the deceleration control of the host vehicle is performed, the inter-vehicle distance from the preceding vehicle gradually increases, and the driver feels left behind from the preceding vehicle, giving the driver a sense of incongruity.
[0059]
In the above embodiment, the car navigation system 15 and step S3 correspond to the curve information detection means and the forward curve information detection means, the wheel speed sensors 20FL to 20RR and step S2 correspond to the vehicle speed detection means, The braking / driving force control unit 8, steps S8 and S20 correspond to deceleration means, the inter-vehicle distance sensor 22, steps S9 and S17 correspond to preceding vehicle detection means, and steps S10 and S19 correspond to deceleration control start delay means, Steps S7 and S17 correspond to the target vehicle speed setting means, steps S8 and S20 correspond to the target deceleration setting means, step S10 corresponds to the deceleration control start threshold setting means, and steps S9 and S17 correspond to the approach tendency detection means and Corresponding to the preceding vehicle position detection means, the steering angle sensor 19 corresponds to the steering angle detection means , Step S5 corresponds to the friction coefficient detection means, selection switch 23 corresponds to the allowable lateral acceleration setting means, the alarm device 21 corresponds to the informing means, step S15 corresponds to the notification start delay means.
[0060]
The above-described embodiment shows an example of the vehicle travel control device of the present invention, and does not limit the configuration of the device.
In the above embodiment, an example in which the target deceleration Xgs is calculated based on the target vehicle speed Vr has been described. However, the present invention is not limited to this. For example, the target deceleration Xgs is corrected based on the road gradient. In this case, when the road is uphill, the target deceleration Xgs can be corrected to be small to prevent the deceleration from becoming too large, and when the road is downhill, The target deceleration Xgs can be greatly corrected to prevent the deceleration from becoming insufficient.
[0061]
Moreover, although the example which stops deceleration control when target deceleration Xgs becomes smaller than (Xgsstart-Kh) was shown, it is not restricted to this, For example, based on the node information detected by the car navigation system 15 Thus, the deceleration control may be stopped after it is detected that the vehicle has passed the target node point, so that the deceleration control is continued until the vehicle reaches a point where turning is difficult. Therefore, it is easy to harmonize with the driver's intention, and the occupant's uncomfortable feeling can be suppressed and prevented.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram showing an example of a vehicle equipped with a vehicle travel control device of the present invention.
FIG. 2 is a flowchart showing a first embodiment of information calculation processing executed in the braking / driving force control unit of FIG. 1;
FIG. 3 is an explanatory diagram for explaining a target node point;
FIG. 4 is a graph for explaining a relationship between a running speed and an allowable lateral acceleration calculation coefficient.
FIG. 5 is an explanatory diagram for explaining a method of calculating a target deceleration.
FIG. 6 is a graph for explaining a relationship between a steering angle and a control amount limit value;
FIG. 7 is a graph for explaining a relationship among a steering angle, a control amount limit value, and a traveling speed.
FIG. 8 is a diagram for explaining the operation of a vehicle equipped with the vehicle travel control device of the present invention.
FIG. 9 is a flowchart showing a second embodiment of information calculation processing executed in the braking / driving force control unit of FIG. 9;
[Explanation of symbols]
6FL-6RR is a wheel cylinder
7 is a brake fluid pressure control circuit
8 is a braking / driving force control unit
9 is the engine
10 is an automatic transmission
11 is a throttle valve
12 is a drive torque control unit.
13 is GPS
14 is a storage medium
15 is a car navigation system.
16 is a master cylinder pressure sensor
17 is an accelerator opening sensor.
18 is a steering wheel
19 is a steering angle sensor
20FL-20RR is a wheel speed sensor
21 is an alarm device
22 is an inter-vehicle distance sensor
23 is a selection switch

Claims (18)

A vehicle travel control device that performs deceleration control based on curve information of a road ahead of the host vehicle and the host vehicle speed,
A vehicle travel control apparatus characterized in that when there is a preceding vehicle that is traveling and has not started deceleration, the start timing of the deceleration control is delayed. Curve information detection means for detecting curve information of the road ahead of the host vehicle, vehicle speed detection means for detecting the host vehicle speed, curve information detected by the curve information detection means, and host vehicle speed detected by the vehicle speed detection means A deceleration means for performing deceleration control based on the vehicle, a preceding vehicle detecting means for detecting a preceding vehicle, and the preceding vehicle detecting means detecting a preceding vehicle that is traveling and has not started decelerating. A vehicle travel control device comprising: deceleration control start delay means for delaying a start timing of deceleration control by the means. Curve information detecting means for detecting curve information of a road ahead of the own vehicle, vehicle speed detecting means for detecting the own vehicle speed, and target vehicle speed setting means for setting a target vehicle speed based on the curve information detected by the curve information detecting means Target deceleration setting for setting a target deceleration based on the target vehicle speed set by the target vehicle speed setting means, the own vehicle speed detected by the vehicle speed detection means, and the curve information detected by the curve information detection means Means,
When the absolute value of the target deceleration set by the target deceleration setting means is larger than a predetermined deceleration control start threshold, a deceleration unit that decelerates the host vehicle so that the target deceleration is achieved, and a preceding vehicle A preceding vehicle detection means for detecting; a deceleration control start threshold setting means for setting the deceleration control start threshold value large when a preceding vehicle that is running and has not started deceleration is detected by the preceding vehicle detection means; A vehicle travel control device comprising: When a preceding vehicle is detected by the preceding vehicle detecting means, the vehicle is provided with an approach tendency detecting means for detecting the magnitude of an approach tendency with the preceding vehicle,
The vehicle deceleration control threshold according to claim 3, wherein the deceleration control start threshold value setting means sets the deceleration control start threshold value large only when the magnitude of the approach tendency detected by the approach tendency detection means is large. Travel control device. Based on the steering angle detection means for detecting the steering angle, the imaging means for imaging the road situation ahead of the host vehicle, the steering angle detected by the steering angle detection means and the image captured by the imaging means, A preceding vehicle position detecting means for detecting that the preceding vehicle detected by the preceding vehicle detecting means is in the own lane;
The deceleration control start threshold setting means increases the deceleration control start threshold only when it is detected by the preceding vehicle position determination means that a preceding vehicle that is running and has not started deceleration is in the own lane. The vehicle travel control device according to claim 3, wherein the vehicle travel control device is set. Curve information detecting means for detecting curve information of a road ahead of the own vehicle, vehicle speed detecting means for detecting the own vehicle speed, and target vehicle speed setting means for setting a target vehicle speed based on the curve information detected by the curve information detecting means And target deceleration setting means for setting a target deceleration based on the target vehicle speed set by the target vehicle speed setting means and the own vehicle speed detected by the vehicle speed detection means, and set by the target deceleration setting means. A deceleration means for decelerating the host vehicle so that the target deceleration is achieved, and a preceding vehicle detection means for detecting the preceding vehicle,
The target vehicle speed setting means sets the target vehicle speed to a large value when a preceding vehicle that is traveling and has not started decelerating is detected by the preceding vehicle detecting means . . An approach tendency detecting means for detecting the magnitude of the approach tendency with the preceding vehicle detected by the preceding vehicle detecting means;
7. The vehicle travel control apparatus according to claim 6, wherein the target vehicle speed setting means sets the target vehicle speed large only when the magnitude of the approach tendency detected by the approach tendency detection means is large. Based on the steering angle detection means for detecting the steering angle, the imaging means for imaging the road situation ahead of the host vehicle, the steering angle detected by the steering angle detection means and the image captured by the imaging means, A preceding vehicle position detecting means for detecting that the preceding vehicle detected by the preceding vehicle detecting means is in the own lane;
The target vehicle speed setting means sets the target vehicle speed large only when it is detected by the preceding vehicle position determining means that a preceding vehicle that is traveling and has not started decelerating is within its own lane. The vehicle travel control device according to claim 6 or 7, characterized in that The target vehicle speed setting means sets the allowable lateral acceleration based on the curve information detected by the curve information detection means, sets the target vehicle speed so as not to exceed the allowable lateral acceleration,
The said target vehicle speed setting means correct | amends greatly the allowable lateral acceleration set by the said target vehicle speed setting means, and sets the said target vehicle speed large, The any one of Claim 6 to 8 characterized by the above-mentioned. Vehicle travel control device. Friction coefficient detection means for detecting the friction coefficient of the road ahead of the vehicle,
The curve information detecting means detects a radius of curvature of the road ahead of the host vehicle,
The target vehicle speed setting means sets the target vehicle speed based on the friction coefficient calculated by the friction coefficient means and the curvature radius detected by the curve information detection means. The vehicle travel control device according to claim 1. Provided with an allowable lateral acceleration setting means for allowing the driver to set an allowable lateral acceleration,
The curve information detecting means detects a radius of curvature of a road ahead of the host vehicle, and the target vehicle speed setting means is a curvature radius detected by the curve information detecting means and an allowable lateral acceleration set by the allowable lateral acceleration setting means. The vehicle travel control apparatus according to any one of claims 3 to 10, wherein the target vehicle speed is set so as not to exceed the allowable lateral acceleration.   The vehicle according to any one of claims 3 to 11, further comprising target deceleration correction means for correcting the target deceleration set by the target deceleration setting means based on a road gradient. Travel control device.   The curve information detecting means includes an own vehicle position detecting means for detecting an own vehicle position, a road information storing means for storing road information, an own vehicle position detected by the own vehicle position detecting means, and the road information storing means. The vehicle according to any one of claims 2 to 12, further comprising forward curve information detecting means for detecting curve information of a road ahead of the vehicle based on road information stored in the vehicle. Travel control device.   The preceding vehicle detection means detects a relative speed or an inter-vehicle distance with a preceding vehicle candidate ahead of the host vehicle using at least one of laser radar, millimeter wave radar, and an image processing device, and based on the detection result The vehicle travel control device according to any one of claims 2 to 13, wherein a preceding vehicle is detected.   The curve information detecting means detects a turning difficult point where the radius of curvature of the road ahead of the vehicle is the minimum or a distance to the turning difficult point to be decelerated most, and a curvature radius at the difficult turning point. The vehicle travel control device according to any one of claims 2 to 14.   3. The deceleration unit stops the deceleration control after detecting that the vehicle has passed the difficult turning point based on the curve information detected by the curve information detection unit. The vehicle travel control device according to any one of 1 to 15.   The speed reduction means decelerates the vehicle by using at least one of a decrease in output of the driving force generator, a change in gear ratio of the transmission, and an increase in output of the braking force generator. The vehicle travel control device according to any one of 1 to 16.   Notification means for notifying that deceleration control is started by the deceleration means, and notification start delay means for delaying the start timing of notification by the notification means when a preceding vehicle is detected by the preceding vehicle detection means. The vehicular travel control apparatus according to any one of claims 2 to 17, further comprising:

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