Video enhanced stability control in road vehicles
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-017/10
B60T-008/24
G05B-019/10
G05B-019/04
출원번호
US-0119537
(2005-04-29)
우선권정보
GB-0225192.4(2002-10-30)
발명자
/ 주소
Courtenay,William John Andres
Tucker,Mark Richard
출원인 / 주소
TRW Limited
대리인 / 주소
MacMillan, Sobanski &
인용정보
피인용 횟수 :
9인용 특허 :
18
초록▼
A stability control system for road vehicles comprising a limit handling assistance controller which uses video lane detection measurements in conjunction with vehicle dynamics information, including inertial brakes and steering measurements to control vehicle EPS and VSC systems to assist the drive
A stability control system for road vehicles comprising a limit handling assistance controller which uses video lane detection measurements in conjunction with vehicle dynamics information, including inertial brakes and steering measurements to control vehicle EPS and VSC systems to assist the driver stabilize the vehicle and correct for any lane offset prior to and/or during of understeer, oversteer, split-μ and heavy breaking conditions, and lane changes.
대표청구항▼
What is claimed is: 1. A stability control system for road vehicles comprising: a video image processing system; and a limit handling assistance controller connected to said video image processing system and which uses video lane detection measurements in conjunction with vehicle dynamics informati
What is claimed is: 1. A stability control system for road vehicles comprising: a video image processing system; and a limit handling assistance controller connected to said video image processing system and which uses video lane detection measurements in conjunction with vehicle dynamics information, including inertial brakes and steering measurements, to control vehicle Electronic Power Steering (EPS) and Vehicle Stability Control (VSC) systems to assist the driver to stabilise the vehicle and correct for any lane offset both prior to and during at least one of the conditions of understeer, oversteer, split-μ and heavy breaking conditions, and lane changes, said limit handling assistance controller including: a scenario control which receives vehicle measurements and Human Machine Interface (HMI) inputs and estimates therefrom the dynamic state of the vehicle, such as understeer/oversteer/heavy braking, and the intentions of the driver, such as lane change, whereby to provide a series of scenario flags for use in informing the controller of what vehicle control action is available; a position and yaw rate control which receives vehicle measurement data and lane detection data and calculates one of a yaw rate required to return the vehicle to the centre of its lane and a yaw rate required for lane transition if a lane change flag is detected; and a steering and braking control which receives said calculated yaw rate and the vehicle measurement data and is operative to calculate steering and braking demands for transfer to the vehicle EPS and VSC systems. 2. A stability control system as claimed in claim 1, further including an application control device coupled to a mode control and acting as a mode switch for connecting the steering and braking demands produced by the steering and braking control to the vehicle EPS and VSC systems when said mode control indicates that the system is active. 3. A stability control system for road vehicles comprising: a video image processing system; a limit handling assistance controller connected to said video image processing system and which uses video lane detection measurements in conjunction with vehicle dynamics information, including inertial brakes and steering measurements, to control vehicle Electronic Power Steering (EPS) and Vehicle Stability Control (VSC) systems to assist the driver to stabilise the vehicle and correct for any lane offset both prior to and during at least one of the conditions of understeer, oversteer, split-μ and heavy breaking conditions, and lane changes, said limit handling assistance controller including: a scenario control which receives vehicle measurements and Human Machine Interface (HMI) inputs and estimates therefrom the dynamic state of the vehicle, such as understeer/oversteer/heavy braking, and the intentions of the driver, such as lane change, whereby to provide a series of scenario flags for use in informing the controller of what vehicle control action is available; a position and yaw rate control which receives vehicle measurement data and line detection data and calculates one of a yaw rate required to return the vehicle to the centre of its lane and a yaw rate required for lane transition if a lane change flag is detected; and a steering and braking control which receives said calculated yaw rate and the vehicle measurement data and is operative to calculate steering and braking demands for transfer to the vehicle EPS and VSC systems, said steering and braking control including: a steering and braking yaw demand allocator, a steering demand control, and a braking demand control, with said steering and braking yaw demand allocator proportioning said calculated yaw rate demanded by said position and yaw rate control to said steering demand control and said braking demand control according to said scenario flags, said steering demand control being operative to generate a steering demand and said braking demand control being operative to generate a braking demand; and an application control device coupled to a mode control and acting as a mode switch for connecting the steering and braking demands produced by said steering demand control and said braking demand control to the vehicles EPS and VSC systems when said mode control indicates that the system is active. 4. A stability control system as claimed in claim 3, wherein in said steering demand control, said steering yaw rate demand is compared to feedback measurements of steering wheel angle and rotational rate to provide an assist steering column torque demand for transmission to the vehicle EPS system. 5. A stability control system as claimed in claim 4, wherein in said braking demand control, said braking yaw rate demand is compared to feedback estimates of brake pressures whereby to provide brake pressure demands for transmission to the vehicle VSC system. 6. A stability control system as claimed in claim 5 in which, in a split-μ stop, the driver is assisted to balance the yaw moment due to the asymmetric longitudinal braking force by demanding a torque to the steering system to assist the driver in achieving the required counter moment. 7. A stability control system as claimed in claim 6, wherein the system includes a video lane detection sensor and further wherein an additional torque to assist the driver correct for lane offsets detected by said video lane detection sensor is used to augment the first mentioned torque. 8. A stability control system as claimed in claim 5, in which in the case of an understeering vehicle condition detected by the vehicle VSC, an appropriate wheel is arranged to be braked to achieve a desired yaw rate in accordance with a driver's command expressed via the steering wheel, whereby to decelerate the vehicle to reduce the understeer. 9. A stability control system as claimed in claim 8, in which once the understeer has been reduced sufficiently for the front tyres to be no longer saturated, a torque is arranged to be demanded of the steering to assist the driver to correct for any lane offsets detected by a video lane detection sensor providing said video lane detection measurements. 10. A stability control system as claimed in claim 5, in which, for the purposes of preventative understeer or oversteer, the video lane detection measurements are used to obtain look-ahead information of a bend, the controller being arranged to demand brake intervention to decelerate the vehicle to an appropriate speed so that the bend can be safely negotiated without one of understeer and oversteer being provided. 11. A stability control system as claimed in claim 5 in which, in the case of an oversteering vehicle condition detected by the vehicle VSC, a torque is arranged to be applied to the steering to assist the driver in stabilising the vehicle following which, if the oversteer progresses to a threshold, the VSC is arranged to brake an appropriate wheel to stabilise the vehicle and achieve a desired yaw rate in accordance with a driver's command via the steering wheel. 12. A stability control system as claimed in claim 11, in which, during and subsequent to the oversteer correction phases of the oversteer control, an additional overlay torque is arranged to be demanded of the steering to assist the driver correct for lane offsets detected by a video lane detection sensor providing said video lane detection measurements. 13. A stability control system as claimed in claim 5 in which during heavy braking while running in a lane, a torque is demanded of the steering system using vehicle inertial, steering and video lane detection measurements to assist the driver to stabilise the vehicle and keep the vehicle in that lane when undergoing said braking. 14. A stability control system as claimed in claim 5, wherein the system includes a video lane detection sensor and further wherein when a lane change selected by the driver is detected by said video lane detection sensor in association with steering and vehicle inertial sensors, a torque is arranged to be demanded of the steering system to assist the driver in making the lane change. 15. A stability control system for road vehicles having an Active Torque Overlay (ATO) system and comprising a limit handling assistance controller which uses video lane detection measurements in conjunction with vehicle dynamics information, including inertial brakes and steering measurements to control the ATO system to assist the driver in stabilizing the vehicle and correcting for any lane offset prior to and during at least one of the conditions of understeer, oversteer, split-μ and heavy braking conditions, and lane changes.
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이 특허에 인용된 특허 (18)
Le Gusquet Frederic,FRX ; Tissedre Marc,FRX ; Saglio Christophe,FRX ; Salanson Philippe,FRX, Control device for making safe a fast vehicle, in particular guided by an operator on board the vehicle or otherwise.
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Murgue Jean P. (Sevres FRX) Pressiat Robert (Ville D\Avray FRX) Robin Lon (Massy FRX), Method and device for assisting height holding in air navigation.
Eckert, Alfred; Marczinski, Lutz; Schramm, Peter; Hagleitner, Walter, Method and device for monitoring or for influencing the movement of a vehicle on a path.
Jokic, Mile; Kostadina, Robert D.; Kuemmel, Martin; Schneider, Markus E.; Schumacher, Christian H. P.; Skellenger, William, Vehicle control of a locked drive system.
Kagawa Kazunori,JPX ; Goto Takeshi,JPX ; Satoh Kunihito,JPX, Vehicle steering control apparatus for assisting a steering effort to move a vehicle along a line desired by a driver.
Faeuster, Daniel; Stumpf, Erik Jürgen; Benak, Attila; Brown, Andrew; Codonesu, Sergio; Hesseler, Karl-Peter; Bremkens, Jan, Method and system for responding to a lane deviation event of a vehicle.
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