Method to assess risk associated with operating an autonomic vehicle control system
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B60W-030/095
G08G-001/16
출원번호
US-0400029
(2009-03-09)
등록번호
US-8244408
(2012-08-14)
발명자
/ 주소
Lee, Jin-Woo
Salinger, Jeremy A.
Chen, Xingping
출원인 / 주소
GM Global Technology Operations LLC
인용정보
피인용 횟수 :
61인용 특허 :
31
초록▼
A vehicle is configured to execute an autonomic lane change maneuver and is equipped with a spatial monitoring system. Each of a plurality of objects located proximate to the vehicle is monitored. Locations of each of the objects are predicted relative to a projected trajectory of the vehicle. A col
A vehicle is configured to execute an autonomic lane change maneuver and is equipped with a spatial monitoring system. Each of a plurality of objects located proximate to the vehicle is monitored. Locations of each of the objects are predicted relative to a projected trajectory of the vehicle. A collision risk level between the vehicle and each of the objects is assessed.
대표청구항▼
1. Method for assessing a risk of collision associated with operation of a subject vehicle including a spatial monitoring system, the subject vehicle configured to execute an autonomic lane change maneuver, comprising: monitoring a plurality of object vehicles located proximate to the subject vehicl
1. Method for assessing a risk of collision associated with operation of a subject vehicle including a spatial monitoring system, the subject vehicle configured to execute an autonomic lane change maneuver, comprising: monitoring a plurality of object vehicles located proximate to the subject vehicle;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle at future time-steps including estimating a longitudinal distance, longitudinal speed, and longitudinal acceleration of each object vehicle relative to the subject vehicle and projecting a longitudinal relative distance between the subject vehicle and each object vehicle for elapsed time periods corresponding to the future time-steps associated with the longitudinal distance, longitudinal speed, and longitudinal acceleration of the object vehicle relative to the subject vehicle;determining lateral overlaps between the subject vehicle and the object vehicles;predicting potential operating behaviors of the object vehicles;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle and associated with the potential operating behaviors at the future time-steps;assessing a collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and comparisons between the longitudinal relative distances and an allowable margin associated with the predicted locations of the object vehicles, the allowable margin comprising a heading margin and a rear margin determined relative to a longitudinal axis parallel to the trajectory of the subject vehicle;initiating an autonomic lane change maneuver in response to a lane change maneuver request and setting a risk tolerance associated therewith; andgranting permission to execute and complete the autonomic lane change maneuver in response to the risk tolerance and the collision risk level;wherein assessing the collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and the comparisons between the longitudinal relative distances and said allowable margin associated with the predicted locations of the object vehicles comprises assessing there to be no collision risk level when there is no combination of longitudinal overlap between the longitudinal relative distances and the allowable margin and no lateral overlap at the future time-steps for the potential operating behaviors, the potential operating behaviors comprising acceleration conditions comprising fixed acceleration, mild braking and hard braking of the object vehicles. 2. The method of claim 1, wherein the risk tolerance comprises one of a conservative risk, a moderate risk, and an aggressive risk corresponding to whether said lane change maneuver has been requested, whether said lane change maneuver has started, and whether said lane boundary has been crossed subsequent to initiating the autonomic lane change maneuver, respectively. 3. The method of claim 1, wherein predicting potential operating behaviors of the object vehicles comprises predicting operating behaviors comprising selected longitudinal acceleration rates for the selected object vehicle; and wherein assessing the collision risk level between the subject vehicle and the selected object vehicle at the future time-steps associated with the predicted locations of the selected object vehicle comprises assessing the collision risk level between the subject vehicle and the selected object vehicle at the future time-steps associated with each of the selected longitudinal acceleration rates. 4. The method of claim 1, wherein predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle at future time-steps including estimating a longitudinal distance, longitudinal speed, and longitudinal acceleration of each object vehicle relative to the subject vehicle comprises: predicting operating behaviors comprising selected longitudinal acceleration rates of each object vehicle; andprojecting a longitudinal relative distance between the subject vehicle and each object vehicle for elapsed time periods corresponding to the future time-steps associated with the longitudinal distance, longitudinal speed, and the selected longitudinal acceleration of each object vehicle relative to the subject vehicle. 5. The method of claim 4, wherein the selected longitudinal acceleration of each object vehicle includes a present acceleration rate, a mild vehicle braking rate, and a hard vehicle braking rate. 6. The method of claim 2, wherein granting permission to execute and complete the autonomic lane change maneuver in response to the risk tolerance and the assessed collision risk level between the subject vehicle and the monitored object vehicles comprises granting permission to execute and complete the autonomic lane change maneuver only when the risk tolerance comprises the conservative risk tolerance and when there has been no collision risk in the most recent 0.3 seconds. 7. The method of claim 2, wherein granting permission to execute and complete the autonomic lane change maneuver in response to the risk tolerance and the assessed collision risk level between the subject vehicle and the monitored object vehicles comprises granting permission to execute and complete the autonomic lane change maneuver only when the risk tolerance comprises the moderate risk tolerance and when the collision risk is one of a low risk and no risk. 8. The method of claim 2, wherein granting permission to execute and complete the autonomic lane change maneuver in response to the risk tolerance and the assessed collision risk level between the subject vehicle and the monitored object vehicles comprises granting permission to execute and complete the autonomic lane change maneuver only when the risk tolerance comprises the aggressive risk tolerance and when the collision risk is a medium risk or less. 9. The method of claim 2, wherein assessing the collision risk level between the subject vehicle and the object vehicles comprises assessing collision risk levels in a front host lane, a rear host lane, a front target lane, a side target lane, and a rear target lane. 10. Method for assessing a risk of collision associated with operation of a subject vehicle including a spatial monitoring system, the subject vehicle configured to execute an autonomic lane change maneuver, comprising: monitoring a plurality of object vehicles located proximate to the subject vehicle;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle at future time-steps including estimating a longitudinal distance, longitudinal speed, and longitudinal acceleration of each object vehicle relative to the subject vehicle and projecting a longitudinal relative distance between the subject vehicle and each object vehicle for elapsed time periods corresponding to the future time-steps associated with the longitudinal distance, longitudinal speed, and longitudinal acceleration of the object vehicle relative to the subject vehicle;determining lateral overlaps between the subject vehicle and the object vehicles;predicting potential operating behaviors of the object vehicles;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle and associated with the potential operating behaviors at the future time-steps;assessing a collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and comparisons between the longitudinal relative distances and an allowable margin associated with the predicted locations of the object vehicles, the allowable margin comprising a heading margin and a rear margin determined relative to a longitudinal axis parallel to the trajectory of the subject vehicle;initiating an autonomic lane change maneuver in response to a lane change maneuver request and setting a risk tolerance associated therewith; andgranting permission to execute and complete the autonomic lane change maneuver in response to the risk tolerance and the collision risk level;wherein assessing the collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and the comparisons between the longitudinal relative distances and said allowable margin associated with the predicted locations of the object vehicles comprises assessing there to be a low collision risk level when there is a combination of longitudinal overlap between the longitudinal relative distances and the allowable margin and a lateral overlap at the future time-steps when the potential operating behavior comprises an acceleration condition comprising hard braking of one of the object vehicles. 11. Method for assessing a risk of collision associated with operation of a subject vehicle including a spatial monitoring system, the subject vehicle configured to execute an autonomic lane change maneuver, comprising: monitoring a plurality of object vehicles located proximate to the subject vehicle;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle at future time-steps including estimating a longitudinal distance, longitudinal speed, and longitudinal acceleration of each object vehicle relative to the subject vehicle and projecting a longitudinal relative distance between the subject vehicle and each object vehicle for elapsed time periods corresponding to the future time-steps associated with the longitudinal distance, longitudinal speed, and longitudinal acceleration of the object vehicle relative to the subject vehicle;determining lateral overlaps between the subject vehicle and the object vehicles;predicting potential operating behaviors of the object vehicles;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle and associated with the potential operating behaviors at the future time-steps;assessing a collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and comparisons between the longitudinal relative distances and an allowable margin associated with the predicted locations of the object vehicles, the allowable margin comprising a heading margin and a rear margin determined relative to a longitudinal axis parallel to the trajectory of the subject vehicle;initiating an autonomic lane change maneuver in response to a lane change maneuver request and setting a risk tolerance associated therewith; andgranting permission to execute and complete the autonomic lane change maneuver in response to the risk tolerance and the collision risk level;wherein assessing the collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and the comparisons between the longitudinal relative distances and said allowable margin associated with the predicted locations of the object vehicles comprises assessing there to be a medium collision risk level when there is a combination of longitudinal overlap between the longitudinal relative distances and the allowable margin and a lateral overlap at the future time-steps when the potential operating behavior comprises an acceleration condition comprising one of mild braking and hard braking of one of the object vehicles. 12. Method for assessing a risk of collision associated with operation of a subject vehicle including a spatial monitoring system, the subject vehicle configured to execute an autonomic lane change maneuver, comprising: monitoring a plurality of object vehicles located proximate to the subject vehicle;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle at future time-steps including estimating a longitudinal distance, longitudinal speed, and longitudinal acceleration of each object vehicle relative to the subject vehicle and projecting a longitudinal relative distance between the subject vehicle and each object vehicle for elapsed time periods corresponding to the future time-steps associated with the longitudinal distance, longitudinal speed, and longitudinal acceleration of the object vehicle relative to the subject vehicle;determining lateral overlaps between the subject vehicle and the object vehicles;predicting potential operating behaviors of the object vehicles;predicting locations of the object vehicles relative to a projected trajectory of the subject vehicle and associated with the potential operating behaviors at the future time-steps;assessing a collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and comparisons between the longitudinal relative distances and an allowable margin associated with the predicted locations of the object vehicles, the allowable margin comprising a heading margin and a rear margin determined relative to a longitudinal axis parallel to the trajectory of the subject vehicle;initiating an autonomic lane change maneuver in response to a lane change maneuver request and setting a risk tolerance associated therewith; andgranting permission to execute and complete the autonomic lane change maneuver in response to the risk tolerance and the collision risk level;wherein assessing the collision risk level between the subject vehicle and the object vehicles at the future time-steps based upon the lateral overlaps and the comparisons between the longitudinal relative distances and said allowable margin associated with the predicted locations of the object vehicles comprises assessing there to be a high collision risk level when there is a combination of longitudinal overlap between the longitudinal relative distances and the allowable margin and a lateral overlap at the future time-steps when the potential operating behavior comprises an acceleration condition comprising one of fixed acceleration, mild braking and hard braking of one of the object vehicles.
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