Consideration of risks in active sensing for an autonomous vehicle
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01C-022/00
G05D-001/00
출원번호
US-0302258
(2014-06-11)
등록번호
US-9176500
(2015-11-03)
발명자
/ 주소
Teller, Eric
Lombrozo, Peter
출원인 / 주소
Google Inc.
대리인 / 주소
McDonnell Boehnen Hulbert & Berghoff LLP
인용정보
피인용 횟수 :
9인용 특허 :
1
초록▼
An autonomous vehicle configured for active sensing may also be configured to weigh expected information gains from active-sensing actions against risk costs associated with the active-sensing actions. An example method involves: (a) receiving information from one or more sensors of an autonomous ve
An autonomous vehicle configured for active sensing may also be configured to weigh expected information gains from active-sensing actions against risk costs associated with the active-sensing actions. An example method involves: (a) receiving information from one or more sensors of an autonomous vehicle, (b) determining a risk-cost framework that indicates risk costs across a range of degrees to which an active-sensing action can be performed, wherein the active-sensing action comprises an action that is performable by the autonomous vehicle to potentially improve the information upon which at least one of the control processes for the autonomous vehicle is based, (c) determining an information-improvement expectation framework across the range of degrees to which the active-sensing action can be performed, and (d) applying the risk-cost framework and the information-improvement expectation framework to determine a degree to which the active-sensing action should be performed.
대표청구항▼
1. A computer-implemented method comprising: (i) receiving, by a computing system, information from one or more sensors of an autonomous vehicle, wherein one or more control processes for the autonomous vehicle are based upon the information;(ii) determining, by the computing system, an information-
1. A computer-implemented method comprising: (i) receiving, by a computing system, information from one or more sensors of an autonomous vehicle, wherein one or more control processes for the autonomous vehicle are based upon the information;(ii) determining, by the computing system, an information-improvement expectation that corresponds to an active-sensing action, wherein the active-sensing action comprises an action that is performable by the autonomous vehicle to potentially improve the information upon which at least one of the control processes for the autonomous vehicle is based;(iii) determining, by the computing system, a risk cost that corresponds to the active-sensing action;(iv) determining, by the computing system, whether or not the risk cost is less than a threshold risk cost, wherein the threshold risk cost corresponds to the information-improvement expectation;(v) if the risk cost is less than the threshold risk cost, then initiating the active-sensing action; and(vi) if the risk cost is greater than or equal than the threshold risk cost, then: (a) making an adjustment to the active-sensing action that affects the corresponding information-improvement expectation and the determined risk cost; and(b) repeating (ii) to (iv) for the adjusted active-sensing action until either the determined risk cost is less than the threshold risk cost, or a determination is made that no further adjustments should be made to the active-sensing action. 2. The method of claim 1, wherein the one or more sensors comprise one or more of: (a) at least one camera, (b) at least one microphone, (c) a Global Positioning System (GPS), (d) at least one accelerometer, (e) at least one gyroscope, (f) at least one compass, (g) a RADAR, (h) at least one laser rangefinder, (i) LIDAR, (j) at least one steering sensor, (k) a throttle sensor, and (l) at least one brake sensor. 3. The method of claim 1, wherein the active-sensing action comprises one or more of: (a) a change in speed of the autonomous vehicle, (b) a change in position of the autonomous vehicle relative to an aspect of an environment of the autonomous vehicle, (c) a change in position of the autonomous vehicle within a lane, (d) a change in position of at least one of the sensors, (e) a change in operation of at least one of the sensors, and/or (f) a change to the processing of sensor data from at least one of the sensors, wherein the sensor data provides information upon which at least one control process is based. 4. The method of claim 1, wherein determining the information-improvement expectation that corresponds to the active-sensing action comprises: determining an information value of sensor data in a first state of the autonomous vehicle;determining an expected information value of the sensor data that is expected to be provided in a second state of the autonomous vehicle; andsubtracting the information value from the expected information value to determine an information-improvement value for the active sensing action. 5. The method of claim 1, wherein determining the information-improvement expectation that corresponds to the active-sensing action comprises: (i) determining an information-improvement value of a given improvement to the information upon which the at least one of the control process is based;(ii) determining a probability of the given improvement occurring as a result of the autonomous vehicle performing the active-sensing action; and(iii) multiplying the information value of the given improvement by the probability of the given improvement occurring to determine an expected information value for the given improvement. 6. The method of claim 1, wherein the risk cost is indicative of a risk associated with the autonomous vehicle performing the active-sensing action. 7. The method of claim 1, wherein the risk cost is indicative of a change in risk associated with the autonomous vehicle performing the active-sensing action. 8. The method of claim 1, wherein determining the risk cost that corresponds to the active-sensing action comprises determining a risk penalty for one or more bad events that could occur as a result of the active-sensing action. 9. The method of claim 1, wherein determining the risk penalty for a given bad event comprises: determining a risk magnitude for the given bad event;determining the probability of the given bad events as a result of the active-sensing action; andmultiplying the risk magnitude for the given bad event the probability of the given bad event occurring to determine the risk penalty for the given bad event. 10. The method of claim 1: wherein the active-sensing action comprises a movement of the autonomous vehicle into a different position relative to at least one other vehicle to potentially improve environmental information provided by image data from a camera; andwherein determining the information-improvement expectation comprises determining an expected improvement to a process that is based on the environmental information, wherein the expected improvement corresponds to the movement of the autonomous vehicle into the different position relative to the at least one other vehicle. 11. The method of claim 1: wherein the active-sensing action comprises an action by the autonomous vehicle to potentially improve a view of a GPS satellite; andwherein determining the information-improvement expectation that corresponds to the active-sensing action comprises determining an expected improvement to a process that is based on data from a GPS signal, wherein the expected improvement corresponds to the action by the autonomous vehicle to improve the view of the GPS satellite. 12. The method of claim 1, wherein making the adjustment to the active-sensing action comprises changing the extent of the active-sensing action. 13. The method of claim 12, wherein changing the extent of the active-sensing action comprises one or more of: (a) adjusting an amount of a change in speed of the autonomous vehicle, (b) adjusting at least one of a distance and a direction of a change in position of the autonomous vehicle relative to an aspect of an environment of the autonomous vehicle, (c) adjusting at least one of a distance and a direction of a change in position of the autonomous vehicle within a lane, (d) adjusting at least one of a distance and a direction of a change in position of at least one of the sensors, and (e) adjusting a degree of a change in operation of at least one of the sensors. 14. The method of claim 1, wherein the adjustment to the active-sensing action changes the information-improvement expectation corresponding to the active-sensing action. 15. The method of claim 14, further comprising: before repeating (ii) to (iv) for the adjusted active-sensing action, updating the threshold risk cost based on the changed information-improvement expectation. 16. An autonomous-vehicle system comprising: one or more sensor interfaces operable to receive data from one or more sensors of an autonomous vehicle; anda computer system configured to: (i) receive, via the one or more sensor interfaces, information from the one or more sensors, wherein one or more control processes for the autonomous vehicle are based upon the information;(ii) determine an information-improvement expectation that corresponds to an active-sensing action, wherein the active-sensing action comprises an action that is performable by the autonomous vehicle to potentially improve the information upon which at least one of the control processes for the autonomous vehicle is based;(iii) determine a risk cost that corresponds to the active-sensing action;(iv) determine whether or not the risk cost is less than a threshold risk cost, wherein the threshold risk cost corresponds to the information-improvement expectation;(v) if the risk cost is less than the threshold risk cost, then initiate the active-sensing action; and(vi) if the risk cost is greater than or equal than the threshold risk cost, then: (a) make an adjustment to the active-sensing action that affects the corresponding information-improvement expectation and the determined risk cost, and (b) repeat (ii) to (iv) for the adjusted active-sensing action until either the determined risk cost is less than the threshold risk cost, or a determination is made that no further adjustments should be made to the active-sensing action. 17. The autonomous-vehicle system of claim 16, wherein the adjustment to the active-sensing action comprises a change in extent of the active-sensing action. 18. The autonomous-vehicle system of claim 16, wherein the change in extent the active-sensing action comprises one or more of: (a) an adjustment to an amount of a change in speed of the autonomous vehicle, (b) an adjustment to at least one of a distance and a direction of a change in position of the autonomous vehicle relative to an aspect of an environment of the autonomous vehicle, (c) an adjustment to at least one of a distance and a direction of a change in position of the autonomous vehicle within a lane, (d) an adjustment to at least one of a distance and a direction of a change in position of at least one of the sensors, and (e) an adjustment to a degree of a change in operation of at least one of the sensors. 19. A method comprising: receiving, by a computing system, information from one or more sensors of an autonomous vehicle, wherein one or more control processes for the autonomous vehicle are based upon the information;determining, by the computing system, a risk-cost framework that indicates risk costs across a range of degrees to which an active-sensing action can be performed, wherein the active-sensing action comprises an action that is performable by the autonomous vehicle to potentially improve the information upon which at least one of the control processes for the autonomous vehicle is based;determining, by the computing system, an information-improvement expectation framework that indicates information-improvement expectations across the range of degrees to which the active-sensing action can be performed;applying, by the computing system, the risk-cost framework and the information-improvement expectation framework to determine a degree to which the active-sensing action should be performed, wherein a score of the active-sensing action of the determined degree is less than a threshold score, wherein the score is determined based on the risk cost and information-improvement expectation corresponding to the determined degree; andinitiating the active-sensing action of the determined degree. 20. The method of claim 19, wherein the determined degree maximizes the information-improvement expectation corresponding to the active-sensing action, with a constraint that the corresponding score is less than the threshold score. 21. The method of claim 19, wherein determining the information-improvement expectation framework comprises: determining information-improvement expectation data across one or more of: (a) a range of speed changes for the autonomous vehicle, (b) a range of positional changes of the autonomous vehicle relative to an aspect of an environment of the autonomous vehicle, (c) a range of positional changes of the autonomous vehicle within a lane, (d) a range of positional changes of at least one of the sensors, and (e) a range of operational adjustments to at least one of the sensors. 22. An autonomous-vehicle system comprising: one or more sensor interfaces operable to receive data from one or more sensors of an autonomous vehicle; anda computer system configured to: receive information from one or more sensors of an autonomous vehicle, wherein one or more control processes for the autonomous vehicle are based upon the information;determine a risk-cost framework that indicates risk costs across a range of degrees to which an active-sensing action can be performed, wherein the active-sensing action comprises an action that is performable by the autonomous vehicle to potentially improve the information upon which at least one of the control processes for the autonomous vehicle is based;determine an information-improvement expectation framework that indicates information-improvement expectations across the range of degrees to which the active-sensing action can be performed;apply the risk-cost framework and the information-improvement expectation framework to determine a degree to which the active-sensing action should be performed, wherein a score of the active-sensing action of the determined degree a score that is greater than a threshold score, wherein the score is determined based on the risk cost and information-improvement expectation corresponding to the determined degree; andinitiate the active-sensing action of the determined degree. 23. The autonomous-vehicle system of claim 22, wherein the determined degree maximizes the information-improvement expectation corresponding to the active-sensing action, with a constraint that the corresponding score is less than the threshold score. 24. The autonomous-vehicle system of claim 22, wherein the risk-cost framework comprises risk-cost data across one or more of: (a) a range of speed changes for the autonomous vehicle, (b) a range of positional changes of the autonomous vehicle relative to an aspect of an environment of the autonomous vehicle, (c) a range of positional changes of the autonomous vehicle within a lane, (d) a range of positional changes of at least one of the sensors, and (e) a range of operational adjustments to at least one of the sensors. 25. The autonomous-vehicle system of claim 22, wherein the information-improvement expectation framework comprises information-improvement expectation data across one or more of: (a) a range of speed changes for the autonomous vehicle, (b) a range of positional changes of the autonomous vehicle relative to an aspect of an environment of the autonomous vehicle, (c) a range of positional changes of the autonomous vehicle within a lane, (d) a range of positional changes of at least one of the sensors, and (e) a range of operational adjustments to at least one of the sensors.
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이 특허에 인용된 특허 (1)
Young, Shih-Yih; Jerome, Kristen M., Motion planner for unmanned ground vehicles traversing at high speeds in partially known environments.
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