Vehicle diagnostics based on information communicated between vehicles
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04N-007/18
G05D-001/00
G01S-007/00
G01S-017/02
G05D-001/02
H04N-005/247
H04N-013/00
H04N-013/02
출원번호
US-0122355
(2008-05-16)
등록번호
US-8947531
(2015-02-03)
발명자
/ 주소
Fischer, Jacob
Frampton, Dale
Schmiedel, Gary
Yakes, Christopher K.
Broggi, Alberto
출원인 / 주소
Oshkosh Corporation
대리인 / 주소
Foley & Lardner LLP
인용정보
피인용 횟수 :
25인용 특허 :
279
초록▼
A system and method for controlling a convoy of vehicles. The convoy of vehicles including a leader vehicle in communication with a plurality of autonomous follower vehicles. The leader vehicle is configured to receive a first autonomous follower vehicle data and compare the first autonomous followe
A system and method for controlling a convoy of vehicles. The convoy of vehicles including a leader vehicle in communication with a plurality of autonomous follower vehicles. The leader vehicle is configured to receive a first autonomous follower vehicle data and compare the first autonomous follower vehicle data to at least one of a leader vehicle data, a second autonomous follower vehicle data and/or a threshold value. The first autonomous follower vehicle data, the leader vehicle data, the second autonomous follower vehicle data and the threshold value relate to a vehicle performance characteristic.
대표청구항▼
1. A convoy of vehicles comprising: a leader vehicle in communication with a plurality of autonomous follower vehicles, the leader vehicle configured to receive a first autonomous follower vehicle data from a first autonomous follower vehicle, the leader vehicle configured to compare the first auton
1. A convoy of vehicles comprising: a leader vehicle in communication with a plurality of autonomous follower vehicles, the leader vehicle configured to receive a first autonomous follower vehicle data from a first autonomous follower vehicle, the leader vehicle configured to compare the first autonomous follower vehicle data to at least one of a leader vehicle data, a second autonomous follower vehicle data from a second autonomous follower vehicle, and a threshold value;wherein the first autonomous follower vehicle data, the leader vehicle data, the second autonomous follower vehicle data and the threshold value relate to a vehicle performance characteristic,wherein the leader vehicle is configured to transmit a first command to the first autonomous follower vehicle, wherein the first autonomous follower vehicle is configured to transmit a second command to the second autonomous follower vehicle, and wherein the first autonomous follower vehicle is configured to transmit the first autonomous follower vehicle data to the leader vehicle, andwherein the first autonomous follower vehicle and the second autonomous follower vehicle are configured to receive the first command from the leader vehicle and the second command from the first autonomous follower vehicle, respectively, compare the first command and the second command, respectively, to a predetermined tolerance range, follow the first command and the second command, respectively, if the first command and the second command, respectively, are within the predetermined tolerance range, and disregard the first command and the second command, respectively, if the first command and the second command, respectively, are not within the predetermined tolerance range, the predetermined tolerance range including at least one of a cargo load capacity, a speed, a turning radius, a number of revolutions per minute, a temperature maximum value, and a temperature minimum value. 2. The convoy of vehicles in claim 1, wherein at least one of the first autonomous follower vehicle data, the leader vehicle data and the second autonomous follower vehicle data is generated by an on-board diagnostics system. 3. The convoy of vehicles in claim 1, wherein a discrepancy report is generated based on a detected disparity between a comparison of the first autonomous follower vehicle data to at least one of the leader vehicle data, the second autonomous follower vehicle data and the threshold value. 4. The convoy of vehicles in claim 3, wherein a maintenance schedule is generated based on the discrepancy report. 5. The convoy of vehicles of claim 1, wherein the first autonomous follower vehicle is adjacent to the leader vehicle and the second autonomous follower vehicle is adjacent to the first autonomous follower vehicle, but not adjacent to the leader vehicle. 6. The convoy vehicles of claim 1, wherein the first autonomous follower vehicle is within a first transmission range of the leader vehicle and the second autonomous follower vehicle is within a second transmission range of the second autonomous follower vehicle, but outside of the first transmission range of the leader vehicle. 7. A convoy of vehicles comprising: a leader vehicle in communication with a plurality of autonomous follower vehicles, the leader vehicle configured to receive autonomous follower vehicle data, the leader vehicle configured to transmit at least one command signal to the plurality of autonomous follower vehicles;wherein the plurality of autonomous follower vehicles are configured to compare a command value associated with the command signal to a predetermined tolerance range, and wherein the plurality of autonomous follower vehicles are configured to implement the at least one command signal when the command value is within the predetermined tolerance range and not implement the at least one command signal when the command value is not within the predetermined tolerance range,wherein the leader vehicle is movable at least one of physically by moving the leader vehicle to another location and electronically by switching a leader vehicle command function from the leader vehicle to at least one of the plurality of autonomous follower vehicles, andwherein the leader vehicle comprises an override mode configured to force the plurality of autonomous follower vehicles to implement the command signal regardless of whether the command value is within the predetermined tolerance range. 8. The convoy of vehicles in claim 7, wherein an off-course follower vehicle receives a course data to rejoin the convoy. 9. The convoy of vehicles in claim 7, wherein the leader vehicle and the plurality of autonomous follower vehicles obtain data related to at least one of a terrain, an obstacle, an enemy installation and enemy personnel. 10. The convoy of vehicles in claim 9, wherein the obtained data is utilized to generate a first representative image of an area surrounding the convoy. 11. The convoy of vehicles in claim 10, wherein the leader vehicle is configured to receive a second representative image of the area surrounding the convoy from a terrain database. 12. The convoy of vehicles in claim 11, wherein the leader vehicle further comprises a control center configured to display a composite image of the first representative image of the area surrounding the convoy and the second representative image of the area surrounding the convoy. 13. The convoy of vehicles in claim 12, wherein the control center includes a screen configured to facilitate selecting a subset of the convoy in the composite image and changing the location of the subset of the convoy in the composite image; and wherein the leader vehicle is configured to transmit a command signal to maneuver the subset of the convoy to correspond to a change in location of the subset of the convoy in the composite image. 14. The convoy of vehicles of claim 7, wherein the predetermined tolerance range is a mission specific tolerance range received by the plurality of autonomous follower vehicles prior to starting a current mission. 15. The convoy of vehicles of claim 7, wherein the predetermined tolerance range is a tolerance range programmed into the plurality of autonomous follower vehicles during a manufacturing process of the plurality of autonomous follower vehicles. 16. The convoy of vehicles of claim 7, wherein the plurality of autonomous follower vehicles are configured to determine, based on the comparison of the command value to the predetermined tolerance range, that at least one of the plurality of autonomous follower vehicles may be damaged if the command signal is implemented by the at least one autonomous follower vehicle, and wherein the at least one autonomous follower vehicle is configured to not implement the command signal based on the determination that doing so may cause the at least one autonomous follower vehicle to be damaged.
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