Vehicle-to-vehicle wireless communication for controlling accident avoidance procedures
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01S-013/93
G08G-001/16
B60W-030/08
B60W-030/09
G01S-005/00
G01S-017/93
B62D-015/02
출원번호
US-0173818
(2014-02-06)
등록번호
US-9697733
(2017-07-04)
발명자
/ 주소
Penilla, Angel A.
Penilla, Albert S.
출원인 / 주소
Penilla, Angel A.
인용정보
피인용 횟수 :
11인용 특허 :
170
초록▼
Methods, computer systems, and servers for processing collision avoidance feedback to vehicles using vehicle-to-vehicle wireless communication, are provided. One method includes detecting proximity separation between a first vehicle and a second vehicle (e.g., and other vehicles within the proximity
Methods, computer systems, and servers for processing collision avoidance feedback to vehicles using vehicle-to-vehicle wireless communication, are provided. One method includes detecting proximity separation between a first vehicle and a second vehicle (e.g., and other vehicles within the proximity separation). At least one of the sensors of the first vehicle or the second vehicle determine that a proximity separation is less than a threshold distance. A pairing algorithm is triggered between electronics of the first and second vehicle to enable direct communication for data exchange between the first and second vehicles. The method includes triggering a warning to one or both of the first and second vehicles if the data exchange determines that a probability exists that a heading of the first or second vehicles will result in a collision between the first and second vehicles. The method may initiate corrective action by one or both of the first or second vehicles if the data exchange between the first and second vehicles increase the probability that the heading will result in a collision between the first and second vehicles.
대표청구항▼
1. A method for providing collision avoidance feedback to vehicles, wherein electronics are incorporated in a first vehicle that receives input from at least one sensor of the first vehicle and electronics are incorporated in a second vehicle receive input from at least one sensor of the second vehi
1. A method for providing collision avoidance feedback to vehicles, wherein electronics are incorporated in a first vehicle that receives input from at least one sensor of the first vehicle and electronics are incorporated in a second vehicle receive input from at least one sensor of the second vehicle, comprising, processing position data of the first vehicle using at least the first sensor of the first vehicle, the position data used to identify vehicles in an area around the first vehicle;detecting the second vehicle, being in the area around the first vehicle and within a proximity separation of the first vehicle, the proximity separation is within a wireless communication range between the first vehicle and the second vehicle;for when the second vehicle is within the proximity separation of the first vehicle, establishing wireless communication between the first vehicle and the second vehicle, the wireless communication used to exchange data that includes position data between the first and second vehicles, the exchange of data is used to identify changes in position data of the first vehicle or the second vehicle and to track a speed of either the first or second vehicle and to track a heading of either the first or second vehicle;triggering a warning in one or both of the first and second vehicles if the exchange of data determines that a speed and a heading of the first or second vehicle will result in a collision between the first and second vehicles, the warning being one of a sound warning, an audio spoken sound, tactile feedback to a component of the vehicle, light signals within the vehicle, or a combination of two or more thereof; andinitiating corrective action by one or both of the first or second vehicles if the exchange of data between the first and second vehicles identifies a lack of change in the speed or the heading to avoid the collision, the corrective action including one of an application of brakes, application of auto-turning of a steering wheel, a switch to auto-drive mode, an acceleration, an acceleration and deceleration, or combinations of two or more thereof, and storing a history of events that led up to the triggering of the warning or events associated with the corrective action, the history being automatically communicated over the Internet to cloud processing systems for remote storage and access, the method being executed by a processor. 2. The method of claim 1, wherein the second vehicle is either moving or stationary. 3. The method of claim 1, wherein the wireless communication includes automatically pairing for communication between the first and second vehicles, the pairing being for a temporary period of time while the first vehicle is within the proximity separation of the second vehicle. 4. The method of claim 1, wherein the wireless communication includes short form communication, or peer-to-peer communication, or Wi-Fi communication, or NFC communication, or Bluetooth communication. 5. The method of claim 1, further comprising, detecting additional vehicles within the proximity separation of the first vehicle, andtracking the speed and heading of the additional vehicles relative to the first vehicle to determine if the warning or corrective action is to be executed. 6. The method of claim 5, wherein the exchange of data occurs during a period of time when the second vehicle or any one of the additional vehicles are within the proximity separation. 7. The method of claim 1, wherein detecting that the second vehicle is within the proximity separation of the first vehicle is further processed by analyzing sensor data, the sensor data obtained from the sensors of either the first and second vehicles, the sensors include global positioning sensors, or radar sensors, or optical sensors, or mechanical sensors, or networked sensors, or audio sensors, or camera sensors, or ultrasonic sensors, or infrared (IR) sensors, or combinations of two or more sensors thereof. 8. The method of claim 1, wherein the electronics of each of the first and second vehicles include a network interface to enable the wireless communication; wherein at least one of the network interfaces communicate with a process executed by respective electronics, the process is configured to manage a table that stores metrics of the first or second vehicles, the metrics include at least speed and heading of vehicles within the proximity separation, the table is configured to be updated over time based on which vehicles are within the proximity separation. 9. A method for providing collision avoidance feedback to vehicles using vehicle-to-vehicle wireless communication, comprising, detecting proximity separation between a first vehicle and a second vehicle, wherein when at least one sensor of the first vehicle or the second vehicle determine that a proximity separation is less than a threshold distance, a pairing algorithm is triggered between electronics of the first and second vehicle to enable direct communication for data exchange between the first and second vehicles;triggering a warning to one or both of the first and second vehicles if the data exchange determines that a probability exists that a heading of the first or second vehicles will result in a collision between the first and second vehicles; andinitiating corrective action by one or both of the first or second vehicles if the data exchange between the first and second vehicles increase the probability that the heading will result in a collision between the first and second vehicles,triggering recording of audio and video surrounding the first or second vehicle when it is determined that the probability exists that the heading of the first or second vehicles will result in the collision; andtransmitting the recording over the Internet to cloud processing systems for remote storage and remote access, the method is executed by a processor. 10. The method of claim 9, wherein the warning is supplied to either the first or second vehicles in an output form to alert a human occupant in the vehicles. 11. The method of claim 10, wherein the warning includes one of a sound warning, an audio spoken sound, tactile feedback to a component of the vehicle, light signals within the vehicle, or a combination of one or more thereof. 12. The method of claim 9, wherein the corrective action includes application of brakes, application of auto-turning a steering wheel, a switch to auto-drive mode, acceleration, acceleration and deceleration, or combinations of one or more thereof. 13. The method of claim 9, wherein detecting proximity separation includes detecting moving objects, the moving objects include the first and second vehicles or the vehicles and a non-vehicle physical object. 14. The method of claim 9, wherein the pairing algorithm enables the direct communication, the direct communication includes a peer-to-peer communication, a Wi-Fi communication, an NFC communication, or Bluetooth communication, or a radio communication. 15. The method of claim 9, further comprising, storing a history event log of occurrences and actions taken that led up to triggering a warning or taking corrective action, the history event log being communicated over the Internet to cloud processing systems for remote storage and remote access. 16. The method of claim 9, wherein a notification regarding the notification recording is forwarded to one or more predetermined recipients, to an account of a user, to an account of a rental car company, to an account of a service provider, wherein the notification is one of an email, a text message, a social network message, a phone call, an audio alert, an audio/visual alert;wherein the notification includes a clip of the recording or access to the recording on remote storage via access to an account user name and password. 17. The method of claim 16, wherein the notification is sent to an insurance broker if is determined that a collision actually occurred, or enables user permissions for sending to the insurance broker or third party, orwherein the notification for when a collision actually occurs includes data regarding a heading, or speed, or weather conditions, or video clips, or license plate images, or person identification data, or combinations thereof. 18. A method for providing collision avoidance feedback to vehicles, wherein electronics are incorporated in a first vehicle that receives input from at least one sensor of the first vehicle and electronics are incorporated in a second vehicle receive input from at least one sensor of the second vehicle, comprising, processing position data of the first vehicle using at least the first sensor of the first vehicle, the position data used to identify vehicles in an area around the first vehicle;detecting the second vehicle, being in the area around the first vehicle and within a proximity separation of the first vehicle;for when the second vehicle is within the proximity separation of the first vehicle, establishing wireless communication between the first vehicle and the second vehicle, the wireless communication used to exchange data that includes position data between the first and second vehicles, the exchange of data is used to identify changes in position data of the first vehicle or the second vehicle and to track a speed of either the first or second vehicle and to track a heading of either the first or second vehicle;triggering a warning in one or both of the first and second vehicles if the exchange of data determines that a speed and a heading of the first or second vehicle will result in a collision between the first and second vehicles, the warning being one of a sound warning, an audio spoken sound, tactile feedback to a component of the vehicle, light signals within the vehicle, or a combination of two or more thereof;initiating corrective action by one or both of the first or second vehicles if the exchange of data between the first and second vehicles identifies a lack of change in the speed or the heading to avoid the collision, the corrective action including one of an application of brakes, application of auto-turning of a steering wheel, a switch to auto-drive mode, an acceleration, an acceleration and deceleration, or combinations of two or more thereof; anddetecting additional vehicles within the proximity separation of the first vehicle, and for each of the additional vehicles within the proximity separation, enabling wireless communication with the additional vehicles;enabling the exchange of data with the first vehicle to enable tracking of the speed and heading of the additional vehicles relative to the first vehicle;triggering warnings to the first vehicle or the additional vehicles when the speed and heading of any of the additional vehicles and the first vehicle identify a possible collision; andremoving vehicles from communication with the first vehicle when vehicles move outside of the proximity separation,storing a history event log of occurrences and actions taken when triggering the warning or taking corrective action, the history event log being automatically communicated over the Internet to cloud processing systems for remote storage and remote access, the method being executed by a processor. 19. The method of claim 9, wherein the proximity separation is determined by a wireless communication range between the first vehicle, the second vehicle or other vehicles relative to the first vehicle, or by sensor data obtained from the sensors of either or a combination of sensors from the first vehicle, the second vehicle or other vehicles, the sensors include global positioning sensors, or radar sensors, or audio sensors, or optical sensors, or mechanical sensors, or networked sensors, or camera sensors, or ultrasonic sensors, or infrared (IR) sensors, or combinations of two or more sensors thereof, or the proximity separation is determined by a wireless communication range between the first vehicle, the second vehicle or other vehicles relative to the first vehicle and at least one of said sensors of the first vehicle, the second vehicle or other vehicles. 20. The method of claim 18, wherein the proximity separation is determined by a wireless communication range between the first vehicle, the second vehicle or other vehicles relative to the first vehicle, or by sensor data obtained from the sensors of either or a combination of sensors from the first vehicle, the second vehicle or other vehicles, the sensors include global positioning sensors, or radar sensors, or audio sensors, or optical sensors, or mechanical sensors, or networked sensors, or camera sensors, or ultrasonic sensors, or infrared (IR) sensors, or combinations of two or more sensors thereof, or the proximity separation is determined by a wireless communication range between the first vehicle, the second vehicle or other vehicles relative to the first vehicle and at least one of said sensors of the first vehicle, the second vehicle or other vehicles.
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