Method and apparatus for an object detection system using two modulated light sources
원문보기
IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0080722
(2011-04-06)
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등록번호 |
US-8599363
(2013-12-03)
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발명자
/ 주소 |
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출원인 / 주소 |
- GM Global Technology Operations LLC
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인용정보 |
피인용 횟수 :
2 인용 특허 :
6 |
초록
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An object detection tracking system for a vehicle includes a first modulated light source for transmitting a first light signal with a first propagation pattern into a target region and a second modulated light source for transmitting a second light signal with a second propagation pattern into the
An object detection tracking system for a vehicle includes a first modulated light source for transmitting a first light signal with a first propagation pattern into a target region and a second modulated light source for transmitting a second light signal with a second propagation pattern into the target region. A sensor measures light reflected off objects in the target region. A controller demodulates the measured light to detect when the first or second light signals are received. The controller determines respective ranges for generating a first set of range data for the first light signal and a second set of range data for the second light signal. The controller maintains an object tracking list that includes a position of detected objects relative to the vehicle. The position of each object is determined using trilateration of the first and second sets of range data.
대표청구항
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1. An object detection tracking system for a vehicle comprising: a first modulated light source disposed on a first region of the vehicle for transmitting a first light signal with a first propagation pattern into a target region;a second modulated light source disposed on a second region of the veh
1. An object detection tracking system for a vehicle comprising: a first modulated light source disposed on a first region of the vehicle for transmitting a first light signal with a first propagation pattern into a target region;a second modulated light source disposed on a second region of the vehicle for transmitting a second light signal with a second propagation pattern into the target region;a sensor including at least one pixel disposed on the vehicle for measuring light reflected off objects in the target region; anda controller for demodulating the measured light to detect when the first or second light signals are received, the controller determining respective ranges in response to a time delay associated with the at least one pixel from a time when the first or second light signal is transmitted until the corresponding light signal is detected to generate a first set of range data for the first light signal and a second set of range data for the second light signal;wherein the controller maintains an object tracking list that includes a position of detected objects relative to the vehicle, and wherein the position of each object is determined using trilateration of the first and second sets of range data. 2. The object detection tracking system of claim 1 wherein the position of the vehicle is identified by an azimuth angle and a resulting range between the vehicle and the object, wherein the azimuth angle and the resulting range is calculated using trilateration. 3. The object detection tracking system of claim 2 wherein the controller applies a time-division multiplexing technique for processing the received light signals at different time slots. 4. The object detection tracking system of claim 2 wherein the object tracking list maintains a plurality of objects detected by the vehicle, and wherein objects are continuously tracked by their position relative to the vehicle. 5. The object detection tracking system of claim 2 wherein the azimuth angle as determined by the controller is represented by the following formula: θ=arcsinb2D1+b2D2-4D1D22+4D12D2b(b2-2D12-2D22)where θ is the azimuth angle, b is the predetermined distance between the first and second modulated light sources, D1 is the distance from the first modulated light source to the object, and D2 is the distance from second modulated light source to the object. 6. The object detection tracking system of claim 2 wherein the resulting range as determined by the controller is represented by the following formula: R=-b2+2D12+2D224(D1+D2)where R is the resulting range from the object to the sensor, b is the predetermined distance between the first and second modulated light sources, D1 is the distance from the first modulated light source to the object, and D2 is the distance from second modulated light source to the object. 7. The object detection tracking system of claim 2 wherein the sensor includes a photodetector. 8. The object detection tracking system of claim 7 wherein the photodetector comprises a single pixel. 9. The object detection tracking system of claim 7 wherein the photodetector comprises an array of pixels. 10. The object detection tracking system of claim 7 wherein the sensor includes a plurality of pixels, and wherein the controller determines the respective ranges in response to a time delay associated with each pixel from a time when the first or second light signal is transmitted until the corresponding light signal is detected to generate a first set of pixel-by-pixel range data for the first light signal and a second set of pixel-by-pixel range data for the second sight signal. 11. The object detection tracking system of claim 1 wherein the first and second modulated light sources are LED. 12. The object detection tracking system of claim 1 wherein the first and second modulated light sources are laser diode. 13. A method for tracking objects exterior of a vehicle, the method comprising the steps of: transmitting a first light signal having a first propagation pattern from a first modulated light source into a target region, the first modulated light source being disposed on a first region of the vehicle;transmitting a second light signal having a second propagation pattern from a second modulated light source into the target region, the second modulated light source being disposed on a second region of the vehicle;measuring a light reflected off an object in a target zone by a sensor, the sensor including at least one pixel,demodulating the measured light by a controller when the first or second light signals are received, wherein the controller determines respective ranges in response to a time delay associated with the at least one pixel from a time when the first or second light signal is transmitted until the corresponding light signal is detected to generate a first set of range data for the first light signal and a second set of range data for the second light signal;maintaining an object tracking list that includes a position of detected objects relative to the vehicle, and wherein the position of each object is determined using trilateration of the first and second sets of range data. 14. The method of claim 13 wherein the position of the vehicle is identified by an azimuth angle and a resulting range between the vehicle and the object, wherein the azimuth angle and the resulting range determined using trilateration. 15. The method of claim 14 wherein a time-division multiplexing technique is used to process the light signals received by the sensor at different time slots. 16. The method of claim 14 wherein the sensor includes a photodetector for receiving the reflected light signals from the first and second modulated light sources. 17. The method of claim 16 wherein a single pixel photodetector receives the reflected light signals. 18. The method of claim 16 wherein an array of pixel photodetectors receives the reflected light signals. 19. The method of claim 18 wherein a first set of pixel-by-pixel range data for the first light signal and a second set of pixel-by-pixel range data for the second sight signal is generated in response to reflected light signals being received by the array of pixels, wherein the controller determines the respective ranges in response to a time delay associated with each pixel from a time when the first or second light signal is transmitted until the corresponding light signal is detected. 20. The method of claim 14 wherein the determination of the azimuth angle is represented by the following formula: θ=arcsinb2D1+b2D2-4D1D22+4D12D2b(b2-2D12-2D22)where θ is the azimuth angle, b is the predetermined distance between the first and second modulated light sources, D1 is the distance from the first modulated light source to the object, and D2 is the distance from second modulated light source to the object. 21. The method of claim 14 wherein calculating the resulting range via a trilateration technique is represented by the following formula: R=-b2+2D12+2D224(D1+D2)where b is the predetermined distance between the first and second modulated light sources, D1 is the distance from the first modulated light source to the object, and D2 is the distance from second modulated light source to the object. 22. The method of claim 14 wherein the object is tracked in multiple tracking frames, wherein the object tracked in each frame is represented by a set of particles, and wherein each particle is represented by a respective range and respective azimuth angle, and wherein a weighting factor for the set of particles is represented by the following formula: wi=ⅇ-D1-(Ri2-Risinθib+Ri)2σ2ⅇ-D2-(Ri2+Risinθib+Ri)2σ2where b is the predetermined distance between the first and second modulated light sources, D1 is the distance from the first modulated light source to the object, and D2 is the distance from second modulated light source to the object, θi is a determined azimuth angle for a respective particle, Ri is a determined range for a respective particle, and σ is a sensor error constant. 23. The method of claim 22 wherein a weighted azimuth based on set of particles is represented by the following formula: θ=∑i=1Nwiθiwhere wi is the weighting factor of a respective particle, and θi is the azimuth angle of a respective particle. 24. The method of claim 22 wherein a weighted range based on set of particles is represented by the following formula: R=∑i=1NwiRiwi is the weighting factor of a respective particle, and Ri is the resulting range of a respective particle. 25. The method of claim 13 wherein a data association matching technique is applied for matching the first set of range data from the first modulated light source and the second set of range data from the second modulated light source to a same object, the data association matching technique comprising the steps of: determining whether the first set of range data from the first modulated light source to the object and the second set of range data from the second modulated light source to the object are within a predetermined threshold of one another; andassociating the object with the first and second sets of range data in response to the first and second sets of range data being with the predetermined threshold.
이 특허에 인용된 특허 (6)
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Buermann,Dale H.; Mandella,Michael J., Apparatus and method for optical determination of intermediate distances.
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Doemens,G체nter; Mengel,Peter, Device for monitoring spatial areas.
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Nishiuchi, Hidekazu, Distance measurement method and device and vehicle equipped with said device.
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Eubelen,Emmanuel, Distance measurement sensor.
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Beadles Robert L. (Durham NC) Greene Henry A. (Durham NC) Pekar Jaroslaw (Chapel Hill NC), Method and apparatus for measuring range by use of multiple range baselines.
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Bass Michael (Winter Springs FL) Copley Stephen M. (Palos Verdes Estates CA), Optical proximity apparatus and method using light sources being modulated at different frequencies.
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Retterath, James E., Methods and apparatus for an active pulsed 4D camera for image acquisition and analysis.
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Retterath, Jamie E.; Laumeyer, Robert A., Methods and apparatus for array based LiDAR systems with reduced interference.
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