An adaptive anti-collision method for vehicles has steps of creating multiple driving patterns with each driving pattern corresponding to a vehicle speed, a safe distance and a braking distance parameter, such as longer safe distance configured for faster vehicle speed, and higher vehicle speed or s
An adaptive anti-collision method for vehicles has steps of creating multiple driving patterns with each driving pattern corresponding to a vehicle speed, a safe distance and a braking distance parameter, such as longer safe distance configured for faster vehicle speed, and higher vehicle speed or shorter safe distance for different road condition, acquiring dynamic information, such as vehicle speed or acceleration, of the vehicle using sensors on the vehicle, combining the dynamic information and drivers' driving behavior to determine a driving pattern through a statistical analysis and a neural network, adjusting control parameters of the vehicle according to the driving pattern for an electronic control unit of the vehicle to issue an alert or activate a braking action according to the driving pattern. Accordingly, the anti-collision method can be adapted to different vehicle speed, road condition and drivers' driving habits for adjusting the safe distance and the braking system.
대표청구항▼
1. An adaptive anti-collision method for vehicles, wherein each vehicle having multiple sensors and a control unit, the sensors acquire a vehicle speed and a measured distance between the vehicle and an obstacle in the front, the control unit is electrically connected to an electronic control unit (
1. An adaptive anti-collision method for vehicles, wherein each vehicle having multiple sensors and a control unit, the sensors acquire a vehicle speed and a measured distance between the vehicle and an obstacle in the front, the control unit is electrically connected to an electronic control unit (ECU) of the vehicle and the sensors, and the adaptive anti-collision method is performed by the control unit and comprises steps of: creating multiple driving patterns and indices or alert levels corresponding to the driving patterns, wherein each driving pattern has a vehicle speed, a safe distance and a reference braking distance related parameter, and the driving pattern at the vehicle speed corresponds to a comparison relationship between the measured distance and the safe distance and one of four safe levels;analyzing the vehicle speed and the measured distance acquired by the sensors to determine one of the driving patterns, wherein actual driving conditions of the vehicle are statistically analyzed to acquire a driving state of a driver of the vehicle and classify into a corresponding driving pattern associated with the driver so as to generate one of the indices or the alert levels corresponding to the driving pattern and vary control parameters of the vehicle according to the classified driving patterns, wherein the index generated according to the driving patterns is calculated by Index=((a1×A+a2×B+a3×C+a4×D)a1+a2+a3+a4)(A+B+C+D)where a1, a2, a3 and a4 are weight factors, and A, B, C, D are frequencies of the driving patterns of the driver corresponding to the four safe levels; andproviding driver assistance and control, wherein if the driver has not responded to the alert, the control unit instructs the ECU to issue the alert according to a corresponding control parameter and to provide a braking assistance or brake the vehicle. 2. The method as claimed in claim 1, wherein the driving pattern of the driver is analyzed with a neural network. 3. The method as claimed in claim 2, wherein the neural network is calculated by a self-organizing map (SOM) algorithm, and the SOM algorithm includes steps of: inputting an initial weighting matrix (IW);introducing an input training vector;calculating a distance and a winning node, wherein the winning node has the shortest distance between an output unit (j) and the input training vector;calculating a weighting value correction matrix (ΔW↓j), wherein the weighting value correction matrix is a difference between a weighting matrix at next time and a weighting matrix at present; andupdating the IW;whereina radius of a neighboring center (q) is expressed by: Rn+1=λ×Rn whereR is a radius of a neighboring center (q); andλ is a radius adjustment factor;a neighboring distance is expressed by: disjq=∥rj−rq∥=√{square root over ((xj−xq)2+(yj−yq)2)}{square root over ((xj−xq)2+(yj−yq)2)}wheredisjq is a distance between the output unit (j) and the neighboring center (q);rj is a topology position (xj, yj) of the output unit (j); andrq is the topology position (xq, yq) of the neighboring center (q);a neighboring function is expressed by: Kjq=ⅇ-(disjqR)2whereKjq is a weighting relationship of the output unit (j) and the neighboring center (q); andR is the radius of the neighboring center (q);a weighting value correction matrix is expressed by: ΔWj=η×└X−Wj┘×Kjq whereηis a learning rate;X is an input vector;Kjq is a neighboring function;Wj is a weighting matrix of the output unit (j); andΔWj is the weighting value correction matrix, Wj (next time)=ΔWj+Wj (present). 4. The method as claimed in claim 3, wherein the driving pattern is classified into two types respectively corresponding to a safe level and a slightly dangerous level, the safe level is classified when the measured distance is greater than the safe distance, and the slightly dangerous level is classified when the measured distance is less than the safe distance. 5. The method as claimed in claim 4, wherein the driving pattern is further classified into two additional types respectively corresponding to a very safe level and a very dangerous level, the very safe level is classified when the measured distance is greater than double of the safe distance, the very dangerous level is classified when the measured distance is less than two thirds of the safe distance, and the slightly dangerous level is classified when the measured distance is within two thirds of the safe distance and the safe distance. 6. The method as claimed in claim 1, wherein after the measured distance and the vehicle speed detected by the sensors are analyzed to classify into a driving pattern, the measured distance between the obstacle and the vehicle is further updated, and if the measured distance is less than the index of the driving pattern of the driver, an alert is issued to warn the driver. 7. The method as claimed in claim 6, wherein after the alert is issued to warn the driver, if the measured distance is still less than the index and the driver has not responded to avoid the obstacle, the control unit automatically activates a braking system of the vehicle to stop the vehicle. 8. The method as claimed in claim 1, wherein the driving pattern is classified into two types respectively corresponding to a safe level and a slightly dangerous level, the safe level is classified when the measured distance is greater than the safe distance, and the slightly dangerous level is classified when the measured distance is less than the safe distance. 9. The method as claimed in claim 8, wherein the driving pattern is further classified into two additional types respectively corresponding to a very safe level and a very dangerous level, the very safe level is classified when the measured distance is greater than double of the safe distance, the very dangerous level is classified when the measured distance is less than two thirds of the safe distance, and the slightly dangerous level is classified when the measured distance is within two thirds of the safe distance and the safe distance.
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이 특허에 인용된 특허 (7)
Huang, Jihua; Lin, William C.; Chin, Yuen-Kwok, Adaptive vehicle control system with driving style recognition based on headway distance.
Ansaldi Ermanno (Turin ITX) Re Fiorentin Stefano (Grugliasco ITX) Saroldi Andrea (Turin ITX), Method and means for avoiding collision between a motor vehicle and obstacles.
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