Embodiments describe new mechanisms for signalized intersection control. Embodiments expand inputs beyond traditional traffic control methods to include awareness of agency policies for signalized control, industry standardized calculations for traffic control parameters, geometric awareness of the
Embodiments describe new mechanisms for signalized intersection control. Embodiments expand inputs beyond traditional traffic control methods to include awareness of agency policies for signalized control, industry standardized calculations for traffic control parameters, geometric awareness of the roadway and/or intersection, and/or input of vehicle trajectory data relative to this intersection geometry. In certain embodiments, these new inputs facilitate a real-time, future-state trajectory modeling of the phase timing and sequencing options for signalized intersection control. Phase selection and timing can be improved or otherwise optimized based upon modeling the signal's future state impact on arriving vehicle trajectories. This improvement or optimization can be performed to reduce or minimize the cost basis of a user definable objective function.
대표청구항▼
1. A self-configuring traffic signal controller method, the method comprising: under control of a traffic controller comprising electronic hardware, receiving sensor data from a trajectory sensor at an intersection, the trajectory sensor optionally including a radar or video camera;generating trajec
1. A self-configuring traffic signal controller method, the method comprising: under control of a traffic controller comprising electronic hardware, receiving sensor data from a trajectory sensor at an intersection, the trajectory sensor optionally including a radar or video camera;generating trajectory data from the sensor data based on intersection geometric data about the intersection stored in data storage, the trajectory data representing trajectories of a plurality of vehicles at the intersection, said generating comprising updating at least part of the trajectory data corresponding with some of the vehicles with position and speed data from Basic Safety Messages wirelessly received directly from connected vehicles, said updating comprising replacing a first part of the trajectory data corresponding to a first one of the vehicles, generated from the sensor data, with second trajectory data derived from one or more of the Basic Safety Messages wirelessly received directly from a first one of the connected vehicles;automatically adjusting a signal timing configuration of the traffic controller multiple times per day by analyzing the trajectory data according to an objective function specified by user-defined policies, wherein the user-defined policies comprise the following: delay of the vehicles, number of stopped ones of the vehicles, a safety factor, and intersection capacity; andoutputting control signals to traffic signal lights according to the adjusted signal timing configuration to cause the traffic signal lights to selectively turn on and off the traffic signals according to the adjusted signal timing configuration. 2. The method of claim 1, wherein the sensor data is specified according to a coordinate reference frame related to the geometric intersection data. 3. The method of claim 1, wherein generating the trajectory data comprises using vehicle speeds in the sensor data to predict future vehicle positions with respect to the intersection. 4. The method of claim 1, wherein automatically adjusting the signal timing configuration of the traffic controller comprises adjusting one or more of green time, yellow time, and red time according to predicted future vehicle trajectory. 5. The method of claim 1, wherein the user-defined policies emphasize some policies over other policies in the objective function. 6. The method of claim 1, further comprising providing at least some of the trajectory data to a second traffic controller at another intersection to enable the second traffic controller to use at least some of the trajectory data to adjust signal timing at the second traffic controller. 7. The method of claim 1, wherein the objective function is user-definable. 8. The method of claim 1, wherein said automatically adjusting the signal timing configuration comprises selecting a traffic phase from a plurality of possible traffic phases and selecting a phase termination time from a plurality of possible phase termination times. 9. A self-configuring traffic signal controller apparatus, the apparatus comprising: a traffic controller comprising electronic hardware that: receives sensor data from a trajectory sensor at an intersection, the trajectory sensor optionally including a radar or video camera;generates trajectory data from the sensor data based on intersection geometric data about the intersection stored in data storage, the trajectory data comprising data about vehicles speeds of a plurality of vehicles at the intersection, said generating comprising updating at least part of the trajectory data corresponding with some of the vehicles with one or both of position and speed data from Basic Safety Messages received wirelessly from connected vehicles, said updating comprising replacing a first part of the trajectory data corresponding to a first one of the vehicles, generated from the sensor data, with second trajectory data derived from one or more of the Basic Safety Messages wirelessly received directly from a first one of the connected vehicles;automatically adjusts a signal timing configuration of the traffic controller multiple times per day by analyzing the trajectory data according to user-defined policies, wherein the user-defined policies comprise two or more of the following: delay of the vehicles, number of stopped ones of the vehicles, a safety factor, and intersection capacity; andoutputs control signals to traffic signal lights according to the adjusted signal timing configuration to cause the traffic signal lights to selectively turn on and off the traffic signals according to the adjusted signal timing configuration. 10. The apparatus of claim 9, wherein the sensor data is specified according to a coordinate reference frame related to the geometric intersection data. 11. The apparatus of claim 9, wherein the traffic controller generates the trajectory data by at least using vehicle speeds in the sensor data to predict future vehicle positions with respect to the intersection. 12. The apparatus of claim 9, wherein the traffic controller generates the trajectory data by at least using vehicle speeds in the sensor data to predict future vehicle speeds with respect to the intersection. 13. The apparatus of claim 9, wherein the traffic controller automatically adjusts the signal timing configuration of the traffic controller by at least adjusting one or more of green time, yellow time, and red time according to predicted future vehicle trajectory. 14. The apparatus of claim 9, wherein the user-defined policies weight some policies over other policies. 15. The apparatus of claim 9, wherein the traffic controller also provides at least some of the trajectory data to a second traffic controller at another intersection to enable the second traffic controller to use at least some of the trajectory data to adjust signal timing of at the second traffic controller. 16. The apparatus of claim 9, wherein the traffic controller comprises a co-processor or separate circuit board that overrides a traffic controller. 17. The apparatus of claim 9, wherein the traffic controller automatically reconfigures the signal timing configuration by selecting a traffic phase from a plurality of possible traffic phases and selecting a phase termination time from a plurality of possible phase termination times. 18. The apparatus of claim 9, wherein the traffic controller generates the trajectory data multiple times within a single traffic signal cycle until a calculated time to remain in a current phase has been reached. 19. The apparatus of claim 18, wherein the calculated time is based on an average time difference between initial vehicle trajectory detection, obtained from the trajectory data, and a time at which the vehicles are detected from the plurality of inputs as entering a dilemma zone. 20. The apparatus of claim 19, wherein the traffic controller automatically reconfigures the signal timing configuration in response to reaching the calculated time. 21. The method of claim 1, further comprising computing the safety factor based on future state trajectory modeling to predict which of the vehicles will have a safety conflict with one or more of: another vehicle, a pedestrian, or states of the traffic signal. 22. The method of claim 1, further comprising determining the intersection capacity based on one or more of the following factors: a capacity of a movement, saturation flow rate, green time for the movement, startup lost time for the movement, and cycle length. 23. The apparatus of claim 9, wherein the electronic hardware is further configured to compute the safety factor based on future state trajectory modeling to predict which of the vehicles will have a safety conflict with one or more of: another vehicle, a pedestrian, or states of the traffic signal. 24. The apparatus of claim 9, wherein the electronic hardware is further configured to determine the intersection capacity based on one or more of the following factors: a capacity of a movement, saturation flow rate, green time for the movement, startup lost time for the movement, and cycle length.
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