An intelligent traffic control system may be configured to manage autonomous vehicle traffic, such as by communicating with autonomous vehicles. The intelligent traffic control system may be configured to output an indication of a traffic control command to autonomous vehicles and non-autonomous vehicles. The intelligent traffic control system may be configured to determine traffic control commands for autonomous vehicles and non-autonomous vehicles.

A system includes a support, a sensor coupled to the support and arranged to output signals in a direction towards a haul road on which a machine traverses, an indicator coupled to the support, a first line coupled to the support, and a second line coupled to the support. Sensor data is received from the sensor, and based on the sensor data, a position of the machine on the haul road is determined. An alignment of the machine on the haul road is determined, where the alignment is associated with the machine maintaining contact with the first line and the second line. An indication is displayed for laterally aligning the machine on the haul road.

A system includes a support, a sensor coupled to the support and arranged to output signals in a direction towards a haul road on which a machine traverses, an indicator coupled to the support, a first line coupled to the support, and a second line coupled to the support. Sensor data is received from the sensor, and based on the sensor data, a position of the machine on the haul road is determined. An alignment of the machine on the haul road is determined, where the alignment is associated with the machine maintaining contact with the first line and the second line. An indication is displayed for laterally aligning the machine on the haul road.

A roadside relay apparatus includes first, second, and third communication units to which first, second, and third lines described below are connected, a communication processing unit configured to relay or intercept communication between the first and second communication units, and an information processing unit configured to generate signal information for a vehicle, based on a control command, for controlling a traffic signal controller, received by the first communication unit and based on details of control, performed by the traffic signal controller, received by the second communication unit, and to output the generated signal information to the third communication unit. The first, second, and third lines are communication lines for wired communication with a central apparatus of a traffic control system, the traffic signal controller, and a communication apparatus that belongs to a communication system configured to wirelessly provide information to the vehicle, respectively.

A roadside relay apparatus includes first, second, and third communication units to which first, second, and third lines described below are connected, a communication processing unit configured to relay or intercept communication between the first and second communication units, and an information processing unit configured to generate signal information for a vehicle, based on a control command, for controlling a traffic signal controller, received by the first communication unit and based on details of control, performed by the traffic signal controller, received by the second communication unit, and to output the generated signal information to the third communication unit. The first, second, and third lines are communication lines for wired communication with a central apparatus of a traffic control system, the traffic signal controller, and a communication apparatus that belongs to a communication system configured to wirelessly provide information to the vehicle, respectively.

Traffic signals that adapt to traffic conditions are provided with countdown timers. These countdown timers count down from some number towards zero, and indicate the approximate duration remaining before a traffic signal changes state. Since the traffic signal is continuously adapting to traffic conditions, the exact time before a state change occurs is not known in advance. Using a countdown algorithm, the countdown timers imperceptibly modify the countdown sequence in real time so that the traffic signal state change coincides approximately with the moment the countdown reaches its minimum count.

Traffic signals that adapt to traffic conditions are provided with countdown timers. These countdown timers count down from some number towards zero, and indicate the approximate duration remaining before a traffic signal changes state. Since the traffic signal is continuously adapting to traffic conditions, the exact time before a state change occurs is not known in advance. Using a countdown algorithm, the countdown timers imperceptibly modify the countdown sequence in real time so that the traffic signal state change coincides approximately with the moment the countdown reaches its minimum count.

The programming of traffic lights systems (TLS) in cities is a complex optimization problem. The main problem of the actual process is that this is a long, expensive and imprecise process that must be repeated regularly to reflect changes in traffic flow. The invention consists of using Vehicular's ad hoc networks (VANET) to collect traffic data in real time and transmit them to a traffic management system. VANET is currently defined by the IEEE 802.11p standard. We propose to use VANET in correlation with others techniques to control TLS. This invention will permit to program actual TLS more efficiently, manage a network in real-time and it will be possible to be used for urban planning studies, transport planning or to simulate the exit of special events (sporting, cultural, parades, etc.). It also allows programming TLS in real time with any efficient algorithm that exists or to be developed.

The programming of traffic lights systems (TLS) in cities is a complex optimization problem. The main problem of the actual process is that this is a long, expensive and imprecise process that must be repeated regularly to reflect changes in traffic flow. The invention consists of using Vehicular's ad hoc networks (VANET) to collect traffic data in real time and transmit them to a traffic management system. VANET is currently defined by the IEEE 802.11p standard. We propose to use VANET in correlation with others techniques to control TLS. This invention will permit to program actual TLS more efficiently, manage a network in real-time and it will be possible to be used for urban planning studies, transport planning or to simulate the exit of special events (sporting, cultural, parades, etc.). It also allows programming TLS in real time with any efficient algorithm that exists or to be developed.

A collision accident prevention method, apparatus, server, and computer program are proposed. The method can include predicting, based on data on a three-dimensional (3D) space corresponding to a caution zone, motion of each of at least one pedestrian in the caution zone and at least one vehicle in the caution zone. The method may also include determining, based on the predicted motion, a degree of risk of collision between the at least one pedestrian and the at least one vehicle. The method may further include providing a message corresponding to the determined degree of risk of collision to the at least one vehicle.