A method and system for determining a separation distance between a first object and a second object comprises using a search module associated with a first object comprising a first transponder having a unique address. The method includes using a reply module associated with a second object comprising a second transponder having a different, unique address. The method includes the search module transmitting a search signal on a first frequency, said search signal including the address of the first transponder and the address of the second transponder. The reply module receives the search signal and locally validates the address included in said received search signal for the second transponder, whereby, if the validation is positive; the reply module transmits a reply signal on a second, different frequency.

A method and system for determining a separation distance between a first object and a second object comprises using a search module associated with a first object comprising a first transponder having a unique address. The method includes using a reply module associated with a second object comprising a second transponder having a different, unique address. The method includes the search module transmitting a search signal on a first frequency, said search signal including the address of the first transponder and the address of the second transponder. The reply module receives the search signal and locally validates the address included in said received search signal for the second transponder, whereby, if the validation is positive; the reply module transmits a reply signal on a second, different frequency.

Provided is a method and system for determining a separation distance between a first object and a second object. It is envisaged that at least one of the objects is a movable vehicle such as a train. The method comprises using a search module associated with a first object where said search module comprises a first transponder having a unique address. The method includes using a reply module associated with a second object where said reply module comprises a second transponder having a different, unique address. The method includes the search module transmitting a search signal on a first frequency, said search signal including the address of the first transponder and the address of the second transponder. The reply module receives the search signal and locally validates the address included in said received search signal for the second transponder, whereby, if the validation is positive; the reply module transmits a reply signal on a second, different frequency, said reply signal including the address of the second transponder and the address of the first transponder. The search module receives the reply signal and locally validates the address included in said received reply signal for at least the second transponder whereby, if the validation is positive, the search module determines a separation distance between the first object and the second object based on a time taken from transmission of the search signal to receipt of the reply signal at said search module. The local validation of the address of the second transponder at the reply module and then at the search module improves reliability of processing of reply signals and allows the method to be implemented in a stand-alone configuration not reliant on signals from external systems.

A decentralized control of rail vehicles that run in alternating directions on a single-track route, e.g., between two train stations by way of an exclusive right (token). A storage device is arranged at each end of the route, for instance an RFID unit. Only a single exclusive right exists for the route. The exclusive right is either stored in one of the two storage units or carried along by a rail vehicle that is traveling on the route. In the latter case, an additional rail vehicle is effectively prevented from traveling on the route, because none of the storage units can provide the exclusive right, which is being transported between the storage units by the rail vehicle and is occupied by the rail vehicle. The novel concept creates an efficient possibility of decentralized train protection and thus can be implemented significantly more economically than existing centralized train safety approaches.

A decentralized control of rail vehicles that run in alternating directions on a single-track route, e.g., between two train stations by way of an exclusive right (token). A storage device is arranged at each end of the route, for instance an RFID unit. Only a single exclusive right exists for the route. The exclusive right is either stored in one of the two storage units or carried along by a rail vehicle that is traveling on the route. In the latter case, an additional rail vehicle is effectively prevented from traveling on the route, because none of the storage units can provide the exclusive right, which is being transported between the storage units by the rail vehicle and is occupied by the rail vehicle. The novel concept creates an efficient possibility of decentralized train protection and thus can be implemented significantly more economically than existing centralized train safety approaches.

A work vehicle control system includes an on-board communication controller for requesting, while a current travel position indicates that the work vehicle travels in a predetermined first block section of a travel path, a travel permission request signal for permitting travel in a second block section located next to the first block section from an on-board wireless controller. The on-board communication controller, respectively coupled to an on-board wireless controller and a GPS device, changes an interval of requesting the travel permission signal in accordance with a remaining distance to an emergency stop point in the case where it is determined from a current travel position detected by the GPS device that the work vehicle is traveling in the first block section and a control center is controlling travel of the work vehicle.

A track collision avoidance control system including a train having an onboard control system for controlling one or more characteristics of the train. The track collision avoidance control system can further include a warning indication system comprising a transmitter linked to a communication system supported about the train, the communication system comprising a receiver operable to receive a signal from the transmitter, the signal comprising information pertaining to a potentially dangerous condition. The transmitter can be operable alone or in combination with a warning indicator, an actuator and their associated logic circuitry, such that the transmitter is caused to transmit upon the warning indicator being activated. The communication system can interface with an onboard control system of the train. The communication system can receive the signal, which can be used to facilitate an avoidance action to be taken relative to the train.

A track collision avoidance control system including a train having an onboard control system for controlling one or more characteristics of the train. The track collision avoidance control system can further include a warning indication system comprising a transmitter linked to a communication system supported about the train, the communication system comprising a receiver operable to receive a signal from the transmitter, the signal comprising information pertaining to a potentially dangerous condition. The transmitter can be operable alone or in combination with a warning indicator, an actuator and their associated logic circuitry, such that the transmitter is caused to transmit upon the warning indicator being activated. The communication system can interface with an onboard control system of the train. The communication system can receive the signal, which can be used to facilitate an avoidance action to be taken relative to the train.