A railroad crossing light detector system is disclosed. The system includes determining a first signal indicative of the amount of light emitted from an illuminated railroad crossing light source and determining a second signal indicative of the orientation of the crossing light. The first and second signals are transmitted to a signal determination module that compares the first and second signals to predetermined stored values. The compared signals are then provided to a railroad crossing controller for relaying to a central/remote monitoring location. In the event that at least one of the signals is out of range relative to the stored value, then an inspection request signal together with information on the location of the crossing light is provided to the central monitoring location. In this manner, the number of in-person inspections to the crossing light may be significantly reduced.

A railroad crossing light detector system is disclosed. The system includes determining a first signal indicative of the amount of light emitted from an illuminated railroad crossing light source and determining a second signal indicative of the orientation of the crossing light. The first and second signals are transmitted to a signal determination module that compares the first and second signals to predetermined stored values. The compared signals are then provided to a railroad crossing controller for relaying to a central/remote monitoring location. In the event that at least one of the signals is out of range relative to the stored value, then an inspection request signal together with information on the location of the crossing light is provided to the central monitoring location. In this manner, the number of in-person inspections to the crossing light may be significantly reduced.

A railroad crossing light detector system is disclosed. The system includes determining a first signal indicative of the amount of light emitted from an illuminated railroad crossing light source and determining a second signal indicative of the orientation of the crossing light. The first and second signals are transmitted to a signal determination module that compares the first and second signals to predetermined stored values. The compared signals are then provided to a railroad crossing controller for relaying to a central/remote monitoring location. In the event that at least one of the signals is out of range relative to the stored value, then an inspection request signal together with information on the location of the crossing light is provided to the central monitoring location. In this manner, the number of in-person inspections to the crossing light may be significantly reduced.

A first crossing predictor uses signals from a pair to spaced apart receivers, which may be located on opposite sides of a transmitter, to determine on which side of a crossing an approaching train is located. If the first predictor upstream with respect to the approaching train, the first predictor transmits signals to instruct a downstream adjacent predictor to activate its warning device at a constant warning time (referred to as DAXing).

A communication system may wirelessly receive. A crossing controller may check the message to determine whether the message is a valid vital communication. In response to determining the message is the valid vital communication, the crossing controller may deactivate at least one crossing traffic control element. While the at least one crossing traffic control element is deactivated, the crossing controller may activate the at least one crossing traffic control element in response to receiving a command to activate the at least one crossing traffic control element at the communication system. In response to determining the message is not the valid vital communication, the crossing controller may activate the at least one crossing traffic control element.

A traffic control system (TCS) is provided comprising at least one traffic control unit, TCU, (9) equipped with a proximity enabled traffic user equipment, PETUE, (1) and adapted to control traffic of mobile entities wherein the proximity enabled traffic user equipment, PETUE, (1) of said traffic control unit, TCU, (9) is configured to transmit traffic information by sending at least one discovery message, DM, directly via a user equipment to user equipment link to at least one other proximity enabled traffic user equipment, PETUE, of a mobile entity, wherein said discovery message, DM, includes a proximity service, ProSe, application identifier comprising a string of traffic labels, TLs, representing hierarchical traffic information levels.

A traffic control system (TCS) is provided comprising at least one traffic control unit, TCU, (9) equipped with a proximity enabled traffic user equipment, PETUE, (1) and adapted to control traffic of mobile entities wherein the proximity enabled traffic user equipment, PETUE, (1) of said traffic control unit, TCU, (9) is configured to transmit traffic information by sending at least one discovery message, DM, directly via a user equipment to user equipment link to at least one other proximity enabled traffic user equipment, PETUE, of a mobile entity, wherein said discovery message, DM, includes a proximity service, ProSe, application identifier comprising a string of traffic labels, TLs, representing hierarchical traffic information levels.

Systems and methods for detecting train direction and route along a railroad track. The systems and methods use wireless train presence detection sensors such as e.g., magnetometer sensors to detect the presence of the train, and its direction and route along the track.

Systems and methods for detecting train direction and route along a railroad track. The systems and methods use wireless train presence detection sensors such as e.g., magnetometer sensors to detect the presence of the train, and its direction and route along the track.