A grade crossing control system includes a track transmitter configured to couple to rails of a railroad track, and a track receiver configured to couple to the rails of the railroad track, wherein the track transmitter comprises a signal source and an amplifier, and is configured to transmit a first signal to the rails, wherein the track receiver is configured to measure a second signal in response to the first signal, and wherein the track transmitter is configured to provide feedback measurement information of the first signal.

A grade crossing control system includes a track transmitter configured to couple to rails of a railroad track, and a track receiver configured to couple to the rails of the railroad track, wherein the track transmitter comprises a signal source and an amplifier, and is configured to transmit a first signal to the rails, wherein the track receiver is configured to measure a second signal in response to the first signal, and wherein the track transmitter is configured to provide feedback measurement information of the first signal.

A crossing gate mechanism includes a gate mechanism enclosure, electrical components inside the gate mechanism enclosure, and a controller inside the gate mechanism enclosure. The controller is connected to and configured to monitor and/or control the electrical components. The controller includes an operator panel for receiving input from a user. In addition, the controller has a user interface displayed by the operator panel. The controller is operable to present information associated with the electrical components on the user interface.

A crossing gate mechanism includes a gate mechanism enclosure, electrical components inside the gate mechanism enclosure, and a controller inside the gate mechanism enclosure. The controller is connected to and configured to monitor and/or control the electrical components. The controller includes an operator panel for receiving input from a user. In addition, the controller has a user interface displayed by the operator panel. The controller is operable to present information associated with the electrical components on the user interface.

A method for monitoring a danger area of a railway installation. At least one radio module is arranged in, or in the vicinity of, the danger area. Radio signals are transmitted by the radio module and the radio signals are received and evaluated. A pattern of the received radio signals in a basic state of the danger area is determined and when the radio signals are evaluated, differences from the pattern in the basic state are determined and a response is triggered when the differences exceed a predefined limit value. There is also described a monitoring device. The radio modules are preferably WLAN modules and the danger area is a tunnel. Timetabled breaches of the danger area by trains do not lead to an alarm and the radio modules are functionally tested by determining whether the predefined limit value is exceeded when a train travels through.

A system can include a signal light for regulating traffic, a controller, a first communication module configured to electronically communicate with the controller, a memory and two or more position sensors coupled to the signal light is disclosed. The two or more position sensors comprise at least a first position sensor configured to detect a first position of the signal light according to a first measurable criteria and a second position sensor configured to detect a second position of the signal light according to a second measurable criteria. The memory configured to selectively store as a reference, desired position data. The controller can be configured to electronically communicate with the two or more position sensors to receive an updated data regarding the first position and the second position and is configured to compare the updated data to the desired position data.

A system can include a signal light for regulating traffic, a controller, a first communication module configured to electronically communicate with the controller, a memory and two or more position sensors coupled to the signal light is disclosed. The two or more position sensors comprise at least a first position sensor configured to detect a first position of the signal light according to a first measurable criteria and a second position sensor configured to detect a second position of the signal light according to a second measurable criteria. The memory configured to selectively store as a reference, desired position data. The controller can be configured to electronically communicate with the two or more position sensors to receive an updated data regarding the first position and the second position and is configured to compare the updated data to the desired position data.

Systems and methods are disclosed including a system that can include a traffic gate, an electronic circuit and a portable controller. The traffic gate can have an arm. The electronic circuit can have a controller, a first communication module, and one or more light sources configured to mount to the arm or other portions of the traffic gate. The controller can be configured to control the electronic circuit to selectively operate the one or light sources as desired. The portable controller can have a second communication module configured to communicate with the first communication module to actuate the controller to control of the electronic circuit.

Systems and methods are disclosed including a system that can include a traffic gate, an electronic circuit and a portable controller. The traffic gate can have an arm. The electronic circuit can have a controller, a first communication module, and one or more light sources configured to mount to the arm or other portions of the traffic gate. The controller can be configured to control the electronic circuit to selectively operate the one or light sources as desired. The portable controller can have a second communication module configured to communicate with the first communication module to actuate the controller to control of the electronic circuit.

A grade crossing control system includes a controller that receives start and end inputs corresponding to a train traversing an outer approach, determines the difference in time between the start and end inputs, and uses the difference in time to determine a delay period by which activation of a grade crossing warning system will be delayed following detection of the train by a track occupancy circuit in an inner approach in order to compensate for slow moving trains. The start and end inputs for the outer approach may be supplied in different ways including a separate track occupancy circuit for the outer approach, by train detection devices unconnected to the track at the start and end of the outer approach, or by overlapping track occupancy circuits positioned at the start of the outer and inner approaches.