Systems, devices, media, and methods are presented for controlling remote equipment in a network. A switch heater control system includes a weather modeling function. The system periodically obtains weather data according to a predetermined time interval. Based on the closest weather data set, the weather modeling function generates a hyperlocal forecast associated with each switch heater location. The system includes an active snowfall mode and a maintenance mode that controls heating based on an estimate of local snow depth, adjusted for wind conditions and passing trains. When the hyperlocal forecast indicates heating is required, the system calculates a melt duration, starts a timer, and transmits a start signal to the switch heater.

A supplemental shunting device indicator (SSDI) for use with respect to a shunting device for a railroad. The SSDI comprises a housing. The housing comprises a light, a clamp for surrounding at least a portion of the shunting device, a power supply, and a current-sensing switch configured to electrically connect the power supply and the light in response to detection of a current.

A warning system comprising an advanced preemption system is provided to provide warning of an additional advanced preemption time directly from a wayside inspector to a city traffic controller to turn one or more traffic lights red on a route intersecting with the railroad crossing. The advanced preemption system includes a first set of wireless magnetometers to be installed on a railway track of the railroad crossing on a first side of the railroad crossing. The first set of wireless magnetometers to be located at an advanced preemption crossing start activation point that is being at a distance before an existing crossing start activation point of the railroad crossing to provide the warning of the additional advanced preemption time.

System, method and portable device for analyzing signals travelling along track circuits of railway lines, wherein at least one antenna captures, in a contactless manner, a plurality of signals travelling along a track circuit, and a demodulator is adapted to separate into individual signals the plurality of signals captured by the antenna and selectively demodulate one or more of the captured signals. An interface is adapted for transferring, to a user interface, data indicative of the demodulated signals. Each demodulated signal is displayed on a screen for a user to trigger any needed corrective action.

A multiple-input multiple-output (MIMO) based vehicle-mounted system may include a first plurality of antennas and a second plurality of antennas, with an antenna of the first plurality having different polarization than an antenna of the second plurality, an antenna of the first plurality and an antenna of the second plurality having antenna patterns in a different direction relative to at least another antenna of the first plurality and another antenna of the second plurality, and an antenna pattern of one antenna of the first plurality and an antenna pattern of one antenna of the second plurality being directed at least approximately parallel to the path. A corresponding MIMO-based stationary system may include at least a first plurality of antennas and a second plurality of antennas, with radiation patterns of the first and second pluralities being configured to overlap within an area between the first and second pluralities.

Systems, devices, media, and methods are presented for controlling remote equipment in a network. A switch heater control system includes a weather modeling function. The system periodically obtains weather data according to a predetermined time interval. Based on the closest weather data set, the weather modeling function generates a hyperlocal forecast associated with each switch heater location. The system includes an active snowfall mode and a maintenance mode that controls heating based on an estimate of local snow depth, adjusted for wind conditions and passing trains. When the hyperlocal forecast indicates heating is required, the system calculates a melt duration, starts a timer, and transmits a start signal to the switch heater.

A railroad measurement system includes a railroad track powered measurement device providing measurement signals of electrical quantities across rails of a railroad track; a wayside control device adapted to receive the measurement signals provided by the railroad track powered measurement device; and a communication network interfacing with the railroad track powered measurement device and adapted to transmit data, wherein the railroad track powered measurement device is adapted to transmit the measurement signals of the electrical quantities via the communication network, and the wayside control device is adapted to receive the measurement signals.

The railroad track wire connection is configured for electrically connecting a first element of a railroad installation to a second element of the railroad installation, the first element and the second element being electrically conductive, at least one of the first element and the second element being a rail of a line of rails of a railroad track of the railroad installation. The railroad track wire connection comprises at least one first element wire having a proximal end for connection to the first element and a distal end, a first element connector provided at the distal end of each first element wire, the first element connector being configured for electrical connection with the second element directly or via a mating second element connector, wherein the first element connector comprises a magnetic element for generating a magnetic force with the second element for fixing the first element connector to the second element in a removable manner or with a magnetic element of the second element connector for fixing the first element connector to the second element connector in a removable manner.

Systems and methods are provided for multiple-input multiple-output (MIMO) based communications between moving vehicles and stationary communication systems located along tracks used by the vehicles. A vehicle-mounted system may include antenna sets, each including a plurality of antennas mounted onto a vehicle, with each plurality of antenna having at least two pairs of antennas with orthogonal polarization with respect to each other, and within each pair the antennas being configured to have full pattern diversity based on direction of travel. A stationary communication system may include antenna systems configured to provide at least two cross-polarized RF antenna patterns in the opposite directions along a particular track. The RF antenna patterns may overlap along a section of the track. The two antenna patterns may be utilized in receiving and/or transmitting two sets of different independent signal channels.

A grade crossing control system includes a track circuit with a grade crossing predictor (GCP) system coupled to rails of a railroad track at a grade crossing, wherein a railroad vehicle travelling on the railroad track causes a change of impedance when entering the track circuit, and wherein the GCP system generates grade crossing activation signals in response to the change of the impedance of the track circuit, wherein, for detecting the change of impedance, the GCP system includes a first transmitter transmitting a first signal over the track circuit and a first receiver detecting a first response signal, a second transmitter transmitting a second signal over the track circuit and a second receiver detecting a second response signal, wherein the first transmitter and the first receiver are preprogrammed to a first frequency, and wherein the second transmitter and the second receiver are preprogrammed to a second frequency.