A method of railroad track control includes partitioning a physical track block into a plurality of virtual track blocks, the physical track block defined by first and second insulated joints disposed at corresponding first and second ends of a length of railroad track. The presence of an electrical circuit discontinuity in one of the plurality of virtual track blocks; is detected and in response a corresponding virtual track block position code indicating the presence of the discontinuity in the one of the plurality of virtual track blocks is generated.

A method of railroad track control includes partitioning a physical track block into a plurality of virtual track blocks, the physical track block defined by first and second insulated joints disposed at corresponding first and second ends of a length of railroad track. The presence of an electrical circuit discontinuity in one of the plurality of virtual track blocks; is detected and in response a corresponding virtual track block position code indicating the presence of the discontinuity in the one of the plurality of virtual track blocks is generated.

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.

Aspects of the disclosed embodiments generally relate to railway track circuits, in particular track circuits with continued distance monitoring and broken rail protection.

A magnetically clampable rail shunt (1) comprising two magnetic clamps (10), each clamp having a magnetic device for attaching the clamp to one of two parallel railway rails (R1, R2) of a railway track by magnetic force, and an electrical conductor (20) electrically connecting the two magnetic clamps (10) for shunting the two parallel railway rails. The rail shunt (1) is characterised by a variable electrical resistor assembly (30) for adjusting the electrical resistance of the rail shunt (1), said variable electrical resistor assembly (30) being connected in series between the two magnetic clamps (10) via said electrical conductor (20). Preferred application to testing of track circuits.

A magnetically clampable rail shunt (1) comprising two magnetic clamps (10), each clamp having a magnetic device for attaching the clamp to one of two parallel railway rails (R1, R2) of a railway track by magnetic force, and an electrical conductor (20) electrically connecting the two magnetic clamps (10) for shunting the two parallel railway rails. The rail shunt (1) is characterised by a variable electrical resistor assembly (30) for adjusting the electrical resistance of the rail shunt (1), said variable electrical resistor assembly (30) being connected in series between the two magnetic clamps (10) via said electrical conductor (20). Preferred application to testing of track circuits.

Method, system and software code for calibrating a rail track circuit comprising a plurality of rails coupled to form a track section having a predefined length, a transmit processing unit coupled to the track section at a first end of the track section, and a receive processing unit coupled at the second end of the track section. A transfer function between a transmit voltage applied by the transmit processing unit at the track section and a resulting receive current detected at the receive processing unit is first determined and then applied to the rail track circuit for automatic initial calibration or recalibration.

A system for detecting the presence of a train on a railway track (1b) comprising a plurality of sections (2a, 2b, . . . , 2n), the system comprising: a transmitter (10b) arranged to emit a main signal towards the plurality of sections (2a, 2b, . . . , 2n); a plurality of selecting devices (14a, 14b, . . . , 14n) associated respectively to the plurality of sections (2a, 2b, . . . , 2n) along the railway track (1b) and arranged to selectively allow passage of said main signal towards respective sections of said plurality of sections (2a, 2b, . . . , 2n); a receiver (12b) arranged to receive the main signal after having passed through the plurality of sections (2a, 2b, . . . , 2n); a control unit (20) associated to said receiver (12b) arranged to perform an analysis of said received signal so as to detect the presence of a train on a predetermined section (2a, 2b, . . . , 2n) of said plurality of sections (2a, 2b, 2n).

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.