A system for enhancing personnel safety on a railroad track is presented. The system can receive data from sensors and/or a PTC system to determine positions of clients/worker and/or vehicles, and further utilize such data to determine if a vehicle is within a certain proximity of the client/worker location. The system can further generate geofences around clients/vehicles to and determine when such geofences intersect one another. Additionally, the present disclosure can assign severity levels and generate alerts with the assigned severity levels, and such severity levels can indicate how close a vehicle is to a particular location. It is an object of the invention to provide a system for generating alerts to notify personnel when they much retreat to a place of safety.

In an embodiment, a system for detection of trains at railroad crossings is provided. The system comprises a field-deployed detection and reporting device comprising a microphone, a communication module, a microprocessor, and an application. When executed on the microprocessor, the application receives data describing sounds captured by the microphone and identifies frequencies of a first received sound. The application also transmits, based on the identified frequencies and a formula, a first message via the communication module. The first received sound is generated by a warning bell sounded at the railroad crossing. The first message is received by a backend server that issues a first broadcast based on receipt of the first message. The application further determines that the first received sound discontinues. Based on the determination, the application sends a second message via the module to the backend server which issues a second broadcast that the crossing is reopened.

In an embodiment, a system for detection of trains at railroad crossings is provided. The system comprises a field-deployed detection and reporting device comprising a microphone, a communication module, a microprocessor, and an application. When executed on the microprocessor, the application receives data describing sounds captured by the microphone and identifies frequencies of a first received sound. The application also transmits, based on the identified frequencies and a formula, a first message via the communication module. The first received sound is generated by a warning bell sounded at the railroad crossing. The first message is received by a backend server that issues a first broadcast based on receipt of the first message. The application further determines that the first received sound discontinues. Based on the determination, the application sends a second message via the module to the backend server which issues a second broadcast that the crossing is reopened.

Disclosed is a method for determining the relationship between a track-circuit current signal and a railway vehicle location, including: sending, by a track circuit, current signal across a railway track block; measuring the current signal for different railway vehicles running successively on the railway track block; aligning the measured current signals and calculating a reference curve as the average value of all the aligned curves by using a Dynamic Time Warping algorithm, this reference curve representing the relationship between the track-circuit current signal and the railway vehicle location on the railway track block.

A method to determine the position of a locomotive (100) by having a first device (306) measuring the electromotive force from a propelling motor (105) and calculating the speed; combined with detection of fixed reference points by measuring of the magnetic field generated by permanent magnets (106) at known positions. At regular intervals this information is passed to a second device (108). By use of a pattern recognition algorithm the second device estimates the position and operates the locomotive according to location-based behavior. The first device characterized by having a magnetic field sensor (302) integrated on an ordinary model railroad decoder, which already supports motor measurement and packet transmission. The second device characterized by having a data packet receiver (403) and an Ethernet interface (405) for communication with a command station (109). A microcontroller (402) utilizes a parameterized representation of the model railroad layout to determine the position of the locomotive. From the position proper behavior is determined and corresponding speed commands are sent to the command station. Other methods and embodiments are described and shown.

A forward monitoring apparatus is installed on a train, and includes: a monitoring unit that monitors a situation ahead of the train; a storage unit that stores map information including information on a position of a track, a shape of the track, and a position of a turnout provided on the track; a train position acquisition unit that acquires train position information indicating a position of the train; a route information acquisition unit that acquires open route information including information for indicating an open direction of the turnout located ahead of the train; and a monitoring direction determination unit that determines a direction to be monitored by the monitoring unit, by using the open route information acquired, the train position information acquired, and the map information being stored in the storage unit.

A forward monitoring apparatus is installed on a train, and includes: a monitoring unit that monitors a situation ahead of the train; a storage unit that stores map information including information on a position of a track, a shape of the track, and a position of a turnout provided on the track; a train position acquisition unit that acquires train position information indicating a position of the train; a route information acquisition unit that acquires open route information including information for indicating an open direction of the turnout located ahead of the train; and a monitoring direction determination unit that determines a direction to be monitored by the monitoring unit, by using the open route information acquired, the train position information acquired, and the map information being stored in the storage unit.

A vehicle control system includes a controller disposed onboard a first vehicle system and comprising one or more processors. The controller is operably connected to a propulsion and braking subsystem of the first vehicle system. The controller is configured to analyze a notification message received from an off-board source as the first vehicle system travels on a route. The notification message identifies an unplanned brake application made by a second vehicle system. In response to the notification message, the controller is configured to control the propulsion and braking subsystem to modify movement of the first vehicle system based at least in part on a location of the second vehicle system to avoid the second vehicle system.

The train detection system comprises a wireless communication network further comprising train detection modules attached to catenary poles at the entrance and exit of the railyard. Each train detection module is equipped with a plurality of diverse sensors configured to detect trains and other on-track vehicles. The diverse sensors are simultaneously active and work together for detecting an approaching or leaving train. The train detection modules generate train alerts which are transmitted wirelessly over the wireless communication network. Each of the railyard workers wears a personal alert device capable of wirelessly connecting with the train detection modules and receiving the train alerts over the said wireless communication network. The train alert modules are capable of transmitting alerts wirelessly to personal alert devices and other train alert modules. Train alert modules are capable of generating audio visual warnings for any personnel which may not be equipped with personal alert module.

A train-information management device mounted on a train, includes: an intra-block position calculator to convert information on a kilometrage that indicates a position of the train into information on a block number and an intra-block position of a plurality of blocks into which a route of the train is divided and that are used when a train position is specified by a train radio system; and an on-board router to communicate the information on the block number and the intra-block position to a ground side by using a system that is different from a system that is used for communication between the ground side and a train side via a radio base station in the train radio system.