Systems and methods are provided for train operation control and enforcement. A vehicle mounted system for train control may include a vehicle mounted data radio mounted on a railway vehicle and a vehicle mounted controller. The vehicle mounted controller may be connected to the vehicle mounted data radio. The vehicle mounted data radio may be in wireless communication with a wayside reporting station, which may be in communication with a signal control point that is associated with a safety point that is further associated with an interlocking, and the vehicle mounted data radio may be configured to receive signal state status information from the wayside reporting station. The vehicle mounted controller may be configured to determine a distance between the railway vehicle and the safety point. The vehicle mounted data radio may be an ultra-wide band (UWB) radio.

Systems and methods are provided for train operation control and enforcement. A vehicle mounted system for train control may include a vehicle mounted data radio mounted on a railway vehicle and a vehicle mounted controller. The vehicle mounted controller may be connected to the vehicle mounted data radio. The vehicle mounted data radio may be in wireless communication with a wayside reporting station, which may be in communication with a signal control point that is associated with a safety point that is further associated with an interlocking, and the vehicle mounted data radio may be configured to receive signal state status information from the wayside reporting station. The vehicle mounted controller may be configured to determine a distance between the railway vehicle and the safety point. The vehicle mounted data radio may be an ultra-wide band (UWB) radio.

A train control method includes: acquiring a current control level of the train and outputting the current control level to a train traction control system; acquiring current train operation data and calculating an evaluation score according to the current train operation data by the train traction control system; and inputting the current train operation data and the evaluation score into a neural network learning system to adjust the current control level of the train to obtain a final outputted control level.

A railroad personnel scheduling and management system is disclosed. The system may include a personnel database storing qualification data associated with a plurality of railroad personnel and a controller comprising a personnel management module and a communication module. The controller may be configured to receive railroad asset data and personnel location data via the communication module and select a primary personnel from the plurality of railroad personnel in conjunction with the personnel management module and based on the qualification data, the railroad asset data, and the personnel location data. The controller may also be configured to generate a dispatch signal based on the railroad asset data and communicate the dispatch signal to the primary personnel via the communication module.

A method of monitoring a track using train cars includes collecting first sensor data corresponding to a track location by a first sensor network on a first train car. Based on the first sensor data, a potential track anomaly at the track location is identified by a diagnostics system on the first train car. A message describing the anomaly is transmitted to diagnostics systems located on other train cars. The message is received by a second diagnostics system on a second train car located behind the first train car. The second diagnostics system determines a time at which the second train car will be passing over track location and, at the determined time, collects second sensor data. If the track anomaly is present in both the first sensor data and the second sensor data at the track location, a train control system is notified of the track anomaly.

A method of monitoring a track using train cars includes collecting first sensor data corresponding to a track location by a first sensor network on a first train car. Based on the first sensor data, a potential track anomaly at the track location is identified by a diagnostics system on the first train car. A message describing the anomaly is transmitted to diagnostics systems located on other train cars. The message is received by a second diagnostics system on a second train car located behind the first train car. The second diagnostics system determines a time at which the second train car will be passing over track location and, at the determined time, collects second sensor data. If the track anomaly is present in both the first sensor data and the second sensor data at the track location, a train control system is notified of the track anomaly.

A monitoring system for detecting a condition in a vehicle, including at least one imaging device having a field of view including at least a portion of an interior cabin of the vehicle occupied by an operator of the vehicle during operation, a data storage medium configured to store parameter data in a database, the parameter data including control parameter data for the interior cabin of the vehicle, and at least one processor in communication with the at least one imaging device and the data storage medium. The at least one processor is programmed or configured to receive operational image data from the at least one imaging device, generate operational parameter data from the operational image data, compare the operational parameter data to the control parameter data, and determine if at least one operator is absent from the interior cabin and/or if at least one unauthorized display device is present in the vehicle.

This system utilizes autonomous rail cars that automatically couple and uncouple to and from a primary moving train. The primary train travels along a given route but never needs to stop at intermediate stations. Instead, autonomous rail cars gather passengers or goods at designated station locations and then automatically depart in order to meet up with the primary train. When the autonomous rail cars couple to the primary train, the contents of the autonomous rail car are transferred to the primary train. Likewise, contents that are already aboard the primary train which need to depart will be loaded onto this autonomous rail car. When the primary train approaches the next station, the autonomous rail car will detach and stop at the station while the primary train continues to travel on. This process repeats for each station on the route.

In a method or apparatus for transporting bulk goods by rail cars on a rail network to a rail car handling terminal where the handling terminal includes a loading and/or unloading system with a metering device for measuring an amount of the bulk goods loaded or unloaded. At the terminal there is a center control data hub connecting to a plurality of portable hand held field computers and a communication system for communication with the rail network to obtain a Car Location Message (CLM), a way bill and mechanical data for each of the rail cars. The center control hub generates data indicating a current stage of each of the railcars and a signal indicative that a rail car can be transferred from one stage to another stage to the portable computers to control transfer of the rail car from one stage to the next stage.

A temporary speed restriction safe management method for a multi-mode train control system. The method comprises: step 101, issuing a temporary speed restriction setting instruction by means of a line network dispatching system; step 102, performing a validity check on a set temporary speed restriction, and setting a first mark-drawing up after the check is successful; step 103 setting a second mark-verification; step 104, feeding a verification state or verification failure of the set temporary speed restriction back to the dispatcher; step 105, an auxiliary dispatcher issuing an execution instruction for the verified temporary speed restriction; step 106, determining that the temporary speed restriction is successfully executed; step 107, feeding an execution state or execution failure of the temporary speed restriction back to the dispatcher; and step 108, sending the temporary speed restriction to a train of a corresponding system that passes through a speed restriction zone.