A event recorder system carried on-board a locomotive may include a controller configured to receive data from one or more of a train management system, a cab signaling system, an energy management system, an exhaust aftertreatment monitoring system, a braking system, a communications management system, and an operator fatigue or distraction monitoring system. The data may include one or more of video data, audio data, sensor output data, GPS map data, scanned image data of an operator in a cab of the locomotive, and operational data associated with operation of the locomotive during a trip. The controller may be configured to synchronize the data based on a common attribute associated with all of the data received by the controller, receive from a user one or more customizable parameters predetermined to be indicative of one or more of a system-related characteristic or behavior associated with any one or more of the systems from which the controller receives data, and generate a system notification based on an indication of one or more of a system-related characteristic or behavior that one of falls outside of a predetermined range of system-determinable parameters, or indicates a trend in one or more system-determinable parameters that deviates from an expected trend in the one or more system-determinable parameters.

A control system for remotely facilitating a lead change among a plurality of locomotives in a train is disclosed. The control system may include a user input device, a display device, a communicating device configured to exchange information with the plurality of locomotives, and a controller in electronic communication with the user input device, the display device, and the communicating device. The controller may be configured to generate on the display device a graphical user interface configured to receive a plurality of user inputs in conjunction with the user input device, wherein the plurality of user inputs includes an isolation switch selection, a distributed power selection, and a lead/trail selection. The controller may also be configured to generate configuration commands communicable to the plurality of locomotives via the communicating device based on the user inputs.

A distributed power system includes a communication device and a control device. The communication device is configured to be disposed onboard a first vehicle of a vehicle system that also includes at least a second vehicle. The communication device is configured to communicate a discover message. The control device is configured to be operatively connected to the communication device, and, responsive to the communication device receiving a discover reply message from a second vehicle, to generate a configure message for the communication device to transmit to the second vehicle based on an identifier of the second vehicle included in the discover reply message. The configure message includes instructions for the second vehicle to transition to a remote mode of operation in which remote control of tractive and braking efforts of the second vehicle is enabled.

An unmanned rail vehicle for surveillance, inspection and/or maintenance of an infrastructure, the infrastructure including a rail structure with a rail, the unmanned rail vehicle being movable along the rail and the unmanned rail vehicle including a first position sensor system configured for measuring, by interaction with the rail structure, first position data indicative of a position of the unmanned rail vehicle along the rail, a second position sensor system configured for measuring, by interaction with the rail structure, second position data indicative of a position of the unmanned rail vehicle along the rail, a position determining unit configured for receiving and combining first and second position data to determine the position of the unmanned rail vehicle along the rail.

A rail vehicle includes a vehicle unit having operating device subsystems and a guide system including a first guide system level in which operating device subsystems are networked with one another by using a digital data bus structure, and at least one second guide system level having at least one line set associated with the analog handling of processes in the operating device subsystems. In order to provide a generic rail vehicle in which a high level of safety can be achieved with little outlay on wiring, the vehicle unit includes a guide system interface device having a first interface unit associated with the data bus structure, at least one second interface unit associated with the line set, and a control unit which, in at least one operating mode, is provided for handling the processes through the second interface unit.

In order to save energy, it is proposed that parts of a signaling system be switched off, for example, by an operating system. The computers to be switched off store data which are relevant to railway safety, preferably on a central storage medium, for example, an NAS hard drive. When they have been reactivated, the computers read the safety-relevant data and operation can continue. This solution also enables computers which work with data relevant to railway safety to be switched to an energy-saving mode without endangering the safety of the railway.

A method and an apparatus for a train control system are disclosed, and are based on virtualization of train control logic and the use of cloud computing resources. A train control system is configured into two main parts. The first part includes physical elements of the train control system, and the second part includes a virtual train control system that provides the computing resources for the required train control application platforms. The disclosed architecture can be used with various train control technologies, including communications based train control, cab-signaling and fixed block, wayside signal technology. Further, the disclosure describes methodologies to convert cab-signaling and manual operations into distance to go operation.

The present disclosure relates to a CPU module for processing railway signals, and more specifically to a CPU module for processing railway signals that controls operation timing of a first comparator, a signal processing unit and a second comparator.

A rail vehicle has a set of operational subsystems and a driver's cab display device for displaying information to the driver of the vehicle. The driver's cab display device has at least one central display unit. The novel rail vehicle enables flexible and targeted outputting of information to the driver of the vehicle. For that purpose, the driver's cab display device has a control unit which is connected upstream of the display unit and which is provided to organize a dynamic information content, relating to multiple operational subsystems, for the display unit.

A vehicle positioning system includes processing circuitry in communication with the vehicle. The system further includes a memory connected to the processing circuitry, where the memory is configured to store executable instructions that, when executed by the processing circuitry, facilitate performance of operations. The operations include to receive vehicle-speed data from a first set of sensors operably coupled to the vehicle. The operations further include to predict a vehicle location based on the vehicle-speed data. The operations further include to receive inertial data from a second set of sensors operably coupled to the vehicle, and update the predicted vehicle location based upon the inertial data.