A driver's cab configuration for a rail vehicle includes a driving settings device operable by a vehicle driver for setting a desired driving behaviour of the rail vehicle, and a memory device in which a target driving behaviour profile for the rail vehicle is stored. The driver's cab configuration includes an operating actuator which is configured to operate the driving settings device based on the target driving behaviour profile, and a drive control device which is configured to control at least a drive device of the rail vehicle based on operations the driving settings device. A method for operating a rail vehicle is also disclosed.

A mid of train (MOT) mobile unit for use with a train is provided. The MOT mobile unit comprises a first hose for mounting the MOT mobile unit between first and second railway cars of the train located near a middle of the train and a radio for communications with an end of train (EOT) unit disposed on one end of the train and for communications with a head of train (HOT) unit disposed on other end of the train. With the first radio, the MOT mobile unit provides a repeater device functionality for communicating between the EOT unit and the HOT unit. The MOT mobile unit is configured to receive a power from a brake line of the train that runs a length of the train, wherein the power is derived from a compressed air in the brake line by means of an air-powered generator that recharges a battery.

A parking verification system and method, a movement verification system and method, and a monitoring system and method for a train, or other transit vehicle.

A method includes obtaining data relating to operation of a first vehicle in a vehicle consist that includes the first vehicle and a second vehicle communicatively coupled with each other by a communication channel. The first vehicle includes a first electronic component performing functions for the first vehicle using the first data. The method also includes communicating the first data over the communication channel from the first vehicle to a second electronic component disposed onboard the second vehicle responsive to the first electronic component being unable to perform the one or more functions for the first vehicle using the first data. The method further includes performing the functions of the first electronic component with the second electronic component using the first data that is received from the first vehicle.

A train tracking system includes a train tracking module, a plurality of input sources providing train related information, and one or more interface(s) associated with the train tracking module, wherein the train tracking module is configured via computer executable instructions and through operation of a processor to receive the train related information from the plurality of input sources via the one or more interface(s), determine a position of a train within a train track map, and determine a location attribute for the position of the train.

According to some embodiments, a railcar monitoring system for monitoring one or more conditions associated with a railcar comprises a railcar controller and one or more sensors disposed throughout the railcar and communicably coupled to the railcar controller. The railcar controller is configured to exchange data with the one or more sensors and transmit data from the one or more sensors to a remote location. An amount of data exchanged between the railcar controller and the one or more sensors is controlled based on a railcar context. The railcar context is based on a location and/or activity associated with the railcar.

A train control system comprising a vital brake interface unit that is disposed between the train control processors and the braking system. The brake interface unit ensures that any failure in the control processors or the interface itself is detectable and, when detected, causes the system to fail safely (i.e., the train's brakes are applied). By virtue of the use of redundant circuitry paths, the vital braking interface unit enables real-time verification of system circuitry without actually applying the train's brakes.

A cabin monitoring system is disclosed for use with a machine having an operator cabin. The cabin monitoring system may have a scanner oriented inward to capture images inside the operator cabin, and a controller in communication with the scanner. The controller may be configured to determine a change in conditions inside the operator cabin, and to selectively affect operation of the scanner based on the change in conditions.

A railroad control system is disclosed for a network of trains. The system may include a centralized control system configured to transmit trip parameters for each train in the network. The system may include an energy manager in communication with the centralized control system and located onboard each train. The energy manager may be configured to determine an energy profile for a consist of the train based on the trip parameters. The system may further include a consist manager located onboard the consist and configured to determine a distribution of the energy profile for each locomotive of the consist. The system may also include one or more locomotive managers, each associated with a locomotive of the consist, and configured to determine a power configuration of the one locomotive based on the distribution of the energy profile and known parameters of the locomotive.

A method and a system are provided for data management in a transport device, in particular in a train. In a first comparison, a first count value stored in a first control device is compared with a count value stored in a second control device. In a second comparison, a count value selected from the first and second count values on the basis of a result of the first comparison is compared with a control count value stored in a safety device. On the basis of a result of the second comparison, control data stored in the safety device and associated with the control count value are acquired by the first or second control device.