A method includes obtaining one or more images of a segment of a route from a camera while a vehicle is moving along the route. The segment of the route includes one or more guide lanes. The method also includes comparing, with one or more computer processors, the one or more images of the segment of the route with a benchmark visual profile of the route based at least in part on an overlay of the one or more images onto the benchmark visual profile or an overlay of the benchmark visual profile onto the one or more images. The one or more processors identify a misaligned segment of the route based on one or more differences between the one or more images and the benchmark visual profile and respond to the identification of the misaligned segment of the route by modifying an operating parameter of the vehicle.

A method includes obtaining one or more images of a segment of a route from a camera while a vehicle is moving along the route. The segment of the route includes one or more guide lanes. The method also includes comparing, with one or more computer processors, the one or more images of the segment of the route with a benchmark visual profile of the route based at least in part on an overlay of the one or more images onto the benchmark visual profile or an overlay of the benchmark visual profile onto the one or more images. The one or more processors identify a misaligned segment of the route based on one or more differences between the one or more images and the benchmark visual profile and respond to the identification of the misaligned segment of the route by modifying an operating parameter of the vehicle.

A rail vehicle, such as a power car or a locomotive, has a drive and brakes, and a drive controller for controlling the drive and the brakes of the rail vehicle. An operating device for the drive controller has a device for modifying the operating mode of the rail vehicle. The operating device has an operating lever, which can be operated by an operator of the rail vehicle, for operating the drive controller. In order to simplify the operation of the rail vehicle, the function of the operating lever is dependent on the operating mode of the rail vehicle.

A rail vehicle, such as a power car or a locomotive, has a drive and brakes, and a drive controller for controlling the drive and the brakes of the rail vehicle. An operating device for the drive controller has a device for modifying the operating mode of the rail vehicle. The operating device has an operating lever, which can be operated by an operator of the rail vehicle, for operating the drive controller. In order to simplify the operation of the rail vehicle, the function of the operating lever is dependent on the operating mode of the rail vehicle.

According to various aspects, exemplary embodiments are disclosed of devices, systems, and methods related to tracking location of operator control units for locomotives. In an exemplary embodiment, an operator control unit includes a user interface configured to receive one or more commands from an operator for controlling a locomotive. The operator control unit also includes receiver configured to receive location information of the operator control unit, and a wireless communication device. The wireless communication device is configured to transmit command data corresponding to the one or more commands and location data corresponding to the location information to a machine control unit on the locomotive.

According to various aspects, exemplary embodiments are disclosed of devices, systems, and methods related to tracking location of operator control units for locomotives. In an exemplary embodiment, an operator control unit includes a user interface configured to receive one or more commands from an operator for controlling a locomotive. The operator control unit also includes receiver configured to receive location information of the operator control unit, and a wireless communication device. The wireless communication device is configured to transmit command data corresponding to the one or more commands and location data corresponding to the location information to a machine control unit on the locomotive.

A housing of a railway vehicle device includes a reinforcing member and at least one first exterior member. The reinforcing member includes a first support member extending in a X-axis direction, and second support members that are fixed to the first support member while main surfaces are oriented in a direction intersecting the X-axis direction, the second support members being plate-like members. The first exterior members are thin plate-like members that are fixed to side surfaces of the second support members, cover a periphery of the reinforcing member, and form housing surfaces extending along the X-axis direction. In each of the first exterior members, cutouts each are formed extending in a direction intersecting the X-axis direction from the both ends in the direction intersecting the X-axis direction. An opening is formed, by the cutouts, in at least one of the housing surfaces extending along the X-axis direction.

A housing of a railway vehicle device includes a reinforcing member and at least one first exterior member. The reinforcing member includes a first support member extending in a X-axis direction, and second support members that are fixed to the first support member while main surfaces are oriented in a direction intersecting the X-axis direction, the second support members being plate-like members. The first exterior members are thin plate-like members that are fixed to side surfaces of the second support members, cover a periphery of the reinforcing member, and form housing surfaces extending along the X-axis direction. In each of the first exterior members, cutouts each are formed extending in a direction intersecting the X-axis direction from the both ends in the direction intersecting the X-axis direction. An opening is formed, by the cutouts, in at least one of the housing surfaces extending along the X-axis direction.

A locomotive engine control system includes one or more processors operably connected to fuel supply devices. The fuel supply devices are configured to supply fuel into different corresponding cylinders of an engine. The one or more processors are configured to monitor a fuel quantity injected into the cylinders of the engine before and after communication of an overfuel control signal. The overfuel control signal commands the fuel supply device corresponding to a first cylinder of the cylinders to supply excess fuel into the first cylinder. Responsive to the fuel quantity that is monitored not decreasing after the communication of the overfuel control signal, the one or more processors are configured to determine that the fuel supply device corresponding to the first cylinder is defective, and may generate one or more control signals indicative of the fuel supply device corresponding to the first cylinder being defective.

A locomotive engine control system includes one or more processors operably connected to fuel supply devices. The fuel supply devices are configured to supply fuel into different corresponding cylinders of an engine. The one or more processors are configured to monitor a fuel quantity injected into the cylinders of the engine before and after communication of an overfuel control signal. The overfuel control signal commands the fuel supply device corresponding to a first cylinder of the cylinders to supply excess fuel into the first cylinder. Responsive to the fuel quantity that is monitored not decreasing after the communication of the overfuel control signal, the one or more processors are configured to determine that the fuel supply device corresponding to the first cylinder is defective, and may generate one or more control signals indicative of the fuel supply device corresponding to the first cylinder being defective.