The method S100 can include: determining a remote operation request S110; optionally determining a priority of the remote operation request S120; providing vehicle data to a remote operator S130; responding to the remote operation request S140; and optionally training a model based on the response S150. However, the method S100 can additionally or alternatively include any other suitable elements. The method S100 functions to facilitate remote assistance of a vehicle operating within a rail network (e.g., operation of unmanned vehicles within restricted track regions). Additionally or alternatively, the system can function to facilitate remote validation/verification of vehicle operations and/or rail infrastructure status.

The present disclosure relates to a transportation system that includes a plurality of cabs that are attached to suspension frames suspended from a cable using multiple pairs of sheaves running freely on an overhead cable guide-way to allow balancing of total weight of the cab along the cable guide-way. The pairs of sheaves are assembled to articulate in a horizontal plane to allow easy traversing along curved cable guide-way sections. The transportation system also includes a plurality of smart electro-mechanical switches capable of disengaging continuity of line of motion of the cab from the cable guide-way section and diverting the cab onto other cable guide-way sections. Each of the plurality of cabs can be coupled with a plurality of propellers to provide thrust for forward movement, speed control, steering, stabilization of the cab from swinging on the suspension frame and stopping of the cab by reversing the thrust developed thereof.

A method for locating a railway vehicle in a railway network, including first detection devices detecting the passage of a railway vehicle in a first perimeter, second detection devices detecting the passage of a railway vehicle in a second perimeter and a centralized server, includes the following steps: detection, by one of the first detection devices, of the passage of the railway vehicle and sending of a first detection signal; detection, by one of the second detection devices, of the passage of the railway vehicle and sending of a second detection signal; and reception of the signals by the centralized server and determination of the position of the railway vehicle on the railway network by intersection of the first perimeter and the second perimeter.

A method and system for determining a position of a rail-bound vehicle on a railway is disclosed. The apparatus comprises: a transmitter and receiver for wireless communication with at least one base station arranged at a predetermined position in the vicinity of the railway; a measurement device to determine a distance to the at least one base station based on measurements of the radio signals of the wireless communication in the phase domain; and a controller arranged to determine a present position of the vehicle on the railway based on the distance. A control system/method for controlling rail-bound vehicles in a railway system, and/or an internal or external system related to such rail-bound vehicles, using such position determination is also disclosed.

A method and system for determining a position of a rail-bound vehicle on a railway is disclosed. The apparatus comprises: a transmitter and receiver for wireless communication with at least one base station arranged at a predetermined position in the vicinity of the railway; a measurement device to determine a distance to the at least one base station based on measurements of the radio signals of the wireless communication in the phase domain; and a controller arranged to determine a present position of the vehicle on the railway based on the distance. A control system/method for controlling rail-bound vehicles in a railway system, and/or an internal or external system related to such rail-bound vehicles, using such position determination is also disclosed.

Provided is a wheel detector for detecting a wheel of a rail vehicle, including two detector channels. Each channel includes a coil unit which is connected with a measurement and feeding module for feeding the coil unit with an output signal of the measurement and feeding module. A decision module of the respective channel is bi-directionally connected to the measurement and feeding module. The measurement and feeding module of each channel includes a temperature measurement module and/or a module for measurement of mechanical vibration, that is/are connected with an input/inputs of a decision module of the channel. The decision modules are connected via a bidirectional digital interface. The decision module of one channel is connected via a bidirectional digital interface with a data transmission module for communication with a supervisory system via a data transmission line.

A method for optimizing track performance is provided. The method involves measuring one or more track status data at one or more measurement sites of the track during a train pass through the one or more measurement sites. Followed by analyzing the one or more track status data against one or more baseline reference values to obtain a track status profile, and adjusting an operating parameter, a track parameter, or both the operating and track parameters, based on the track status profile, to optimize the track's performance.

A system includes one or more processors configured to communicatively link a remote-control system disposed off-board a vehicle system with an onboard vehicle control system on the vehicle system. The remote-control system and the onboard vehicle control system are configured to control movement of the vehicle system, wherein the one or more processors are configured to transfer control of the movement of the vehicle system from the remote-control system to the onboard vehicle control system based on one or more of a location, a condition of the vehicle system, or by one or more of a request or condition of an operator or from the onboard vehicle control system to the remote-control system based on the one or more of the location, the condition of the vehicle system, or by the one or more of the request or condition of the operator.

A control system for remotely configuring a locomotive includes a plurality of operational control devices located on-board the locomotive, the plurality of operational control devices being configured to implement a change to a designated configuration of the locomotive. A controller located on-board the locomotive is configured to activate the plurality of operational control devices to change the designated configuration of the locomotive upon receipt of a configuration command signal. An off-board remote user interface located remotely from the locomotive is configured to receive a single input from a user commanding a change in configuration of the locomotive, the single input being implemented by activation of a single input device on the remote user interface, and selectively send a configuration command signal to the on-board controller to activate the plurality of operational control devices to change the designated configuration of the locomotive.

A system that includes a controller that may receive one or more input characteristics related to upcoming movement of a group of vehicles, the one or more input characteristics indicative of an amount of energy needed to move the group of the vehicles along a segment of a route. The controller may also calculate a threshold range of tractive effort needed to move the group of the vehicles along the segment of the route based on the one or more characteristics and to monitor the tractive effort expended by a propulsion-generating vehicle of the vehicles in the group to move one or more of the vehicles in the group, and determine whether the vehicles in the group are coupled with each other or whether two or more of the vehicles are not coupled with each other based on the tractive effort that is monitored and the threshold range.