Provided is an electric dual-mode wiper system for a railway vehicle. The electric dual-mode wiper system for a railway vehicle includes a first wiper drive unit and a second wiper drive unit, and controls a synchronization operation of the first wiper drive unit and a second wiper drive unit.

A system and method for automating workflow and performing root cause analysis for enforcement events is presented. The system can enable accurate detection of an enforcement event and identifies the root cause of such events. The system can provide a user with an interface to monitor the enforcement event by collecting a list of data characterizing the enforcement event, as well as analyze the data to evaluate what is the root cause of the enforcement event. The system can extract critical information from train system logs of the train using an extraction model to generate a window of activity providing an analysis model with a comprehensive scope to analyze the enforcement event. The system can give the user robust and accurate information of the root cause of the enforcement event.

Control software, which is intended for a multiplicity of rail vehicles, contains basic functions that are required for the basic operation of the rail vehicles. In addition, optional functions are implemented in the control software which are required for carrying out customer-specific requests. The basic functions and the optional functions are tested, validated and approved in their specifications, combinations and functional processes prior to installation in the rail vehicles. The basic functions and the optional functions are then implemented in the rail vehicles. In a selected rail vehicle, at least one optional function is activated or deactivated using a switching parameter which is individually associated with the optional function. The required switching parameter is created outside of the rail vehicle and subsequently transferred to the selected rail vehicle. The switching parameter is transferred encrypted to the selected rail vehicle, selectively specific to an individual vehicle.

In the present invention, a resource management device receives transmission of a reservation request for a block section to be reserved from among a plurality of block sections included in a track traveled by a vehicle on the basis of track information which indicates the plurality of block sections and the connection relationships of the block sections. In a case where the block section to be reserved, as indicated by the reservation request, has not already been reserved by a vehicle other than the vehicle that transmitted the reservation request at the point in time when such reservation request was received, the following is recorded in a management table: that the block section to be reserved as indicated by the reservation request and a connection boundary between that block section and another block section are objects reserved for the vehicle that transmitted the reservation request.

A controller for a vehicle includes a processor configured to repeatedly perform operations, at each control iteration among a plurality of control iterations along a path of the vehicle from a start location to a target location. The operations include, based on a current state of the vehicle, generating a travel plan for a remainder of the path from a current position of the vehicle to the target location, by solving an optimization problem. The operations further include controlling a motoring and braking system of the vehicle to execute the generated travel plan until a next control iteration among the plurality of control iterations.

Systems and methods are provided for vehicle host interface module (vHIM) based braking solutions and use thereof in trains.

A self-learning vehicle control system, the control system including: a controller configured to receive one or more of the following inputs: actual propulsion effort command; actual braking effort command; requested speed command; change in the requested speed command; change in the requested acceleration command; measured vehicle location; measured vehicle 3-D speed; measured vehicle 3-D acceleration; and measured vehicle 3-D angular speed; and one or more position determination sensors communicably connected with the controller; one or more 3-D speed determination sensors communicably connected with the controller; one or more 3-D acceleration determination sensors communicably connected with the controller; one or more 3-D angular speed determination sensors communicably connected with the controller; and an output device communicably connected with the controller and for providing requested speed and acceleration commands.

Fluorinated carbonates comprising two oxygen bearing functional groups, methods for the preparation thereof, and their use as solvent or solvent additive for lithium ion batteries and supercapacitors are disclosed.

To facilitate determination of start of an operation of a new transportation that can cope with the travel demand in an area where multiple transportations and travel routes are present. A transportation demand and supply matching system 10 includes a storage device 2011 that stores information on travel demand and transportation supply capability in a predetermined area, and an arithmetic device 2041 that estimates a congested transportation and a congested route in the area based on the information on the travel demand and the transportation supply capability, estimates an avoidance route for avoiding the congested route, and a provisional transportation which is not operated but has to be operated on the avoidance route in the area by a predetermined algorithm, and outputs information on each of the avoidance route and the provisional transportation to a predetermined device.

A power control system for a vehicle system identifies coupler nodes in the vehicle system for travel of the vehicle system along a route. The coupler nodes represent slack states of couplers between vehicles in the vehicle system. The system also determines combined driving parameters at locations along the route where a state of the coupler nodes in the vehicle system will change within the vehicle system during the upcoming movement of the vehicle system. The system determines a restriction on operations of the vehicle system to control the coupler nodes during the upcoming movement of the vehicle system and to distribute the combined driving parameters among two or more of the vehicles.