System and methods for detecting an operational status of a valve or passageway on a railway asset. The methods may comprise: resiliently biasing a magnet in a direction away from a wireless sensor node coupled to the passageway; determining that the passageway is in an open position when the wireless sensor node is neutrally polarized (the data collection device being neutrally polarized when the magnet is distant therefrom); causing the magnet to move in a direction towards the wireless sensor node responsive to a cover of the passageway being closed; and determining that the passageway is in a closed position when the wireless sensor node is magnetically polarized (the wireless sensor node being magnetically polarized when the magnet is proximate thereto).

An engineer recertification assistant that utilizes a real-time data acquisition and recording system (DARS), a DARS viewer, and a video analytics system for mobile assets. DARS includes a data recorder, an onboard data manager, and at least one local memory module. The video analytics system processes video data from at least one camera and operational data from the data recorder for critical events and regulatory requirements based on a mobile asset operator's operational performance. The processed video data and operational data is display, along with episodes, exceptions, and user comments, on a display device featuring a web portal. The engineer recertification assistant can further determine an automated score-based recommendation for certification or decertification of the mobile asset operator or can directly certify or decertify the mobile asset operator for gross non-compliance.

Various embodiments of methods and systems are provided for enhancing engine operation through data-sharing among vehicles. In one embodiment, a method includes determining whether a first value of a first operating parameter produced by a first vehicle is corrupted or unavailable; receiving a second value of the first operating parameter produced by a second vehicle that is proximate to the first vehicle; adjusting the second value by a first adjustment factor, the first adjustment factor based on a first value of a global positioning system (GPS) position of the first vehicle produced by the first vehicle and a second value of a GPS position of the second vehicle produced by the second vehicle; and in response to determining that the first value is corrupted or unavailable, controlling operation of an engine of the first vehicle based on the adjusted second value of the first operating parameter.

A locomotive is disclosed. The locomotive includes a car body, including an operator cabin, a power source, and an operator health monitor within the operator cabin, the operator health monitor configured to monitor at least one health condition associated with the operator and configured to generate an operator health signal associated with the at least one condition. The locomotive includes an operator warning system within the operator cabin, configured to present the operator with an operator warning in response to an operator warning signal, and an electronic controller. The electronic controller may be configured to determine an operator fatigue score based on, at least, the operator health signal, determine if the operator fatigue score exceeds a warning threshold, and transmit the operator warning signal to the operator warning system if the operator fatigue score exceeds the warning threshold.

A system that can automatically measure, track, and/or report train emissions for complying with geographic environmental restrictions. An emissions module determines the amount of emissions emitted by a train over time. A location module tracks the location of the locomotive of the train relative geographic locations having emission regulations. A compliance module records the amount of emissions emitted by the train in the geographic location.

A method analyzes conditions of technical components in view of a rarity and/or an abnormality of a condition. To provide a reliable analysis and thus a safely operating system the method includes: a) describing conditions of the technical components in a behavioral input space that is spanned by state variables, which are characteristic for the technical components, b) analyzing a condition of one technical component in respect to other conditions of this technical component in the behavioral input space, whereby a rarity of this condition of the technical component is detectable, and c) analyzing the condition of the technical component also in respect to analyses of conditions of further technical components in the behavioral input space. Whereby an abnormality of the condition of the technical component is detectable.

A monitoring and surveillance system arranged for processing video data associated with a vehicle, wherein said system is arranged to operate in at least two operating modi, a first modus of said two modi being associated with a first latency requirement for said video data and a second modus of said two modi being associated with a second latency requirement, said system comprising a camera unit, arranged to be installed in said vehicle, wherein said camera unit is arranged for capturing video data; a streaming unit, arranged to be installed in said vehicle, and arranged for receiving said video data and for transmitting said video data over a telecommunication network to a video processing server; said video processing server arranged for selecting a modus of said at least two operating modi, and for communicating said selected modus, over said telecommunication network, to said camera unit such that said streaming unit can be tuned to said selected modus. Complementary systems and methods are also presented herein.

Intermodal vehicles may be loaded with items and an aerial vehicle, and directed to travel to areas where demand for the items is known or anticipated. The intermodal vehicles may be coupled to locomotives, container ships, road tractors or other vehicles, and equipped with systems for loading one or more items onto the aerial vehicle, and for launching or retrieving the aerial vehicle while the intermodal vehicles are in motion. The areas where the demand is known or anticipated may be identified on any basis, including but not limited to past histories of purchases or deliveries to such areas, or events that are scheduled to occur in such areas. Additionally, intermodal vehicles may be loaded with replacement parts and/or inspection equipment, and configured to conduct repairs, servicing operations or inspections on aerial vehicles within the intermodal vehicles, while the intermodal vehicles are in motion.

The driving assistance device (10) for a railway vehicle comprises means (12) for determining a target speed (V.sub.c), means (20) for comparing an instantaneous speed (V.sub.i) of the railway vehicle with the target speed (V.sub.c) or an interval surrounding the target speed, and means (22) for indicating driving instructions intended for a driver of the railway vehicle, said driving instructions including instructions for modifying the instantaneous speed (V.sub.i) with view to bringing it closer to the target speed (V.sub.c).

A device for supplying energy to a sensor arrangement in a rail vehicle. The device has at least one second electrical conductor which has an inductive coupling to a first electrical conductor. The first electrical conductor connects a converter to a motor of the rail vehicle. The device has a switching module which is operated by way of an operating voltage and has the purpose of processing signals of at least one sensor. The at least one sensor serves to acquire data and/or detect a state of a vehicle component. The switching module is connected to a second electrical conductor. The second electrical conductor is configured to generate the operating voltage from an alternating voltage, applied to the first conductor, by way of induction in the second electrical conductor.