Examples relate to digital context aware (DCA) data collection. In some examples, a DCA start location component is positioned at a first location along a travel route, and a DCA end location component is positioned at a second location along the travel route. In response to using a wireless interface to detect the DCA start location component, data collection of measurements by a sensor are initiated. In response to using the wireless interface to detect the DCA end location component, the data collection by the sensor is halted.

The invention relates to a portable device for measuring lateral rail measurements under service to record and report excessive rail movement and angle differential to prevent a train from derailing. The device may be spring-loaded and light-weight. The device may include a microprocessor, sensors, and a display. The device may be installed on the rail. The device may sense an approaching train, automatically turn on the device, detect the train speed, and measure the angle differential, the real-time displacement, and the maximum/minimum displacement between the two rails while the train is operating over the rail at all speeds. The device measures and records the separation and angle differential of the rail to ensure the rail does not exceed separation that could derail the train.

A system and method for inspecting a railway track using sensors oriented at an oblique angle relative to a rail vehicle on which the system is traveling. The use of an air blower, ducts, and one or more air distribution lids over the sensors helps remove debris from blocking the sensors and structured light generators.

A system and method for inspecting a railway track using sensors oriented at an oblique angle relative to a rail vehicle on which the system is traveling. The orientation of the sensors allows for different data to be gathered regarding a particular rail including rail design specifications (gathered based on manufacturer markings detected and analyzed by the system), rail seat abrasion values based on direct measurement of rails from the oblique angle, and other analysis of rail features including joint bars, rail welds, bond wires, rail holes, and broken rails. The use of an air blower, ducts, and one or more air distribution lids over the sensors helps remove debris from blocking the sensors and structured light generators.

A rail vehicle has a vehicle frame which, supported on on-track undercarriages, is mobile on the rails of a track. The rail vehicle includes a first measuring platform with a first inertial measuring system for recording a track course. A second measuring platform is arranged on the rail vehicle, with a second inertial measuring system and at least one sensor device for recording surface points of a track section. The second measuring platform and the second inertial measuring system enable the movement of the sensor device in the three-dimensional space to be recorded in a simple manner.

A rail-guided permanent way machine is operated by means of a control device in such a way that at least one state variable (Z) of the permanent way machine is determined in dependence on an operating state, and the at least one state variable is compared to at least one pre-defined limit value (G.sub.W, G.sub.S) for monitoring a derailment safety of the permanent way machine. Thus, the derailment safety of the permanent way machine is determined in accordance with the current operating state and monitored. As a result, the permanent way machine has an expanded operating range and increased performance and thus increased efficiency.

The invention describes an electronic processing apparatus (10) for determining railroad information, comprising a sensor adapted to provide a sensor signal representing a railroad property or a railroad event, a gateway adapted to communicate with the sensor and with a remote processing unit, and a mounting base (12) adapted to be fixedly mounted to a crosstie (14) of the railroad, wherein the mounting base (12) carries at least one electronic device (8) of the electronic processing apparatus (10).

This application relates to methods and apparatus for distributed fibre optic sensing and especially to the processing of signals derived from such sensing techniques to characterise events of interest. The application describes a method of distributed fibre optic sensing, comprising; performing distributed fibre optic sensing so as to generate at least one set of measurement signals from each of a plurality of sensing channels of an optical fibre (101) in response to at least one event of interest. For each set of measurement signals, processing the measurement signals from different sensing channels according to an association metric to determine whether any sensing channels are associated with one another and form at least one association matrix indicative of the sensing channels that are associated with one another. The method further comprising performing distributed fibre optic sensing to acquire a further set of measurement signals from said sensing channels in response to a further event of interest and processing said further set of measurement signals based on said at least one association matrix to characterise said further event of interest.

A method, an apparatus, a system, and a computer program product for managing safety for a railway system. A computer system generates a probability of a safety issue for a particular section of a railroad track in the railway system using information from a set of weather event sources. A set of unmanned aerial vehicles is dispatched to the particular section of the railroad track when the probability of the safety issue exceeds a threshold. A number of images of the particular section of the railroad track is received from the set of unmanned aerial vehicles. A risk score for the safety issue at the particular section of the railroad track is generated using the number of images by the computer system. An action is performed to resolve the safety issue using the risk score, enabling the computer system to manage safety issues for the railway system.

This application relates to an overload and unbalanced load detecting system for a railway and a detecting method. This system includes at least one steel rail. A rail web of each steel rail is provided with two sampling points at two sides between every two adjacent rail sleepers, respectively, and the two sampling points on one side are symmetrically disposed about the steel rail with respect to the two sampling points on the other side. A fiber-optic sensitive element used for continuously measuring a load when a train passes through the two sampling points is obliquely fixed at each sampling point, and two fiber-optic sensitive elements on the same side of each steel rail are disposed at an angle of 90 with each other.