Abstract: In a method of determining a length of a train, a first camera at the head of the train acquires a first image of a first object on or proximate a path of the train and a second camera at the end of the train acquires a second image of a second object on or proximate the path of the train. A controller determines a length of the train based on a first geographical location associated with the first object in the first image and a second geographical location associated with second object in the second image. The first and second geographical locations of the first and second objects can be determined from corresponding prerecorded images of the objects that are geotagged with the geographical locations of the objects.

Abstract: A system that includes a notification light configured to be coupled with a first vehicle and to emit light to notify an approaching, second vehicle of the location of the first vehicle. A controller is provided that includes one or more processors configured to determine one or more of a direction of movement of the first vehicle, a speed of the movement of the first vehicle, or a distance between the first vehicle and the approaching, second vehicle. The controller is configured to notify the approaching, second vehicle of the one or more of the direction of the movement of the first vehicle, the speed of the movement of the first vehicle, or the distance between the first vehicle and the second vehicle by directing the notification light to change a characteristic of the light emitted by the notification light.

Abstract: In a method of determining a radius or diameter of a train wheel, a camera mounted on a train acquires first and second images (pictures) of first and second objects spaced along a path being traveled by the train. Matches are then determined between the first and second objects appearing in the first and second acquired images and representations (pictures) of the first and second objects appearing in prerecorded images included in a track database that include corresponding first and second geographical locations. A distance L traveled by the train between the first and second geographical locations is determined and a sum C of electrical pulses generated by an encoder coupled to the train wheel during travel of the train the distance L is determined. Based on the distance L and the sum C, a diameter or radius of the wheel is determined.

Abstract: In a method of train deceleration, a train computer: (a) causes brakes of the train to be set according to a target deceleration curve, profile, or braking model estimated to decelerate the train from a present speed at a present location to a target speed at a target location; (b) during deceleration of the train according to the target deceleration curve, profile, or braking model of step (a), determines an actual deceleration curve of the train; (c) in response to determining from the actual deceleration curve that the train will overshoot the target speed at the target location, determines another target deceleration curve, profile, or braking model estimated to decelerate the train to the target speed at the target location; and (d) causes the brakes of the train to be set according to the other target deceleration curve, profile or braking model of step (c).

Abstract: A controller is provided that can receive or determine at least one first location associated with at least a first vehicle belonging to a vehicle group; receive or determine at least one second location associated with at least a second vehicle; and determine a route or lane from a plurality of possible routes or lanes on which the vehicle group is located based at least partly on the at least one first location and on the at least one second location.

Abstract: An airbrake retention system and method for controlling air flow within an airbrake system, including the steps of: receiving, with a computer system comprising one or more processors, train control data associated with stopping on a grade; determining, with a computing system comprising one or more processors, an air retention controller within a railcar brake system to control air pressure release based on the train control data; communicating, with a computing system comprising one or more processors, an air control signal, the air control signal comprising information associated with a retainer valve of the braking assembly; and controlling, with a computing system comprising one or more processors, the retainer valve to adjust from a first state to a second state based on the air control signal to control air flow between the reservoir and the air braking assembly.

Abstract: A system and method for determining a track location and/or a direction of travel of a train includes at least one computer programmed or configured to determine at least one of a track on which the train is located and a direction of travel of the train on the track based at least partly on at least one location associated with at least one locomotive or control car of the train and at least one other location associated with at least one other locomotive or control car of the train. The at least one computer can be programmed or configured to determine a track on which the train is located based at least partly on the at least one location associated with the at least one locomotive or control car of the train and at least one additional location associated with at least one additional locomotive or control car of at least one additional train.

Abstract: Disclosed is a computer-implemented method for determining dynamic braking data for use in a braking model of at least one train, the method including: (a) determining at least one initial safety factor; (b) determining at least one dynamic braking adjustment factor based at least partially on (i) the expected dynamic braking force, and (ii) specified retarding forces of the train; and (c) determining at least one new safety factor based at least partially on the at least one initial safety factor and the at least one dynamic braking adjustment factor. Also disclosed are braking systems including dynamic braking for a train having at least one locomotive.

Abstract: A system and method for determining a track location and/or a direction of travel of a train includes at least one computer programmed or configured to determine at least one of a track on which the train is located and a direction of travel of the train on the track based at least partly on at least one location associated with at least one locomotive or control car of the train and at least one other location associated with at least one other locomotive or control car of the train. The at least one computer can be programmed or configured to determine a track on which the train is located based at least partly on the at least one location associated with the at least one locomotive or control car of the train and at least one additional location associated with at least one additional locomotive or control car of at least one additional train.

Abstract: A control system for a train having at least one locomotive or control car and, optionally, at least one railroad car, operating in a track network, wherein an on-board computer determines or receives movement data and location data and generates stopping data representing an amount of force for stopping the train at a distance from a target and/or predictor data representing an estimated or predicted location or position of the train in the track network based on the movement data and the location data. A train control method is also provided.

Abstract: A control system for a train having at least one locomotive or control car and, optionally, at least one railroad car, operating in a track network, wherein an on-board computer determines or receives movement data and location data and generates stopping data representing an amount of force for stopping the train at a distance from a target and/or predictor data representing an estimated or predicted location or position of the train in the track network based on the movement data and the location data. A train control method is also provided.

Abstract: Disclosed is a computer-implemented method for determining dynamic braking data for use in a braking model of at least one train, the method including: (a) determining at least one initial safety factor; (b) determining at least one dynamic braking adjustment factor based at least partially on (i) the expected dynamic braking force, and (ii) specified retarding forces of the train; and (c) determining at least one new safety factor based at least partially on the at least one initial safety factor and the at least one dynamic braking adjustment factor. Also disclosed are braking systems including dynamic braking for a train having at least one locomotive.

Abstract: Disclosed is a computer-implemented method for determining dynamic braking data for use in a braking model of at least one train, the method including: (a) determining at least one initial safety factor; (b) determining at least one dynamic braking adjustment factor based at least partially on (i) the expected dynamic braking force, and (ii) specified retarding forces of the train; and (c) determining at least one new safety factor based at least partially on the at least one initial safety factor and the at least one dynamic braking adjustment factor. Also disclosed are braking systems including dynamic braking for a train having at least one locomotive.

Abstract: Disclosed are a computer-implemented method for determining safety factors or a safety factor formula for use in a braking model of at least one train, a computer-implemented method for determining a plurality of safety factors for use in a braking model of at least one train, and braking systems for use on trains.

Abstract: Disclosed is a computer-implemented method for determining dynamic braking data for use in a braking model of at least one train, the method including: (a) determining at least one initial safety factor; (b) determining at least one dynamic braking adjustment factor based at least partially on (i) the expected dynamic braking force, and (ii) specified retarding forces of the train; and (c) determining at least one new safety factor based at least partially on the at least one initial safety factor and the at least one dynamic braking adjustment factor. Also disclosed are braking systems including dynamic braking for a train having at least one locomotive.