Abstract: A method is provided including determining a first power level required from a diesel powered system. The first power level corresponds to a first proportion of a maximum power. The method also includes determining an emission output for a mission based on the first power level. The method further includes determining a second power level corresponding to a second proportion of the maximum power, wherein alternate use of the second power level and at least one of the first power level or a third power level results in a lower emission output for the mission, with the overall resulting power being proximate the minimum power required. The method also includes automatically controlling operation of the diesel powered system by using the second power level alternately with at least one of the first power level or the third power level.

Abstract: A method for operating a train includes: (a) using a processor carried by the train, creating a trip profile which is computed at so as to substantially optimize an operating parameter of the train which depends on multiple operating variables; (b) operating the train along a route at speeds determined by the trip profile; (c) identifying a target location ahead of the train which cannot be cleared in a desired time if the train operates in accordance with the trip profile; and (d) operating the train at a clearing speed substantially faster than determined by the trip profile until the target location is cleared. A computer program product is provided for carrying out the method.

Abstract: A method for operating a train includes: (a) using a processor carried by the train, creating a trip profile which is computed at so as to substantially optimize an operating parameter of the train which depends on multiple operating variables; (b) operating the train along a route at speeds determined by the trip profile; (c) identifying a target location ahead of the train which cannot be cleared in a desired time if the train operates in accordance with the trip profile; and (d) operating the train at a clearing speed substantially faster than determined by the trip profile until the target location is cleared. A computer program product is provided for carrying out the method.

Abstract: A system is provided for monitoring the effectiveness of a braking function in a powered system. The system includes a sensor configured to measure a parameter related to the operation of the powered system. Additionally, the system includes a processor coupled to the sensor, to receive data related to the parameter. Subsequent to activating the braking function, the processor is configured to determine the effectiveness of the braking function of the powered system, based upon whether the parameter data varies by a predetermined threshold. A method and a computer software code are also provided for monitoring the effectiveness of a braking function in a powered system.

Abstract: A method that relates to mobile platform positioning through landmark recognition. The method includes receiving a captured image of a landmark, wherein the captured image was captured from an onboard camera system located on the mobile platform. A comparison of the captured image to a plurality of stored images, that are images of landmarks at known locations is made. The method recognizes the captured image based on the comparison and then determines the location of the mobile platform, based on the recognition. The method may be employed with a locomotive. A system and computer program product for mobile device positioning is also disclosed.

Abstract: An imaging system for generating images taken from a rail vehicle, the system including a camera configured to generate video data associated with a rail vehicle, and a processor configured to control recording of video data according to at least one of a variable frame rate or a variable resolution based on operating conditions of the rail vehicle. A method and non-transitory computer readable medium with instructions are also included.

Abstract: A system is provided for pacing a powered system traveling along a route separated into a plurality of block regions. Each block region has a respective signal. The system includes a controller configured to receive a status of the signal in an adjacent block region to a current block region of the powered system. The controller is configured to determine a time duration between a change in the status of the signal in an adjacent block region. The controller is further configured to determine an expected status of the signal to be experienced by the powered system in the plurality of block regions, based upon the time duration and a route parameter of the plurality of block regions.

Abstract: An imaging system (5) for generating landmark correlated images taken from a railroad locomotive includes a camera (142) mounted on the locomotive (22) for imaging an environment in a vicinity of the locomotive and transmitting imaging data indicative of images acquired. The system also includes a location sensor (20) on-board the locomotive generating signals indicative of a geographic location of the locomotive constituting location data. The system also includes a railroad landmark database (68) comprising a plurality of railroad landmarks (76) associated with respective geographic locations constituting landmark tags. The system also includes a processor (e.g., 10) receiving the imaging data and location data and communicating with the railroad landmark database to correlate the landmark tags with the imaging data and the location data for generating landmark correlated image data. The system may also include a computer system (86) for accessing the landmark correlated image data by landmark location.

Abstract: A system is provided for pacing a powered system traveling along a route separated into a plurality of block regions. Each block region has a respective signal. The system includes a controller configured to receive a status of the signal in an adjacent block region to a current block region of the powered system. The controller is configured to determine a time duration between a change in the status of the signal in an adjacent block region. The controller is further configured to determine an expected status of the signal to be experienced by the powered system in the plurality of block regions, based upon the time duration and a route parameter of the plulality of block regions.

Abstract: A method for improving train performance, the method including determining a rail car parameter for at least one rail car to be included in a train, and creating a train trip plan based on the rail car parameter in accordance with one or more operational criteria for the train.

Abstract: A system for the communication of data used in the operation of a powered vehicle comprises a plurality of controllers onboard the powered vehicle for controlling operations of the vehicle. At least one of the controllers has a memory in which data is stored and the data is accessible and used by at least two of the controllers for controlling vehicle operations. A communication link is provided between the at least two controllers for sharing data stored in the memory of one of the controllers to control operations of the powered vehicle.

Abstract: A control system is provided for controlling a braking effort of a braking system in a powered system. The powered system travels along a route. The control system includes a controller coupled to the braking system, where the controller is configured to monitor the braking effort of the braking system at a braking region along the route. The controller is further configured to control the braking effort at the braking region, such that the braking effort approaches within a predetermined range of a braking effort threshold, but does not exceed the braking effort threshold. A method is also provided for controlling a braking effort of a braking system in a powered system.

Abstract: A system for controlling a railroad train over a segment of track. The system comprises a first element for determining a location of the train on the segment of track; a second element for providing track characterization information for the segment of track; the track characterization information related to physical conditions of the segment of track; and a processor for controlling applied tractive forces and braking forces of the train responsive to the location of the train and the track characterization information to reduce at least one of wheel wear and/or track wear during operation of the train over the segment of track.

Abstract: A system is provided for pacing a plurality of powered systems traveling along a route. The plurality of powered systems include a constraining powered system and at least one trailing powered system traveling behind the constraining powered system along the route. The system includes one or more controllers configured to control the constraining powered system to travel along the route according to respective predetermined operating parameters at respective incremental locations along the route. The system further includes one of said controllers being configured to control the trailing powered system to travel along the route according to the respective predetermined operating parameters of the constraining powered system at the respective incremental locations along the route. A method is also provided for pacing a plurality of powered systems traveling along the route.

Abstract: A system is provided for processing images of wayside equipment adjacent to a route. The system includes a video camera configured to collect visible spectral data of the wayside equipment. The video camera is positioned on an external surface of a powered system traveling along the route. Additionally, the system includes a controller coupled to the video camera, where the controller is configured to process the visible spectral data, and is further configured to transmit a signal based upon processing the visible spectral data. Additionally, a method and computer readable media are provided for processing images of wayside equipment adjacent to a route.

Abstract: A system is provided for pacing a powered system traveling along a route separated into a plurality of block regions. Each block region has a respective signal. The system includes a controller configured to receive a status of the signal in an adjacent block region to a current block region of the powered system. The controller is configured to determine a time duration between a change in the status of the signal in an adjacent block region. The controller is further configured to determine an expected status of the signal to be experienced by the powered system in the plurality of block regions, based upon the time duration and a route parameter of the plurality of block regions.

Abstract: A method for operating a train includes: (a) using a processor carried by the train, creating a trip profile which is computed at so as to substantially optimize an operating parameter of the train which depends on multiple operating variables; (b) operating the train along a route at speeds determined by the trip profile; (c) identifying a target location ahead of the train which cannot be cleared in a desired time if the train operates in accordance with the trip profile; and (d) operating the train at a clearing speed substantially faster than determined by the trip profile until the target location is cleared. A computer program product is provided for carrying out the method.

Abstract: A route defect detection system for a powered system, the route defect detection system including a control system connected to the powered system for application of tractive effort, and a processor to determine an unplanned change in the application of tractive effort and/or otherwise associated with the tractive effort of the powered system. Based on the unplanned change, the processor determines a type of defect encountered along a mission route. A method and computer software code stored on a computer readable media and executable with a processor are also disclosed for a powered system to detect a defect along a mission route.

Abstract: A method for controlling a powered system, the method including operating the powered system to perform a mission based on an optimized mission plan, identifying when the powered system is approaching a location in the mission where the powered system may change from a first route to a second route, obtaining information about whether the first route or the second route will be taken, and if the second route is taken, adjusting the mission plan to optimize reduced emissions output and/or reduced fuel consumption based on the route change.

Abstract: A method for operating a powered system, the method including determining whether a mission plan of the powered system is correct to satisfy at least one mission objective of the powered system, if not, updating information used to establish the mission plan, revising the mission plan based on the updated information to satisfy the at least one mission objective, and operating the powered system based on the revised mission plan. A system and a computer software code for operating a powered system are also disclosed.