A mechanism to determine whether conditions are correct for coupling one train consist to another train consist is disclosed. Controllers on locomotives are configured to determine the forces and/or compression state between locomotives and/or cars of a consist based at least in part on an intra-train force model and measured sensor data. The controllers also determine the relative speed of the consists that are to be joined. Based at least in part on the compressive state of at least one of the consists and the relative speed of the consists, the controller determines whether the conditions are suitable to couple the two consists. In some cases, terrain data, such as upcoming slope of tracks data may also be used in determining whether conditions are suitable for coupling consists. In further cases, the operation of at least one consist may be modified to achieve suitable conditions for coupling the two consists.

An timetable plan creation system 100 includes: a storage device 101 that stores information regarding a constraint that is generated in each of timetable variables of an timetable plan and regarding the intensity of the constraint, information that associates a creation algorithm of the timetable plan and a measure of an evaluation index improved by a timetable variables of the timetable plan and by the creation algorithm, and information on desired change of the intensity of the constraint; and a computing device 104 that generates a constraint that has an intensity and that is generated for each of the timetable variables of the timetable plan, and that selects a plan creation algorithm for improving the quality of the timetable plan, and that creates a new timetable plan by executing each of selected plan creation algorithms to which the generated constraint is applied.

Systems and methods for remotely operating a vehicle system are provided. A system is provided herein that includes a radio frequency (RF) circuit configured to establish a plurality of bi-directional communication links with a plurality of remote vehicle systems, and a controller circuit communicatively coupled to the RF circuit. The controller circuit is configured to obtain operational data from the plurality of remote vehicle systems, determine operation statuses of the remote vehicle systems based on the operational data relative to one or more predetermined thresholds, display on a display the operation statuses of the plurality of remote vehicle systems, and transmit a control signal along a first bi-directional communication link of the plurality of bi-directional communication links to the first remote vehicle system.

A long distance transit system for transferring passengers at a high rate of speed, the transit system comprises at least one mainline train, at least one station train, a rail system having at least one station with at least one mainline track and at least one station line. At least one mainline train travels exclusively on the at least one mainline track and the at least one station train travels on at least one station line. At least one mainline train travels at a consistent speed on at least one mainline track. At least one station train travels from at least one station to at least one mainline track reaching a speed substantially equal to that of the at least one mainline train and traveling adjacent thereto.

An exemplary method includes electronically determining that movement of a rolling stock should be prevented based on a failure condition of the rolling stock. And if it is electronically determined that movement of the rolling stock should be prevented based on the failure condition of the rolling stock, the method further includes preventing movement of the rolling stock including preventing the rolling stock from initiating a movement from a stationary position along a track within a work area defined around the rolling stock by: preventing brakes of the rolling stock from being released via one or more pneumatic components; and/or preventing the rolling stock from receiving or accepting a movement command.

An exemplary method includes electronically determining that movement of a rolling stock should be prevented based on a failure condition of the rolling stock. And if it is electronically determined that movement of the rolling stock should be prevented based on the failure condition of the rolling stock, the method further includes preventing movement of the rolling stock including preventing the rolling stock from initiating a movement from a stationary position along a track within a work area defined around the rolling stock by: preventing brakes of the rolling stock from being released via one or more pneumatic components; and/or preventing the rolling stock from receiving or accepting a movement command.

A vehicle control system and method of operation includes directing a portable distribution vehicle to a first loading location. The portable distribution vehicle may be loaded with first cargo at the first loading location. Instructions may be communicated to the portable distribution vehicle to move from the first loading location to a first distribution location, where the first cargo may be unloaded. The portable distribution vehicle may be a first type of portable distribution vehicle that is allowed to move along a designated route. Vehicles of a second type are prohibited from moving along the designated route. Operation of the portable distribution vehicle may be automatically controlled to move from the first loading location to the first distribution location without an operator onboard the portable distribution vehicle manually controlling the portable distribution vehicle.

A vehicle control system and method of operation includes directing a portable distribution vehicle to a first loading location. The portable distribution vehicle may be loaded with first cargo at the first loading location. Instructions may be communicated to the portable distribution vehicle to move from the first loading location to a first distribution location, where the first cargo may be unloaded. The portable distribution vehicle may be a first type of portable distribution vehicle that is allowed to move along a designated route. Vehicles of a second type are prohibited from moving along the designated route. Operation of the portable distribution vehicle may be automatically controlled to move from the first loading location to the first distribution location without an operator onboard the portable distribution vehicle manually controlling the portable distribution vehicle.

An abnormal situation alarming system includes a detection unit that detects an abnormal situation, an acquisition unit that acquires, when the abnormal situation is detected, information representing the circumstances of the location where the abnormal situation occurred, a calculation unit that calculates the time allowable for handling the abnormal situation from a detection result of the abnormal situation and an acquisition result of the information, and an alarming unit that gives an alarm of the detection result of the abnormal situation and a calculation result of the time.

An abnormal situation alarming system includes a detection unit that detects an abnormal situation, an acquisition unit that acquires, when the abnormal situation is detected, information representing the circumstances of the location where the abnormal situation occurred, a calculation unit that calculates the time allowable for handling the abnormal situation from a detection result of the abnormal situation and an acquisition result of the information, and an alarming unit that gives an alarm of the detection result of the abnormal situation and a calculation result of the time.