Abstract: A communications method for a vehicle consist (10) comprising a lead vehicle (14) having a first (29A) and second (29B) antenna associated with a respective first (28A) and second (28B) transceiver and a remote vehicle (12A/12B/12C) having a third (29A) and fourth (29B) antenna associated with a respective third (28A) and fourth (28B) transceiver.

Abstract: A communications method for a vehicle consist (10) comprising a lead (14) and a remote (12A/12B/12C) powered vehicle, the lead (14) vehicle comprising first (29A) and second (29B) antennas each associated with a radio, and the remote vehicle (12A/12B/12C) comprising third (29A) and fourth (29B) antennas each associated with a radio. The method comprises transmitting an outbound message from the lead (14) vehicle, receiving the outbound message at the third antenna (29A) and supplying a signal to the associated radio for producing a first received signal, and receiving the outbound message at the fourth antenna (29B) and supplying a signal to the associated radio for producing a second received signal, determining a first and second signal quality metric for the respective first and second received signals, selecting the first or second received signal for processing by the remote vehicle (12A/12B/12C) in response to the first and second signal quality metrics.

Abstract: An optimization system is provided for a braking schedule of a powered system traveling along a route. The braking schedule is based on at least one predetermined characteristic of the powered system and is configured to be enacted in a braking region along the route. The optimization 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 parameter data. The processor compares the measured parameter with an expected parameter, which is based on the at least one predetermined characteristic of the powered system. The processor adjusts the at least one predetermined characteristic based on the comparison, and adjusts the braking schedule based on the adjustment to the at least one predetermined characteristic. A method is also provided for optimizing a braking schedule of a powered system traveling along a route.

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 railway communication system (10) includes a transmitter (12) receiving an input and producing a communication signal (18). The communication signal (18) includes at least two different portions (20,22) for separately encoding respective indications (38,40) of the input. The system also includes a receiver (14) coupled to a controlled device, the receiver (14) extracting at least one of the respective indications (38,40) from the communication signal (18). The receiver controls the device responsive to the at least one extracted indications (38,40).

Abstract: A railway communication system (10) includes a transmitter (12) receiving an input and producing a communication signal (18). The communication signal (18) includes at least two different portions (20,22) for separately encoding respective indications (38,40) of the input. The system also includes a receiver (14) coupled to a controlled device, the receiver (14) extracting at least one of the respective indications (38,40) from the communication signal (18). The receiver controls the device responsive to the at least one extracted indications (38,40).

Abstract: A communications method for a vehicle consist (10) comprising a lead vehicle (14) having a first (29A) and second (29B) antenna associated with a respective first (28A) and second (28B) transceiver and a remote vehicle (12A/12B/12C) having a third (29A) and fourth (29B) antenna associated with a respective third (28A) and fourth (28B) transceiver.

Abstract: A railway communication system (10) includes a transmitter (12) receiving an input and producing a communication signal (18). The communication signal (18) includes at least two different portions (20,22) for separately encoding respective indications (38,40) of the input. The system also includes a receiver (14) coupled to a controlled device, the receiver (14) extracting at least one of the respective indications (38,40) from the communication signal (18). The receiver controls the device responsive to the at least one extracted indications (38,40).

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 railway communication system (10) includes a transmitter (12) receiving an input and producing a communication signal (18). The communication signal (18) includes at least two different portions (20,22) for separately encoding respective indications (38,40) of the input. The system also includes a receiver (14) coupled to a controlled device, the receiver (14) extracting at least one of the respective indications (38,40) from the communication signal (18). The receiver controls the device responsive to the at least one extracted indications (38,40).

Abstract: A communications method for a vehicle consist (10) comprising a lead (14) and a remote (12A/12B/12C) powered vehicle, the lead (14) vehicle comprising first (29A) and second (29B) antennas each associated with a radio, and the remote vehicle (12A/12B/12C) comprising third (29A) and fourth (29B) antennas each associated with a radio. The method comprises transmitting an outbound message from the lead (14) vehicle, receiving the outbound message at the third antenna (29A) and supplying a signal to the associated radio for producing a first received signal, and receiving the outbound message at the fourth antenna (29B) and supplying a signal to the associated radio for producing a second received signal, determining a first and second signal quality metric for the respective first and second received signals, selecting the first or second received signal for processing by the remote vehicle (12A/12B/12C) in response to the first and second signal quality metrics.

Abstract: A distributed power train (10) communications system for sending and receiving signals between a lead locomotive (14) and remote locomotives (12A/12B/12C) in the train (10). A lead (14) initiated message is received by at least the remote locomotive (12A/12B) nearest to the lead unit (14). The receiving remote unit (12A/12B) retransmits the message for receiving by the next remote unit (12C) in the train. Thus the message leapfrogs down the train from the lead unit (14) to the remote units (12A/12B/12C). When the last remote unit (the nth remote unit) (12C) receives the message, the last remote (12C) transmits a status or other response message to the lead unit's message. The status message is received at the (n-1)th remote unit (12A/12B), which appends its status message and transmits the combined status messages toward the lead unit (14).

Abstract: A system includes a location determination unit for determining a geographic location of a mobile asset having an engine that produces one or more emissions during use; a memory for storing a plurality of predetermined characteristic profiles, the characteristic profiles including information regarding geographic location and at least one of engine emission levels, noise emission levels, fuel usage levels, power output, load manifest, or speed level; a processor in communication with the memory for accessing the characteristic profile for the determined location of the mobile asset and generating a control command responsive to a selected characteristic profile; and a control unit on board the mobile asset controlling an operation of the mobile asset responsive to the control command. Associated methods are provided.

Abstract: An optimization system is provided for a braking schedule of a powered system traveling along a route. The braking schedule is based on at least one predetermined characteristic of the powered system and is configured to be enacted in a braking region along the route. The optimization 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 parameter data. The processor compares the measured parameter with an expected parameter, which is based on the at least one predetermined characteristic of the powered system. The processor adjusts the at least one predetermined characteristic based on the comparison, and adjusts the braking schedule based on the adjustment to the at least one predetermined characteristic. A method is also provided for optimizing a braking schedule of a powered system traveling along a route.

Abstract: A remote control system and method for the remote control operation of a locomotive in the performance of a car-kicking sequence comprises a portable control unit operable from a location off-board of the locomotive. The portable control unit includes an operator interface allowing an operator to initiate, with a single step, a predetermined sequence of locomotive operations for automatically performing a car-kicking procedure and generating a signal responsive to the single step for transmission to the locomotive. The system also includes a memory for storing a set of instructions corresponding to the predetermined sequence. An onboard slave control unit, interfaced with an operating system on the locomotive, receives the signal and automatically controls movement of the locomotive according to the set of instructions.

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 measuring apparatus for measuring an object includes a base member including a portion having a medial cavity and an extendible member that slidably engages the medial cavity of the base member. The extendible member includes a medial member having a mid point indicator defined by an elongate medial passageway, and a point locator defined by a passageway formed through an end portion thereof. The extendible member also includes a pair of opposing flexible members connected to the medial member. Each one of the pair of opposing flexible members have point locators defined by passageways formed through end portions thereof. The measuring apparatus also includes an intersection member connected to the point locaters on the pair of opposing flexible members, and a plurality of sets of measurement marks carried by at least one of the base member and the extendible member relating to a predetermined measurement of the object to be measured.

Abstract: A system (10) for generating a rail yard switch list (e.g., 30) of switch positioning activities for efficient movement of a railyard operator (12). The system includes a first operator control unit (14) (OCU) having a locator (16) for determining a location of the OCU and an associated operator using the OCU during rail yard switching activities. The system also includes a first processor (28) for correlating the rail yard switching activities with a respective location of the OCU in the rail yard to establish a knowledge base of respective preferred locations in the rail yard, and a memory (e.g. 26) for storing the knowledge base of preferred locations in the railyard. The system further includes a second processor (27) for receiving a request (32) for a switch list, accessing the memory, and processing the request based on the knowledge base to generate a switch list.

Abstract: An operator control unit (OCU) (12) for a locomotive remote control system (10) for displaying information to an operator of the OCU for use in controlling operation of a locomotive (16) from a location off-board of the locomotive. The OCU includes a receiver (e.g., 22) receiving data indicative of a fault condition of a locomotive and a processor (24) processing the data to generate locomotive operational recommendation information responsive to the fault condition of locomotive. The OCU also includes an operator display (20) on the OCU showing information indicative of the locomotive operational recommendation information to allow an OCU operator to respond to the fault condition.

Abstract: A method and apparatus that will locate the center of a circle in a single operation by positioning two points of registration at the edge of the circle relative to a third point of registration previously set at the edge of the circle where these points are held in accurate spatial relationship to each other and a fourth point of registration that in turn, indicates the center of the circle. By allowing precise registration and novel operation, this invention provides a simpler, more accurate means to locate the center of a circle that precludes the need to make extraneous marks on the circle being measured.