A railroad crossing control system includes a grade crossing predictor system or grade crossing motion system with a combined crossing termination shunt, the combined crossing termination shunt including a housing, a first printed circuit board (PCB) comprising first circuitry and first rail terminals, a second printed circuit board (PCB) comprising second circuitry and second rail terminals, wherein the first PCB and the second PCB are positioned inside the housing, and wherein the first circuitry and the second circuitry are configured for a same frequency.

An emergency action system for use with a railcar or locomotive is described herein. The emergency action system may include a transmitter and a locomotive transceiver located within a cabin of the locomotive. The locomotive transceiver may receive a signal sent from the transmitter and may further send an emergency stop signal to a set of brakes on the locomotive to stop. The emergency stop signal may cause air to be released from the brake pipe, thereby applying the brakes and bringing the train to an immediate stop. The emergency action system enables crew members to stop a train or railcar without communication to the locomotive operator when a hazard is recognized.

An emergency action system for use with a railcar or locomotive is described herein. The emergency action system may include a transmitter and a locomotive transceiver located within a cabin of the locomotive. The locomotive transceiver may receive a signal sent from the transmitter and may further send an emergency stop signal to a set of brakes on the locomotive to stop. The emergency stop signal may cause air to be released from the brake pipe, thereby applying the brakes and bringing the train to an immediate stop. The emergency action system enables crew members to stop a train or railcar without communication to the locomotive operator when a hazard is recognized.

An object of the present invention is to provide an obstacle detection system and an obstacle detection method for a trajectory traveling vehicle, which are capable of detecting a front obstacle on a trajectory and around the trajectory with high accuracy. The system includes: a monitoring area setting processing unit that sets an obstacle monitoring area for detecting an obstacle; a front obstacle monitoring unit that monitors an obstacle in the obstacle monitoring area using a sensor that horizontally scans the front of the train; and an obstacle detection unit that detects an obstacle in the obstacle monitoring area based on a monitoring result by the front obstacle monitoring unit, in which the front obstacle monitoring unit complements a gap in a detection region of the sensor at a first position with a detection region of the sensor while the train moves from the first position to a second position.

A monitoring system for detecting a condition in a vehicle, including at least one imaging device having a field of view including at least a portion of an interior cabin of the vehicle occupied by an operator of the vehicle during operation, a data storage medium configured to store parameter data in a database, the parameter data including control parameter data for the interior cabin of the vehicle, and at least one processor in communication with the at least one imaging device and the data storage medium. The at least one processor is programmed or configured to receive operational image data from the at least one imaging device, generate operational parameter data from the operational image data, compare the operational parameter data to the control parameter data, and determine if at least one operator is absent from the interior cabin and/or if at least one unauthorized display device is present in the vehicle.

A monitoring system for detecting a condition in a vehicle, including at least one imaging device having a field of view including at least a portion of an interior cabin of the vehicle occupied by an operator of the vehicle during operation, a data storage medium configured to store parameter data in a database, the parameter data including control parameter data for the interior cabin of the vehicle, and at least one processor in communication with the at least one imaging device and the data storage medium. The at least one processor is programmed or configured to receive operational image data from the at least one imaging device, generate operational parameter data from the operational image data, compare the operational parameter data to the control parameter data, and determine if at least one operator is absent from the interior cabin and/or if at least one unauthorized display device is present in the vehicle.

As a front monitoring system of a vehicle with strict restrictions on device arrangement, in a case where one or a plurality of external sensors are installed, an exit wave emitted from the external sensors and reflected by a structural object inside the vehicle is prevented from reentering the external sensor, and erroneous detection of an object is suppressed. As a front monitoring system therefor, an external sensor that is mounted inside a vehicle, emits an exit wave toward a front of the vehicle, and acquires a reflected wave entering the external sensor as a detection signal, and a removing means that removes the exit wave emitted by the external sensor and incident on a structural object installed inside the vehicle in a specific direction, particularly at an incident angle larger than a predetermined angle are provided.

As a front monitoring system of a vehicle with strict restrictions on device arrangement, in a case where one or a plurality of external sensors are installed, an exit wave emitted from the external sensors and reflected by a structural object inside the vehicle is prevented from reentering the external sensor, and erroneous detection of an object is suppressed. As a front monitoring system therefor, an external sensor that is mounted inside a vehicle, emits an exit wave toward a front of the vehicle, and acquires a reflected wave entering the external sensor as a detection signal, and a removing means that removes the exit wave emitted by the external sensor and incident on a structural object installed inside the vehicle in a specific direction, particularly at an incident angle larger than a predetermined angle are provided.

A conveyance system that prevents conveyance carriages from mistakenly entering an area includes a rail extending across a plurality of areas, a FOUP conveyance vehicle that travels along the rail, a conveyance vehicle that has a width and a height at least one of which differs from that of the FOUP conveyance vehicle, an optical sensor that is provided to the FOUP conveyance vehicle, arranged at a position that does not overlap the conveyance vehicle in a traveling direction, and detects an obstacle in front, and a member to be detected that is arranged, in an entry section into a certain area where only the conveyance vehicle is allowed to enter, at a position where the conveyance vehicle is allowed to enter the certain area, the position being detectable by the optical sensor provided to the FOUP conveyance vehicle.

A conveyance system that prevents conveyance carriages from mistakenly entering an area includes a rail extending across a plurality of areas, a FOUP conveyance vehicle that travels along the rail, a conveyance vehicle that has a width and a height at least one of which differs from that of the FOUP conveyance vehicle, an optical sensor that is provided to the FOUP conveyance vehicle, arranged at a position that does not overlap the conveyance vehicle in a traveling direction, and detects an obstacle in front, and a member to be detected that is arranged, in an entry section into a certain area where only the conveyance vehicle is allowed to enter, at a position where the conveyance vehicle is allowed to enter the certain area, the position being detectable by the optical sensor provided to the FOUP conveyance vehicle.