A side wind assistant for a vehicle and a method for the operation of the side wind assistant involve detecting a side wind disturbance acting on the vehicle and reacting to the side wind disturbance by carrying out a side wind compensation intervention to at least partially compensate for the influence of the side wind disturbance, at least when an intervention threshold has been exceeded. The side wind assistant thus reacts to the side wind disturbance in a frequency selective manner in which the frequency selectivity is controlled depending on the side wind compensation or a state of the side wind assistant correlating with the side wind compensation intervention. In particular, the frequency selectivity is controlled depending on whether the side wind compensation intervention is carried out or not carried out, and depending on the duration of the side wind compensation intervention.

A canister that acts as a pressure vessel that contains a payload and that can withstand pressures that may be generated by the payload internal to the canister in order to contain the payload contents. The canister can be launched from a submarine, with the canister being located internal to the pressure hull of the submarine prior to launch and the canister being launchable from the submarine into the surrounding water. After launching, the canister is designed to release or deploy the payload permitting the payload to perform its intended function(s). The payload contained in the canister can be an unmanned underwater vehicle such as an acoustic training target that is powered by one or more lithium batteries.

A canister that acts as a pressure vessel that contains a payload and that can withstand pressures that may be generated by the payload internal to the canister in order to contain the payload contents. The canister can be launched from a submarine, with the canister being located internal to the pressure hull of the submarine prior to launch and the canister being launchable from the submarine into the surrounding water. After launching, the canister is designed to release or deploy the payload permitting the payload to perform its intended function(s). The payload contained in the canister can be an unmanned underwater vehicle such as an acoustic training target that is powered by one or more lithium batteries.

A method of controlling a backing system for a vehicle and trailer assembly comprises initiating a path input mode on an electronic input device associated with an electronic control unit in the vehicle. An intended backing path is input into the electronic control unit by defining the intended backing path with an input control mechanism for the electronic input device. The path input mode on the electronic input device is ended.

Techniques are disclosed for systems and methods to provide stabilized directional control for a vehicle. A directional control system for an embodiment may include a logic device adapted to receive directional data about a vehicle and determine nominal vehicle feedback from the directional data. The nominal vehicle feedback may be used to adjust a directional control signal provided to an actuator of a vehicle. The directional control signal may be limited to a value below an actuator rate limit before a directional control signal is adjusted by the nominal vehicle feedback. A directional control system may include a logic device, a memory, one or more sensors, one or more actuators/controllers, and modules to interface with users, sensors, actuators, and/or other modules of a vehicle.

In a driving assistance device 1, when an execution determination unit 12 determines that a driving assistance unit 11 performs driving assistance, a consciousness degradation determination unit 13 performs control such that a warning unit 9 is less likely to issue a warning than that when the driving assistance is not performed. Therefore, even when the position of a host vehicle is changed by the steering of the host vehicle by a driving assistance unit 11, it is possible to reduce the discomfort of a driver due to a warning.

A submersible vessel comprising: an elongated hull; at least one propeller mounted on a forward end of said hull and adapted to move said hull through water; said at least one propeller being of a size and configuration such that when it is rotated at an appropriate speed, it generates supercavitated water flowing from said at least one propeller and thence along an outer surface of said hull so as to diminish friction on the outer surface of said hull and facilitate high underwater speeds.

A submersible vessel comprising: an elongated hull; at least one propeller mounted on a forward end of said hull and adapted to move said hull through water; said at least one propeller being of a size and configuration such that when it is rotated at an appropriate speed, it generates supercavitated water flowing from said at least one propeller and thence along an outer surface of said hull so as to diminish friction on the outer surface of said hull and facilitate high underwater speeds.

An electric power steering controller adjustably generates a target steer torque dynamically by weighting (i) a load based target steer torque that is determined based on an estimated load and (ii) a steer angle based target steer torque with a weighting ratio. The weighting ratio varies depending on a condition of a road surface on which a subject vehicle is traveling, a steering state of the driver and the like, which enables an adjustment of the target steer torque to suitably accommodate the condition of the road surface and to provide a road surface conscious steering feel while achieving robustness over an influence of a friction of the mechanical components in a steering system.

A control device in an electric power steering device calculates a first assist component based on steering torque and a vehicle speed. The control device also calculates a compensation component associated with an reverse input and calculates a steered angle command value based on an addition value of the compensation component and basic drive torque that is an addition value of the steering torque and the first assist component, produces a second assist component by performing steered angle feedback control that causes the steered angle of a vehicle to follow the steered angle command value. The control device controls drive of a motor based on an assist command value that is an addition value of the first assist component and the second assist component.