Underwater robotic systems are disclosed. In some instances, a robotic system may include a body, a flexible fin, and a rotatable mass associated with the body such that angular acceleration of the rotatable mass causes a reaction torque that rotates the body to deform the flexible fin to create thrust in water.

A vehicle steering angle detecting apparatus and an electric power steering apparatus equipped therewith. The apparatus connects a motor, which assist-controls a steering system of a vehicle, to the steering shaft via a reduction mechanism, and includes a first angle sensor which detects the steering shaft angle of the steering shaft and the second angle sensor which detects the motor shaft angle of the motor, including: a function that updates a static characteristic map and a dynamic characteristic map by iteratively learning a static characteristic and a dynamic characteristic of the nonlinear elements including the reduction mechanism, and mutually estimates the steering shaft angle and the motor shaft angle by using the static characteristic map and the dynamic characteristic map.

An auxiliary steering system (100) and method for an electric vehicle and the electric vehicle are disclosed. The system includes a detection component (6A) including a first electric motor (4) and a detection controller (6) configured to determine whether a steering assist device (2) is normal, to continue to determine whether the steering assist device (2) is normal if yes, and to control a drive rack (5A) of the first electric motor (4) to drive wheels (17) of the electric vehicle to return and to output a steering failure signal, a steering wheel torque signal and a direction signal if no; an electric motor controller (8); a second electric motor (14); and a vehicle controller (7). The electric motor controller (8) is further configured to control the second electric motor (14) to increase a drive torque for an outer front wheel (17), to brake an inner rear wheel (17), and to stop driving an inner front wheel (17) and an outer rear wheel (17).

A vehicle travel control device includes: an EPS device turning a wheel of a vehicle; and a control device performing autonomous driving control that controls autonomous driving of the vehicle. The autonomous driving control includes: calculating a target steering angle of the wheel; and actuating the EPS device to turn the wheel such that a steering angle of the wheel becomes the target steering angle. Calculating the target steering angle includes: calculating an autonomous driving steering angle and a target state quantity required for automatic steering in the autonomous driving; calculating a counter steering angle required for vehicle stabilization control, based on the target state quantity without using a steering wheel angle; and calculating a sum of the autonomous driving steering angle and the counter steering angle as the target steering angle.

A vehicle can be configured to operate relative to oncoming objects. The vehicle can sense to external environment of the vehicle. An oncoming object approaching the vehicle from an opposite direction can be detected. It can be determined whether the oncoming object intends to execute a left turn across the path of the vehicle. Such a determination can be performed in various ways. Responsive to determining that the oncoming object intends to execute a left turn across the path of the vehicle, a driving maneuver to avoid a collision with the oncoming object can be determined. The vehicle can be caused to implement the determined driving maneuver.

The present invention discloses a roll-over floating mixed multi-habitat submersible based on built-in driving principle comprising an outer spherical shell, a propulsion unit, an inner spherical shell, a rolling power unit, a buoyancy adjusting unit and a steering unit; the inner spherical shell can be set in the outer spherical shell rotating in the first axis direction relative to outer spherical shell; the roller power unit can be set in the inner spherical shell, capable of rotating around the second axis to generate an eccentric moment to advance or retract the submersible; the buoyancy adjusting unit and steering unit are installed in the space between the outer spherical shell and the inner spherical shell, wherein the buoyancy adjusting unit is capable of causing the submersible to sink or float in the water body and the steering unit is capable of driving the inner spherical shell to rotate relative to the outer spherical shell; The first axis is perpendicular to the second axis. The present invention has the beneficial effect that it not only can float in water body and move at the bottom of the water body, but also be able to move on land to realize the ability of interdisciplinary activity, and also to make the laying and recycling simple.

A vehicle control device according to an embodiment includes: a steering controller configured to control steering of a vehicle; and a controller configured to, when the vehicle is located at a first position on a travel route, instruct the steering controller to control the vehicle at a steering angle corresponding to a second position that is an advanced position from the first position in a traveling direction on the travel route.

A lane change controller determines whether lane change is available or unavailable on the basis of a detection result of an obstacle by a radar and an obstacle recognizer in response to detection of a winker operation by an operation detection unit. A lane keep controller continues lane keep control if the operation detection unit detects the winker operation during the lane keep control and if the lane change controller determines that the lane change is unavailable.

Systems and methods use cameras to provide autonomous and/or driver-assist navigation features. In some implementations, techniques for predicting the location of first roadway lane constraints are provided. The system may receive multiple images of a roadway in a vicinity of a vehicle, recognize a first roadway lane constraint, and, when lane prediction conditions are determined to be satisfied, predict a location of a second roadway lane constraint. In some implementations, techniques for detecting and responding to construction zones are provided. The system may receive multiple images of a roadway in a vicinity of a vehicle, recognize indicators of a construction zone in the images, determine that the vehicle is proximate to a construction zone, and output a signal indicating that the vehicle is proximate to a construction zone.

A backup assist system for a vehicle reversing a trailer includes an input element, including a base and a rotary element rotatably coupled with the base. The system further includes a controller causing a rotation of the rotary element relative to the base to be constrained in a first rotational movement mode that is biased toward a center position. The controller further interprets a first instantaneous position of the rotary element as a trailer control commanding position and outputs a vehicle steering command based thereon.