Provided is a drift car for children, including a car body, a driving system and a control system, the driving system includes a front wheel set, a rear wheel set and a motor set on the car body, the front wheel set includes a left front wheel and a right front wheel, and the rear wheel set includes a left rear wheel and a right rear wheel, the control system includes an on-board controller arranged in the car body, and the motor set includes a left motor and a right motor, in which the left motor is connected to the left front wheel or the left rear wheel, the right motor is connected to the right front wheel or the right rear wheel, and the left and right motors are both connected to the on-board controller; the controller system also includes a drift trigger switch connecting to the on-board controller.

A remote wireless hydraulic cab preferably includes a cab member, a hydraulic sensor block, an electrical bulkhead, a cab bridge controller and a cab transceiver. The cab member preferably includes a cab enclosure, two hydraulic joysticks, two hydraulic treadles and electrical equipment. The hydraulic sensor block includes a sensor block and a plurality of hydraulic pressure sensors. Hydraulic lines from the joysticks and treadles are connected to the sensor block. Pressure measurements from the joysticks and treadles are sent from the plurality of hydraulic pressure sensors to the cab bridge controller. The cab bridge controller sends signals for wireless transmission through a cab wireless transceiver to a frame transceiver. The electrical equipment is supplied with electrical power and transmits signals through the electrical bulkhead. Electrical power to the cab enclosure is supplied through an electrical generator and hydraulic fluid to the joysticks and treadles are supplied through a hydraulic pump.

A method for specifying a cleaning area to a cleaning robot without an in-built map provides a hand-held mobile device capturing a two-dimensional code label arranged on a top of a cleaning robot parked on a charging base, and obtaining a positional relationship between the mobile device and the cleaning robot through the captured image. The cleaning robot is controlled to enter a cleaning mode under the guidance of the mobile device. With captured images, a user can specify an area within the environment for cleaning, and through a touch display screen can control the cleaning robot to go to the specified cleaning area for cleaning. The mobile device and the cleaning robot employing the method are also disclosed.

Systems, assemblies, and methods for conveniently operating marine devices associated with a watercraft are provided herein. An example system includes a controller, a sensor module, and a marine device. The controller is configured to receive a user input indicating a desired action via the sensor module and transmit a signal to the marine device to cause the marine device to operate in a particular manner. The sensor module may include one or more motion sensors, and the controller may be configured to filter unintentional movement from the raw motion data sensed by the sensor module, such as due to movement of the watercraft floating on the surface of the water. Thus, the system may enable convenient and intuitive control over various marine devices associated with the watercraft.

Said control system comprises: a remote device comprising: a remote module for acquiring flight plan data, and a remote module for calculating a remote trajectory or a remote setpoint according to the flight plan data; an on-board device comprising: an on-board module for acquiring flight plan data, an on-board module for calculating an on-board trajectory or an on-board setpoint according to the data acquired by the on-board acquisition module.

The remote device comprises a module for validating the trajectory which is configured to: acquire the on-board and remote trajectory or setpoint; validate or reject the on-board trajectory or setpoint according to the remote trajectory or setpoint; transmit the result of the validation to the on-board device.

Provided is a taxiing system for steering an amphibious aircraft on a body of water with a steering means, a control console and a power source all in operable and electrical communication. The steering means is a jet drive coupled to an impeller assembly mounted inside each float. Alternatively the steering means is a propulsion system with a pair of tunnel-type thrusters mounted inside the floats in the aircraft. The control console operates the taxiing system during steering and at least one electromagnetic lock during docking.

An agricultural machine includes a vehicle body, a travel switch operable to issue a command to start autonomous travel of the vehicle body, and an autonomous travel controller to perform autonomous travel of the vehicle body based on a planned travel line when the command is issued. When the command is issued by operating the travel switch, if at least one of a positional deviation between the planned travel line that is selected and the vehicle body and an orientational deviation between the planned travel line and an orientation of the vehicle body is greater than or equal to a corresponding one of respective first thresholds, the autonomous travel controller is configured or programmed to perform line alignment to make the positional deviation and the orientational deviation less than the respective first thresholds.

A control method and device of a movable platform, a movable platform, and a storage medium are provided. The control method may include acquiring a control amount for controlling the movable platform; converting the control amount into control instruction of the movable platform based upon a position of the movable platform and a position of a target object photographed by the movable platform; and controlling the movable platform to move relative to the target object according to the control instruction.

Systems and methods for editing routes for robotic devices are disclosed herein. According to at least one non-limiting exemplary embodiment, Bezier curves and controls are provided to enable a user to intuitively manipulate a robot route, including changing the shape of the route, deleting segments of the route, and/or adding new route segments.

An unmanned autonomous vehicle is provided and includes at least one propulsion device, at least one image capture device, at least one adjusting member to adjust an tilt angle of the image capture device and is configured to receive, from a control device, a capturing instruction to capture at least one image, acquire angle information indicating a tilt angle of the image capture device, and control, in a case where the capturing instruction is received, the propulsion device so that the image capture device captures at least one image at an altitude which is determined based on the acquired angle information.