Disclosed is a device for reducing a user-sensed weight of a wireless vacuum cleaner including a suctioning pipe and a suction motor disposed on a top of the suctioning pipe, the device comprising: a case disposed adjacent to the suction motor and having a space defined therein, and a rotatable assembly received in the space, wherein the rotatable assembly receives therein a motor and a battery, wherein the rotatable assembly is configured to rotate clockwise or counter-clockwise when the motor is activated.

Disclosed is a device for reducing a user-sensed weight of a wireless vacuum cleaner including a suctioning pipe and a suction motor disposed on a top of the suctioning pipe, the device comprising: a case disposed adjacent to the suction motor and having a space defined therein, and a rotatable assembly received in the space, wherein the rotatable assembly receives therein a motor and a battery, wherein the rotatable assembly is configured to rotate clockwise or counter-clockwise when the motor is activated.

A method for operating a vehicle includes: ascertaining a danger measure of a possible stop position for a safe parking of the vehicle; comparing the ascertained danger measure to a predetermined danger measure threshold value; and guiding the vehicle to the possible stop position in order to safely park the vehicle in the possible stop position only if the ascertained danger measure is less than or equal to the predetermined danger measure threshold value.

Methods and systems are provided for estimating fuel volatility. During a vehicle-off condition following a refueling event, fuel volatility may be estimated by operating a fuel pump of a fuel system immediately after the refueling event while a fuel tank temperature is stable. Based on estimated fuel volatility, fuel injection amount and leak test thresholds may be adjusted.

A signaling system includes an on-board device provided for a moving vehicle traveling on a track, and a station interface device provided for a station, and a branch provided on the track. A second moving vehicle transmits different moving vehicle related data of itself to a first on-board device of a first moving vehicle. The first station interface device transmits station related data of the branch to the first on-board device. The first on-board device outputs a command which instructs to switch the branch, to the first station interface based on the different moving vehicle related data and the station related data, to secure the traveling route. The first station interface device switches the branch and secures the traveling route. The first on-board device determines the traveling of the first moving vehicle of the secured traveling route based on the different moving vehicle related data.

A control system for a suspension system of a multi-hulled vessel, the vessel including a chassis portion, at least two hulls moveable relative to the chassis portion. The suspension system of the vessel provides support of at least a portion of the chassis above the at least two hulls, and includes adjustable supports and at least one motor to enable adjustment of a support force and/or displacement of the adjustable supports. The control system includes a fender friction force input for receiving at least one signal indicative of a friction force on a fender portion between a fixed or floating object and the vessel chassis portion, and in response to the fender friction force input, the control system is to adjust the support force and/or displacement between the chassis portion and the at least two hulls to reduce or minimize the friction force on the fender portion.

A communication device includes a first terminal unit connected to an actuator device having a sensor. Transmission of a steering signal transmitted from a steering wireless device to the actuator device, and transmission of detected signal detected by the sensor in the actuator device are conducted via the first terminal unit. The communication device further includes a control unit. The control unit conducts processing to generate a connection error signal representing that the actuator device are not connected on the basis of a result of determination whether the detected signal is acquired from the actuator device via the first terminal unit, and transmit the connection error signal to the steering wireless device side.

Aspects of the disclosure relate to deploying safety mechanisms in an autonomous vehicle. As an example, the situational information identifying a potential impact target corresponding to an object with which the autonomous vehicle is predicted to have a collision within a predetermined period of time may be received. This situational information may also include an estimated time when the second computing device will receive an update for the potential impact target from the first computing device. The estimated time may be used to determine when to deploy a set of active safety mechanisms for the potential impact target. Each active safety mechanism may be configured to reduce a likelihood of damage to an object external to the autonomous vehicle caused by a collision. A signal is then sent to activate the set of active safety mechanisms prior to an impact with the object corresponding to the identified potential impact target.

The present disclosure relates to technology that controls a remote moving body based on collaboration between the moving body and human, and a method for controlling a moving body includes acquiring a first biosignal indicating an intention to start operation of the moving body from a user, operating the moving body, determining a surrounding situation of the moving body that autonomously controls the driving, providing the user with surrounding information of the moving body for inducing path setting, acquiring a second biosignal evoked by recognition of the surrounding information from the user, setting a driving direction of the moving body, commanding the moving body to automatically perform a driving operation to be carried out in the set driving direction, and acquiring a third biosignal responsive to recognition of a driving error from the user and correcting the driving direction of the moving body to induce driving path resetting.

In embodiments of electronic compensated pivot control, a computing device includes a device housing that is integrated with a display device, and the device housing tilts for multiple display positions. Pivotable components pivot in coordination to position the display device in a display position, and sensors detect positioning inputs that are received to re-position the display device. Actuators are implemented for electronic actuation to drive the pivotable components to position the display device, and clutches are implemented to limit movement of the pivotable components. A pivot controller is implemented to receive input data corresponding to a user input to change a position of the display device, control the actuators based on the input data to assist with positioning the display device, receive an indication that the user input has stopped, and control the one or more clutches to hold the position of the display device.