The present invention relates to an automatic system suitable for reducing the speed of rotation of one or more suspended loads, preferably where said rotation is originated by the flow tube located downstream preferably of the blades of the helicopter whereto said loads are attached, or by any other cause, and whose mechanical operation is based on the use of at least one aerodynamic surface, which automatically positions so as to exert, through the actual interaction with this flow tube, an aerodynamic moment, with respect to the center of mass of these suspended loads, appropriately contrary to said speed of rotation, so as to determine the slowing and therefore the progressive stabilization thereof. The automation of this deceleration is obtained through the use of a cycle of automatic control which is based primarily on the interaction, obtained with a processor, between an element responsive to said speed of rotation and an actuator capable of rotating said aerodynamic surface. Said system may be particularly useful in helicopter rescue operations, especially during the phase of ascent of the suspended load, mainly consisting of a rescuer, stretcher and injured person lying on the same.

The present invention relates to an automatic system suitable for reducing the speed of rotation of one or more suspended loads, preferably where said rotation is originated by the flow tube located downstream preferably of the blades of the helicopter whereto said loads are attached, or by any other cause, and whose mechanical operation is based on the use of at least one aerodynamic surface, which automatically positions so as to exert, through the actual interaction with this flow tube, an aerodynamic moment, with respect to the center of mass of these suspended loads, appropriately contrary to said speed of rotation, so as to determine the slowing and therefore the progressive stabilization thereof. The automation of this deceleration is obtained through the use of a cycle of automatic control which is based primarily on the interaction, obtained with a processor, between an element responsive to said speed of rotation and an actuator capable of rotating said aerodynamic surface. Said system may be particularly useful in helicopter rescue operations, especially during the phase of ascent of the suspended load, mainly consisting of a rescuer, stretcher and injured person lying on the same.

A method for optimizing a flight speed of a remotely-sensed scan imaging platform. The method comprises: selecting a reference point; obtaining a remotely-sensed scan image in a reference point region, and processing data; and optimizing a flight speed of a remotely-sensed scan platform. By optimizing a movement speed of a remotely-sensed movement platform, the method can prevent a geometric dimension of a target in a remotely-sensed scan image from being distorted, so as to obtain a high-precision remotely-sensed image of a ground target; and the method can be used for airborne and satellite borne remotely-sensed images.

A method for optimizing a flight speed of a remotely-sensed scan imaging platform. The method comprises: selecting a reference point; obtaining a remotely-sensed scan image in a reference point region, and processing data; and optimizing a flight speed of a remotely-sensed scan platform. By optimizing a movement speed of a remotely-sensed movement platform, the method can prevent a geometric dimension of a target in a remotely-sensed scan image from being distorted, so as to obtain a high-precision remotely-sensed image of a ground target; and the method can be used for airborne and satellite borne remotely-sensed images.

Systems and methods according to one or more embodiments are provided for rate and position control modes used in the operations of a telescoping refueling boom system. In one example, a system includes a telescoping tube and an actuator coupled to the telescoping tube and configured to extend and/or retract the telescoping tube. A processor is coupled to the actuator and configured to select a telescoping tube rate control mode and/or a telescoping tube position control mode based on a telescoping tube current position error, a telescoping tube current rate of movement, and a value of a telescoping tube rate command.

The disclosure relates to a method for operating a portable input device to control a motor vehicle. The input device has a pressure-sensitive touchscreen. The input device generates control signals to control the motor vehicle, and transmit said signals to the motor vehicle. The control signal has at least one determinable parameter. The input device is designed to capture a pressure value of an actuating force of the touchscreen, and determine the parameter according to the captured pressure value.

The disclosure relates to a method for operating a portable input device to control a motor vehicle. The input device has a pressure-sensitive touchscreen. The input device generates control signals to control the motor vehicle, and transmit said signals to the motor vehicle. The control signal has at least one determinable parameter. The input device is designed to capture a pressure value of an actuating force of the touchscreen, and determine the parameter according to the captured pressure value.

Systems and methods according to one or more embodiments are provided for rate and position control modes used in the operations of a telescoping refueling boom system. In one example, a system includes a telescoping tube and an actuator coupled to the telescoping tube and configured to extend and/or retract the telescoping tube. A processor is coupled to the actuator and configured to select a telescoping tube rate control mode and/or a telescoping tube position control mode based on a telescoping tube current position error, a telescoping tube current rate of movement, and a value of a telescoping tube rate command.

An electronic device includes a driving part including a first driving wheel and a second driving wheel; a memory storing at least one instruction; and at least one processor operatively coupled with the driving part and the memory, wherein the at least one processor is configured to execute the at least one instruction to: based on detecting an occurrence of an event for stopping the robot while the first driving wheel rotates at a first speed and the second driving wheel rotates at a second speed, control the driving part to stop the robot based on the first speed and the second speed, and wherein the at least one processor may be further configured to execute the at least one instruction to control the driving part to stop the robot by: based on a relation between the first speed and the second speed satisfying a first condition, controlling the driving part such that a proceeding axis of the first driving wheel rotates in a first direction and a proceeding axis of the second driving wheel rotates in a second direction opposite to the first direction, and based on the relation between the first speed and the second speed satisfying a second condition, controlling the driving part such that the first driving wheel and the second driving wheel rotate in different directions at a same speed.

An electronic device includes a driving part including a first driving wheel and a second driving wheel; a memory storing at least one instruction; and at least one processor operatively coupled with the driving part and the memory, wherein the at least one processor is configured to execute the at least one instruction to: based on detecting an occurrence of an event for stopping the robot while the first driving wheel rotates at a first speed and the second driving wheel rotates at a second speed, control the driving part to stop the robot based on the first speed and the second speed, and wherein the at least one processor may be further configured to execute the at least one instruction to control the driving part to stop the robot by: based on a relation between the first speed and the second speed satisfying a first condition, controlling the driving part such that a proceeding axis of the first driving wheel rotates in a first direction and a proceeding axis of the second driving wheel rotates in a second direction opposite to the first direction, and based on the relation between the first speed and the second speed satisfying a second condition, controlling the driving part such that the first driving wheel and the second driving wheel rotate in different directions at a same speed.