Device, system, and method for Skydiving Robots? which can skydive using customized or off-the-shelf parachutes and deliver civilian or military payloads. The Skydiving Robots can freefall, open the parachute and steer toward the target, carry payloads, operate in the daytime or the pitch black at night using GPS guidance to land precisely. If they exited the plane at up to or over 30,000 feet above ground level (AGL) the final target could be miles away. They are the ideal reconnaissance scouts with a wide array of sensors such as cameras. They can carry payloads and precisely land within a few feet of a target.

Device, system, and method for Skydiving Robots? which can skydive using customized or off-the-shelf parachutes and deliver civilian or military payloads. The Skydiving Robots can freefall, open the parachute and steer toward the target, carry payloads, operate in the daytime or the pitch black at night using GPS guidance to land precisely. If they exited the plane at up to or over 30,000 feet above ground level (AGL) the final target could be miles away. They are the ideal reconnaissance scouts with a wide array of sensors such as cameras. They can carry payloads and precisely land within a few feet of a target.

A system searches for a track for a vehicle to travel automatically. The system includes a processor. The processor includes a route search unit, a restriction condition generation unit, and a track search unit. The route search unit searches for a series having elements of a position and posture of the vehicle, which is a route for moving from an initial position to a target position of the vehicle, based on a first restriction condition representing a position of an obstacle. The restriction condition generation unit generates a second restriction condition in which a penalty value increases according to a deviation distance from the route. The track search unit searches for a series having elements of a position, posture, speed, and steering angle of the vehicle, which is a track for moving from the initial position to the target position of the vehicle, based on the second restriction condition.

A system searches for a track for a vehicle to travel automatically. The system includes a processor. The processor includes a route search unit, a restriction condition generation unit, and a track search unit. The route search unit searches for a series having elements of a position and posture of the vehicle, which is a route for moving from an initial position to a target position of the vehicle, based on a first restriction condition representing a position of an obstacle. The restriction condition generation unit generates a second restriction condition in which a penalty value increases according to a deviation distance from the route. The track search unit searches for a series having elements of a position, posture, speed, and steering angle of the vehicle, which is a track for moving from the initial position to the target position of the vehicle, based on the second restriction condition.

A robot cleaner includes a body to travel on a floor; an obstacle sensing unit to sense an obstacle approaching the body; an auxiliary cleaning unit mounted to a bottom of the body, to be extendable and retractable; and a control unit to control extension or retraction of the auxiliary cleaning unit when the obstacle is sensed. The control unit prevents the auxiliary cleaning unit from extending if a signal is received from a charger.

The substrate treating apparatus includes an analysis part configured to communicate with a measurement unit to be input with an information with respect to a boundary, to calculate a center coordinate value of a substrate and a center coordinate value of a support unit with an input information on the boundary, to set a calculated center coordinate value of the support unit as a center coordinate value of the measurement unit, to set a calculated center coordinate value of the substrate as a center coordinate value of a transfer robot, to record the center coordinate value of the transfer robot on a plane coordinate system of the measurement unit, and to convert a recorded center coordinate value of the transfer robot and a center coordinate value of the measurement unit to a plane coordinate system of the transfer robot to teach the transfer robot.

Embodiments of the present disclosure provide a distance measurement method and device, a robot and a storage medium. The method comprises: acquiring a first image, where the first image at least comprises a to-be-detected object and a ground on which the to-be-detected object is located; determining an initial constraint condition of the ground based on the first image; acquiring a second image, where the second image at least comprises an intersection line of a line structured light beam with the ground and/or with the to-be-detected object; determining a position parameter of the ground based on the second image, and correcting the initial constraint condition of the ground based on the position parameter; and determining a distance to the to-be-detected object based on the corrected initial constraint condition of the ground and the first image.

Embodiments of the present disclosure provide a distance measurement method and device, a robot and a storage medium. The method comprises: acquiring a first image, where the first image at least comprises a to-be-detected object and a ground on which the to-be-detected object is located; determining an initial constraint condition of the ground based on the first image; acquiring a second image, where the second image at least comprises an intersection line of a line structured light beam with the ground and/or with the to-be-detected object; determining a position parameter of the ground based on the second image, and correcting the initial constraint condition of the ground based on the position parameter; and determining a distance to the to-be-detected object based on the corrected initial constraint condition of the ground and the first image.

A method and apparatus for remote control of a vehicle. An input and/or remote control device is provided. The apparatus includes: a transceiver device in the vehicle, configured to exchange signals with the input and/or remote control device; sensors mounted in or on the vehicle for detecting the environment of the vehicle; a signal from the input and/or remote control device to the transceiver device activates an operating mode in the vehicle in which the vehicle moves to a target position independently, i.e., without the assistance of a driver located in the vehicle. The target position is in a first direction of travel of the vehicle. The vehicle, in the operating mode, also moves in the second direction of travel opposite the first direction of travel depending on the detected environment. The vehicle can also move away from the target position in order to reach the target position.

A method and apparatus for remote control of a vehicle. An input and/or remote control device is provided. The apparatus includes: a transceiver device in the vehicle, configured to exchange signals with the input and/or remote control device; sensors mounted in or on the vehicle for detecting the environment of the vehicle; a signal from the input and/or remote control device to the transceiver device activates an operating mode in the vehicle in which the vehicle moves to a target position independently, i.e., without the assistance of a driver located in the vehicle. The target position is in a first direction of travel of the vehicle. The vehicle, in the operating mode, also moves in the second direction of travel opposite the first direction of travel depending on the detected environment. The vehicle can also move away from the target position in order to reach the target position.