Disclosed is a moving robot including: a voice input unit configured to receive a voice input of a user; a first display capable of receiving a touch input; a second display larger than the first display; and a controller configured to perform control such that a screen to be displayed in response to the voice input or the touch input is displayed on at least one of the first display or the second display based on a type and an amount of information included in the screen, and accordingly, it is possible to provide information and services more effectively using the two displays.

The present disclosure relates to a method for sensing the depth of an object by considering external light and a device implementing the same, and a method for sensing the depth of an object by considering external light according to an embodiment of the present disclosure comprises the steps of: storing, in a storage unit, first depth information of an object, which is sensed at a first time point by a depth camera unit of a depth sensing module; storing, in the storage unit, second depth information of the object, which is sensed at a second time point by the depth camera unit; comparing, by a sensing data filtering unit of the depth sensing module, the generated first and second depth information to identify a filtering target region from the second depth information; and adjusting, by a control unit of the depth sensing module, the depth value of the region filtered from the second depth information.

A robotic animal puzzle is assembled from flat board pieces. The robotic animal includes a head portion. The head portion includes a neck group, a torso portion, including a holder 15 for an optional battery, multiple leg portions, and a tail portion. Those pieces and groups are connected using either interlocking mechanisms or flexible linkages to form the robotic animal-shaped puzzle. Movement and gestures may be controlled by an externally connected processor powered by an on-board battery pack. A pull and drag mechanism is provided to conveniently tune the center of mass. Slots allow the screw that connects the battery holder to slide.

An ultrasonic manipulator for processing three-dimensional composite preforms is provided, including at least one end effector, the end effector having an ultrasonic cutting device, an ultrasonic machining device, an ultrasonic inspecting device, and an ultrasonic bonding device. A method for creating three-dimensional preforms for use in molding composite parts is also provided, and includes the steps of grasping a preform/towpreg, inspecting the composite object using ultrasound, cutting a preform from the composite object using ultrasound, and at least some of the steps of shaping the preform using ultrasound, machining the preform using ultrasound, assembling a plurality of preforms, bonding the assembled preforms together to create a preform charge, and placing the preform charge in an injection mold.

In order to make learning efficient for a robot, a robot operation device is provided with operation information input units for generating operation information specifying a state of a robot on the basis of an operation by an operator, a control unit for controlling the robot on the basis of the operation information, a non-operation information collecting unit for collecting non-operation information which is information that relates to the operator and does not affect the state of the robot, an action analysis unit for estimating the state of the operator on the basis of the non-operation information, and an action learning unit for learning the operation of the operator on the basis of the operation information and the estimation result of the action analysis unit.

An apparatus such as a robot capable of performing goal oriented tasks may include one or more touch sensors to receive touch perception feedback on the location of objects and structures within an environment. A fusion engine may be configured to combine touch perception data with other types of sensor data such as data received from an image or distance sensor. The apparatus may combine distance sensor data with touch sensor data using inference models such as Bayesian inference. The touch sensor may be mounted onto an adjustable arm of a robot. The apparatus may use the data it has received from both a touch sensor and distance sensor to build a map of its environment and perform goal oriented tasks such as cleaning or moving objects.

A control apparatus that controls a robot including a dispenser and range sensors includes a control unit, and the control unit controls a robot arm, when the dispenser is moved in a first moving direction, to place the first range sensor anterior and calculates an amount of ejection using a difference between values detected by the first range sensor and the second range sensor forming a set and controls the robot arm, when the dispenser is moved in a second moving direction, to place the third range sensor anterior and calculates the amount of ejection using a difference between values detected by the third range sensor and the fourth range sensor.

A control device includes a control section configured to control a motion of a robot arm using values detected by a plurality of distance sensors. The plurality of distance sensors include a first distance sensor and a second distance sensor disposed in a first direction orthogonal to the axial direction of a dispenser. The second distance sensor is disposed in a position further apart from the dispenser than the first distance sensor. The control section executes, on a robot, a first instruction for causing the robot to execute discharge of a discharge object by the dispenser when a distance acquired by the first distance sensor is a distance in a predetermined range and a distance acquired by the second distance sensor is a distance larger than the distance in the predetermined range.

A movable automatic feeding device according to an embodiment includes: a body to form an outer appearance which includes an upper housing and a lower housing; a terminal mounting unit formed in the upper housing; a first interface unit which is a wired port disposed near the terminal mounting unit; a moving module provided with wheels disposed on the bottom surface of the lower housing and a drive motor to rotate the wheels; a feeding module which includes a feed container disposed in the upper housing and a feed discharge unit to discharge feed stored in the feed container; and a battery to supply electric power to the moving module and the feeding module.

One embodiment is directed to a personal robotic system, comprising: an electromechanical mobile base configured to be controllably movable upon a substantially planar surface in a global coordinate system wherein a Z axis is defined perpendicular to the substantially planar surface; a torso assembly movably coupled to the mobile base such that the torso may be controllably moved in a direction substantially parallel to the Z axis and also controllably rotated about an axis substantially perpendicular to the Z axis; a head assembly movably coupled to the torso assembly; a robotic arm operatively coupled to the torso assembly; and a controller operatively coupled to the mobile base, torso assembly, head assembly, and robotic arm, and configured to controllably manipulate nearby objects while also automatically minimizing destabilizing moments applied to the mobile base through movement of at least one of the mobile base, torso assembly, head assembly, and robotic arm.