An information processing device (10) according to the present disclosure includes an operation controller (175) that controls a moving operation of an autonomous mobile body (10) that travels while maintaining an inverted state, and controls a posture operation of the autonomous mobile body that temporally changes from a reference posture in the inverted state. Furthermore, the information processing device (10) according to the present disclosure further includes an acquisition unit (174) that acquires motion data corresponding to a posture operation of the autonomous mobile body (10). The operation controller (175) controls a posture operation of the autonomous mobile body (10) based on the motion data acquired by the acquisition unit (174).

A robot has a main body frame, an elastic body that forms a closed space between the elastic body and the main body frame, a movement mechanism that has a surface that is grounded when moving, and which is provided so as to be able to be housed in the closed space, and a drive mechanism that causes the movement mechanism to advance to an exterior of the closed space or to retreat into an interior. The elastic body elastically transforms owing to a pressing force received in accompaniment to an advancing of the movement mechanism, increasing the size of an aperture portion for exposing the movement mechanism, and elastically recovers in accompaniment to a retreat of the movement mechanism, reducing the size of the aperture portion.

The present technology relates to an autonomous mobile body, an information processing method, a program, and an information processing apparatus capable of improving user experience by an output sound of the autonomous mobile body.

The autonomous mobile body includes: a recognition unit that recognizes a motion of its own device; and a sound control unit that controls an output sound output from the own device. The sound control unit controls output of a plurality of operation sounds that is the output sound corresponding to a plurality of the motions of the own device, and changes the operation sound in a case where the plurality of motions has been recognized. The present technology can be applied to, for example, a robot.

Disclosed is a spherical robot may include a body having a substantially spherical shape; and a ring member having a ring shape, the ring member being coupled to the body so as to be rotated about the body, wherein the ring member includes an inner surface configured to face a surface of the body and an outer surface opposite to the inner surface.

A smart interactive toy comprises a shell, an interactive control module, a moving mechanism, and an anti-fall sensing module comprising a first signal sending unit and a signal receiving unit; the first signal sending unit is mounted on the shell, connected electrically with the interactive control module and used for sending a first sensing signal to the interactive control module when the signal receiving unit does not receives a first reflected signal, reflected after the first sensing signal meets an obstacle, in a predetermined time period, so that the interactive control module drives the moving mechanism to stop moving, thereby achieving that the user controls the smart interactive toy to avoid it from falling down a table or into a deep pit, which ensures that the toy can be interacted and is not easy to damage.

A self-propelled device can include at least a wireless interface, a housing, a propulsion mechanism, and a camera. Using the camera, the self-propelled device can generate a video feed and transmit the video feed to a controller device via the wireless interface. The self-propelled device can receive an input from the controller device indicating an object or location in the video feed. In response to the input, the self-propelled device can initiate an autonomous mode to autonomously operate the propulsion mechanism to propel the self-propelled device towards the object or location indicated in the video feed.

An aeronautical vehicle that rights itself from an inverted state to an upright state has a self-righting frame assembly has a protrusion extending upwardly from a central vertical axis. The protrusion provides an initial instability to begin a self-righting process when the aeronautical vehicle is inverted on a surface. A propulsion system, such as rotor driven by a motor can be mounted in a central void of the self-righting frame assembly and oriented to provide a lifting force. A power supply is mounted in the central void of the self-righting frame assembly and operationally connected to the at least one rotor for rotatably powering the rotor. An electronics assembly is also mounted in the central void of the self-righting frame for receiving remote control commands and is communicatively interconnected to the power supply for remotely controlling the aeronautical vehicle to take off, to fly, and to land on a surface.

A ball-balancing robot is capable of accurately controlling its posture when a robot main body is rotated about the vertical axis in a yaw direction in a state in which the robot main body is positioned on a spherical object in a posture in which a gravity center of the robot main body matches a vertical axis passing a center of the spherical object, and in a state in which a base axis of the roll-direction angular velocity sensor is inclined with respect to the horizon in a pitch direction (at an inclination angle θ.sub.P), the robot main body is able to rotate while maintaining a predetermined posture by making correction to cancel a detection error in the angular velocity in the roll direction generated based on the inclination of the base axis of the roll-direction angular velocity sensor.

The Rollback Ball or Ballmerang is a ball toy consisting of a ball shell and a mechanical tracking device tracking the ball shell by using friction force or magnetic force converting the moving ball kinetic energy to potential energy, and then releasing the potential energy rolling the ball back at the same straight line path to the same launching destination when rolling the ball in any direction on a flat floor.

A method for registering one of a plurality of assembly modules operatively coupled to one another in a modular assembly system is provided. A first message including a first identifier of the assembly module is received from one of the plurality of assembly modules. A second message including a second identifier for the assembly module is transmitted to the assembly module. The second identifier is generated based on at least the first identifier. A third message including the second identifier is received from the assembly module. In response to determining that the third message is received, the assembly module is registered as a new assembly module of the modular assembly system. At least one of the receiving, transmitting, determining, and registering is performed by a control module of the plurality of assembly modules.