A robot is provided. When a value obtained by excluding a gravitational component from an acceleration detected by an acceleration sensor is continuously less than a reference value for a certain time, a travelling state of the robot is determined as frictional surface travelling. A control circuit calculates an attitude angle of the robot from an angular velocity in a pitch direction, which is detected by an angular velocity sensor. When the calculated attitude angle is a lower limit angle or more for a determination time, the control circuit sets the attitude angle at the end of the determination time as an attitude control angle. When the travelling state of the robot is determined as the frictional surface travelling, the control circuit moves a counterweight frontward by a movement amount corresponding to the attitude control angle.

A self-propelled device operates to interpret an input corresponding to a set of actions that are performed on a controller device.

A connection structure includes two connection interfaces and a connector. Each connection interface includes planar contacts arranged at a center and one or more concentric rings on a circuit board and first lock mechanisms arranged on a first casing. The connector includes a second casing including two open ends and second lock mechanisms arranged on the second casing and pins. Each pin includes two ends each exposed by one of the two open ends of the second casing, respectively. When the connector is plugged into the two connection interfaces at orientations relative to one another, the pins of the connector are in contact with the planar contacts of each connection interface so that the two connection interfaces are electrically connected, and the second lock mechanisms of the connector are interlocked with the first lock mechanisms of each connection interface so that the two connection interfaces are mechanically connected.

In a robot, after a first value indicating acceleration in the up-and-down axis direction output from an acceleration sensor exceeds a certain threshold value, when any of the first value indicating the acceleration in the up-and-down axis direction, a second value indicating the acceleration in the front-and-back axis direction, and a third value indicating the acceleration in the left-and-right axis direction is determined to exhibit variation exceeding a certain width for a fixed period, the robot determines that a housing of the robot is being held by a user.

A robot including a spherical housing made up of a main housing portion, a first spherical cap portion, and a second spherical cap portion. The main housing portion is disposed between the first spherical cap portion and the second spherical cap portion. The robot further including a weight that is provided in the main housing portion and configured to rotate around a pivot that is orthogonal to a shaft connecting the spherical cap portions. When outputting a response to an input instruction received from a user, via an input device, based on a predetermined processing is determined to require a predetermined time or more, a robot controls a first drive mechanism during the predetermined processing such that the first drive mechanism rotates a weight around the pivot to reciprocally move the weight in the opposite directions of the pivot.

A modular sensing device can include an inertial measurement unit to generate sensor data corresponding to user gestures performed by a user, a mode selector enabling the user to select a mode of the modular sensing device out of a plurality of modes, and one or more output devices to generate output based on the user gestures and the selected mode. The modular sensing device can further include a controller to implement a plurality of state machines. Each state machine can be associated with a corresponding user gesture by a sensor data signature. The state machine can execute a state transition when the sensor data matches the sensor data signature. The executed state transition can cause the controller to generate a corresponding output via the one or more output devices specific to the selected mode and based on the corresponding user gesture.

A robot having a spherical casing, a weight driving mechanism, and a rotating mechanism is provided. The robot further includes a control circuit that controls the weight driving mechanism and the rotating mechanism is also provided. The control circuit is configured to, when responding to an input instruction received from a user, based on a predetermined processing that requires a predetermined amount of time or more to respond to an input instruction by a user input via an input device, cause the weight driving mechanism to be rotated to where a guide path of the weight driving mechanism is positioned to be orthogonal to an advancing direction by a set of driving wheels. The control circuit is further configured to cause the weight to be reciprocally move along the guide path that is positioned orthogonal to the advancing direction, during the predetermined processing.

A robot having a spherical casing, a control circuit and a communication circuit configured to connect to an external server is provided. The robot further includes a set of wheels included in the spherical casing, which comes into contact with an inner surface of the spherical casing and configured to rotate the spherical casing when the driving wheels are driven. The control circuit is configured to, when determining that performing a predetermined processing in response to an input instruction received from a user requires a predetermined amount of time or more, causes each of the set of driving wheels to rotate in opposite directions from each other to rotate the spherical casing during the predetermined processing. When the predetermined processing is complete and a response is to be output, the control circuit stops rotation of the spherical casing with the set of wheels facing toward the user.

In one embodiment, a neuromorphic robot includes a curved outer housing, and multiple touch sensors provided on the outer housing, wherein the robot is configured to interpret a touch of a user sensed with the touch sensors.

A multi-body self-propelled device can include a drive body and a coupled head. The drive body can include a spherical housing and an internal drive system within the spherical housing to propel the multi-body self-propelled device. The drive body can further include a magnet support assembly comprising a rotating portion including a plurality of magnets and a stationary portion comprising one or more magnets. The drive body can further include a yaw motor to drive the rotating portion of the magnet support assembly. The coupled head can include (i) a corresponding rotating portion comprising a plurality of magnets in magnetic interaction, through the spherical housing, with the plurality of magnets of the magnet support assembly, and (ii) a corresponding stationary portion comprising one or more magnets in magnetic interaction with the one or more magnets of the magnet support assembly.