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.

A wearable device can be worn by a user, and can include a mode selector, one or more sensors, a signal detector to detect wireless signals, a feedback mechanism comprising at least one of a haptic system, an audio system, or a visual system and providing feedback outputs. The wearable device can also include a controller that can initiate a selected mode from a plurality of modes on the wearable device, where the selected mode causing the controller to execute a real-world game. In accordance with the selected mode, the controller can interpret sensor data from the one or more sensors and inputs from the signal detector, where the sensor data corresponds to a series of actions performed by the user utilizing the wearable device. Based the interpretations, the controller can generate feedback responses via a feedback mechanism.

A system can include a wearable device and a self-propelled device. The wearable device can include a controller that, in response to a user input on the mode selector, initiates a selected mode from a plurality of modes on the wearable device. The selected mode can cause the controller to establish a communication link with the self-propelled device, and generate an output using a feedback mechanism instructing the user to perform a series of actions with the wearable device. In accordance with the selected mode, the controller can interpret sensor data from one or more sensors to determine whether the user has performed the series of actions while utilizing the wearable device. Based on determining whether the user has performed the series of actions, the controller can generate one of a positive or a negative feedback using the feedback mechanism.

A modular sensing device can generate output via one or more output devices. The modular sensing device can include an inertial measurement unit that generates sensor data corresponding to user gestures performed by a user, a wireless communication module, 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 configured to generate output based on the user gestures and the selected mode. The selected mode configures the manner in which the modular sensing device generates output via the one or more output devices based on the user gestures.

A wearable device can be worn by a user, and can include one or more sensors to detect user gestures performed by the user. The wearable device can further include a wireless communication module to establish a communication link with a self-propelled device, and a controller that can generate control commands based on the user gestures. The control commands may be executable to accelerate and maneuver the self-propelled device. The controller may then transmit the control commands to the self-propelled device over the communication link for execution by the self-propelled device.

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 modular sensing device and method of operating a smart home device includes initiating a control mode from a plurality of modes on the modular sensing device, where the control mode determines a manner in which user gestures are interpreted. Based on initiating the control mode, a connection with the smart home device can be established. Furthermore, the modular sensing device and method can further include receiving sensor data corresponding to the user gestures, translating the sensor data into a corresponding control command, and transmitting the control command to the smart home device. The corresponding control command can be executable to control the smart home device in accordance with the user gesture.

A toy top equipped with a motor having a battery as a power source, wherein a main body is furnished with: a first wheel and a second wheel provided a specified distance from each other in a wheel axis direction; and a motive power transmission mechanism, for transmitting motive power from the motor and for rotating the first wheel in a first direction while rotating the second wheel in a second different direction The toy top is stable with respect to external forces and with which a range of top games can be broadened.

A toy is controlled by a smart device with wireless communication network connection capability, a display screen and programmed to generate optical control signals transmitted through the screen. The toy includes a main body, a control circuit, a holder configured to receive and releasably hold the smart device, and an optical signal receiver supported facing the display screen of the smart device in the holder and operably connected with the control circuit. The control circuit responds to optical control signals transmitted through the screen and detected by the optical signal receiver to control at least one operation of the toy.

A system comprising a self-propelled device and an accessory device. The self-propelled device includes a spherical housing, and a drive system provided within the spherical housing to cause the self-propelled device to roll. When the self-propelled device rolls, the self-propelled device and the accessory device magnetically interact to maintain the accessory device in contact with a top position of the spherical housing relative to an underlying surface on which the spherical housing is rolling on.