Presented are intelligent electronic footwear with controller automated features, methods for making/using such footwear, and control systems for executing automated features of intelligent electronic footwear. An intelligent electronic shoe includes an upper that attaches to a user's foot, and a sole structure attached to the upper for supporting thereon the user's foot. A collision threat warning system, a detection tag, a wireless communications device, and a footwear controller are all mounted to the sole structure/upper. The detection tag receives a prompt signal from a transmitter-detector module and responsively transmits thereto a response signal. The footwear controller receives, through the wireless communications device, a pedestrian collision warning signal generated by the remote computing node responsive to the response signal. Responsively, the footwear controller transmits a command signal to the collision threat warning system to generate a visible, audible and/or tactile alert warning the user of an impending collision with a vehicle.

A method includes receiving monitoring data from at least one sensing device coupled to a subject and analyzing the monitoring data to identify one or more physiologic parameters of the subject. The method also includes providing signaling to at least one stimulating device in response to the identified physiologic parameters, the signaling comprising instructions to apply a stimulus to the subject. The method further includes receiving additional monitoring data from the at least one sensing device, analyzing the additional monitoring data to identify one or more changes in the one or more physiologic parameters of the subject after application of the stimulus to the subject, and providing additional signaling to the at least one stimulating device, the additional signaling comprising instructions to modify the stimulus applied to the subject based on the identified changes in the one or more physiologic parameters.

A method includes receiving monitoring data from at least one sensing device coupled to a subject and analyzing the monitoring data to identify one or more physiologic parameters of the subject. The method also includes providing signaling to at least one stimulating device in response to the identified physiologic parameters, the signaling comprising instructions to apply a stimulus to the subject. The method further includes receiving additional monitoring data from the at least one sensing device, analyzing the additional monitoring data to identify one or more changes in the one or more physiologic parameters of the subject after application of the stimulus to the subject, and providing additional signaling to the at least one stimulating device, the additional signaling comprising instructions to modify the stimulus applied to the subject based on the identified changes in the one or more physiologic parameters.

A wearable may be provided with or configured to provide interactive skin. The interactive skin may be configured for accepting touch input from a user. The interactive skin may include one or more flexible layers and may include or be mounted under a transparent display cover layer such as a layer of clear glass or plastic. Interactive skin may include a touch-sensitive layer that allows a user to provide touch input to the wearable. Display pixels on interactive skin may be used to display visual information to the user. The interactive skin may be configured for detecting a condition of at least one wearable and generating an output function in response to the detected condition.

A wearable may be provided with or configured to provide interactive skin. The interactive skin may be configured for accepting touch input from a user. The interactive skin may include one or more flexible layers and may include or be mounted under a transparent display cover layer such as a layer of clear glass or plastic. Interactive skin may include a touch-sensitive layer that allows a user to provide touch input to the wearable. Display pixels on interactive skin may be used to display visual information to the user. The interactive skin may be configured for detecting a condition of at least one wearable and generating an output function in response to the detected condition.

A system for dynamic movement scoring comprising an article of footwear or apparel and a processor in networked wireless communication with the article of footwear or apparel. The article includes at least one accelerometer or inertial measurement unit operative to monitor spatial motion of at least a portion of the article of footwear or apparel, and to generate a data stream indicative of the monitored spatial motion. The processor is configured to receive the data stream from the article of footwear or apparel, identify at least one motion primitive from the received data stream; and determine an accuracy metric representing a correspondence between the monitored spatial motion of the article of footwear or apparel and the ordered number of motion primitives.

A system for motion-based media creation includes an article of footwear or apparel having at least one accelerometer or inertial measurement unit operative to monitor spatial motion of at least a portion of the article of footwear or apparel and generate a data stream indicative of the monitored spatial motion. The system further includes a processor in networked wireless communication with the article of footwear or apparel. The processor is configured to receive the data stream from the article of footwear or apparel; identify at least one motion primitive from the received data stream; and trigger the playback of an audio sample or a visual effect in response to the identified at least one motion primitive.

A system for motion-based media creation includes an article of footwear or apparel having at least one accelerometer or inertial measurement unit operative to monitor spatial motion of at least a portion of the article of footwear or apparel and generate a data stream indicative of the monitored spatial motion. The system further includes a processor in networked wireless communication with the article of footwear or apparel. The processor is configured to receive the data stream from the article of footwear or apparel; identify at least one motion primitive from the received data stream; and trigger the playback of an audio sample or a visual effect in response to the identified at least one motion primitive.

In a guidance support device to be used by being inserted into footwear, a plurality of vibration generating members generate vibrations at a plurality of positions on a foot of a user who uses the guidance support device. A position acquisition part acquires a current position. A route acquisition part acquires a route from the current position to a destination. A vibration control part, on condition that a route pattern at a current position on the route fits any one of a plurality of predetermined patterns, vibrates the vibration generating members in a combination corresponding to the pattern.

A method includes receiving monitoring data from at least one sensing device coupled to a subject and analyzing the monitoring data to identify one or more physiologic parameters of the subject. The method also includes providing signaling to at least one stimulating device in response to the identified physiologic parameters, the signaling comprising instructions to apply a stimulus to the subject. The method further includes receiving additional monitoring data from the at least one sensing device, analyzing the additional monitoring data to identify one or more changes in the one or more physiologic parameters of the subject after application of the stimulus to the subject, and providing additional signaling to the at least one stimulating device, the additional signaling comprising instructions to modify the stimulus applied to the subject based on the identified changes in the one or more physiologic parameters.