The present disclosure presents a communication device configured to removably attach to a mask, and to receive, transmit, and amplify sound and/or speech from a wearer.

Methods of enhancing a sensory experience to simulate a live event are provided. One includes providing an audible signal representing sound information; generating a vibration signal based on the audible signal and enhanced information that would be present at the live event; and providing the vibration signal to at least one vibration device for stimulating nerve receptors in a foot area, the vibration signal synchronized with the audible signal to produce a perception in the brain of being present at the live event. Another method includes generating a vibration signal representing vibrations including tactile vibrations for stimulating nerve receptors in a foot to simulate being present at a live event, and vibrations based on reproduced sound information; and providing the signal to at least one vibration device for delivering the vibrations to the feet, the tactile vibrations based on enhanced information different from the sound information and including non-audible elements.

Detachable wearable electronic eyeglasses and head mounted gear with a plurality of electronic functions and interchangeable electronic function, and a wearable computer with optimal weight distribution and stretchable arms.

Hands-free electronic devices and electronic functions that can be worn on the surface of the body in a biologically fit manner are described. The embodiments provide a convergence between electronic products, and biological, anatomical, and biomechanical aspects of the human body while providing hands-free and interchangeable wearable electronic apparatuses that can interact with human senses and physiology of a human body in a practical manner.

Wearable electronic device includes a neck loop worn on a neck with two electromechanical units; two in-ear earphones; two earphone cords. Each unit has an earphone cord winding mechanism including (i) a spool for winding the earphone cord; (ii) a double drive mechanism including an electric motor, a reducer, and a spiral spring; (iii) an engagement mechanism for engagement between the drive mechanism and the spool; and (iv) a lock mechanism. One unit has a motor control key for the electric motor and the lock mechanism. One end of the cords is connected to one of the earphones and the other end to one of the spools. The units are mechanically connected to each other to prevent twisting, and to the neck loop so that one of the units is on the left side of the chest, and the other electromechanical unit is on the right side of the chest.

A control apparatus according to an embodiment of the present technology includes an audio control section and a vibration control section.

The audio control section generates audio control signals of a plurality of channels with audio signals of the plurality of channels as input signals, the audio signals each including a first audio component and a second audio component different from the first audio component. The vibration control section generates a vibration control signal for vibration presentation by taking a difference between audio signals of two channels among the plurality of channels.

A set of headphones and audio system comprises a first set of buttons for controlling a volume level of transmitted audio to the headphones and a second set of buttons for controlling a volume level of external audio played by the headphones. The transmitted audio comprises audio received from an audio source such as an electronic device and the external audio comprises surrounding ambient noise received by a microphone coupled to the headphones. With the first set of controls and the second set of controls a user is able to adjust the volume level of the transmitted audio and the volume level of the external audio in order to listen to the transmitted audio while still interacting with the surrounding environment.

The present disclosure relates generally to providing a flexible patch and system for communicating through hard plastic masks such as CPAP/BiPAP® masks. Using electronic circuitry and novel designs, the present systems and methods can detect speech vibrations and output audible speech from hard plastic mask wearers. For example, in certain embodiments, the present systems and methods can recognize speech through a CPAP/BiPAP® mask, filter out non-human voice related noise, and output the resulting speech of the mask wearer.

A face mask can both actively cancel sounds and passively attenuate sounds spoken by the user to prevent the sounds from reaching non-intended recipients positioned near the user. The mask can not only reduce the user's voice from escaping the mask but can also be used to reduce external sounds from reaching inside the mask. Thus, a user can wear the mask in public and talk on their phone without disturbing others around them. The mask can include at least one microphone and at least one audio speaker disposed inside and/or outside the mask. Sounds received by the microphone can be processed by a microphone and computing electronics to provide an output to the audio speaker that can appropriately attenuate the sound received by the microphone, via acoustic cancelation. The mask can not only be used to cancel sounds but may also be used to amplify sounds when desired.

One or more sensors are configured to contextualize a series of user generated movements to control one or more electronic devices. For example, a set of earphones comprises one or more sensors for sensing a location of the earphones. The one or more sensors enable earphones such as a pair of bluetooth or earphones wirelessly coupled to a bluetooth enabled electronic device, the capability to understand the configuration of use of the earphones. Based on a location and use or non-use of the earphones, one or more contextual responses is able to be applied for a given action. In addition, a garment comprises one or more sensors for sensing a motion of a user as the garment is being used. The one or more sensors allow the user to control one or more electronic devices through a series of user generated movements.