A ribbon cord containment and identifying adaptor can be adaptively anchored or fixed to or removed from a ribbon type cord or ribbon cord of a set of earphones by hand via an anchor slot of the adaptor. The anchor slot can have a frame or structure that has an entrapment chamber and a path leading to a cord entrapment chamber where the entrapment chamber is slanted with respect to the path leading to the entrapment chamber. The structure of the entrapment chamber and path help anchor the adaptor on the ribbon type cord segment to prevent inadvertent dislodgement of the adaptor from the cord segment. The structure of the anchor slot is rigid and serves to firmly grip or compress cord segments positioned between gapped-apart opposing sidewalls within the anchor slot. When a cord containment adaptor is anchored via the anchor slot, ribbon type cord segments can be gripped into slots in a manner that helps prevent the adopter from dislodging from the ribbon cord. When positioned on cord segments, the adaptors can serve as identifying objects or adaptors.

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.

This disclosure includes several different features suitable for use in circumaural and supra-aural headphones designs. Designs that include earpad assemblies that improve acoustic isolation are discussed. User convenience features that include automatically detecting the orientation of the headphones on a user's head are also discussed. Various power-saving features, design features, sensor configurations and user comfort features are also discussed.

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.

Headphone playback devices can include a cable assembly including a plurality of conductors extending between a first earpiece and a second earpiece. The cable assembly includes a jacket, a power conductor disposed within the jacket and coupled between a power source in the first earpiece and a wireless transceiver in the second earpiece. The cable assembly further includes a microphone conductor at least partially disposed within the jacket and coupled to a microphone in one of the earpieces. A shield is at least partially disposed between the power conductor and the microphone conductor to reduce electromagnetic interference between the two.

This document describes techniques and devices for detecting twist input with an interactive cord. An interactive cord may be constructed with one or more conductive yarns wrapped around a cable in a first direction (e.g., clockwise), and one or more conductive yarns wrapped around the cable in a second direction that is opposite the first direction (e.g., counter-clockwise). A controller measures one or more capacitance values associated with the conductive yarns. In response to detecting a change in the one or more capacitance values, the controller determines that the change in the capacitance values corresponds to twist input caused by the user twisting the interactive cord. Then, the controller initiates one or more functions based on the twist input, such as by controlling audio to a headset by increasing or decreasing the volume, scrolling through menu items, and so forth.

A hearing device and subassembly therefor includes a sleeve member configured for at least partial insertion into a user's ear canal, the sleeve member defining a cavity that receives and retains at least a portion of a sound-producing electroacoustic transducer. The sleeve member includes a cable interface, wherein an electrical interface of a sound-producing electroacoustic transducer received in the cavity is accessible via the cable interface. The device also includes on or more sensors integrated with the sleeve member and positioned to sense a biomarker or other condition when the sleeve member is at least partially inserted into the user's ear canal. The hearing device includes conductive traces integrated with the sleeve member, where at least one conductive trace is electrically connected to the sensor and electrically connectable via the cable interface.

Systems and apparatuses for supporting electronic devices are described. Such systems and apparatuses provide significant adaptability to position an electronic device in commonly used locations by using an interface that is readily provided in virtually any location. Furthermore, the systems and apparatuses described herein include cradles that adaptable to a wide array of electronic device dimensions, including width and depth or thickness.

A tool for arranging voice coil leadouts in a microspeaker comprises an expanding collet constructed and arranged for positioning at an interior of a bobbin having an inner diameter, the expanding collet including a hole that extends through an interior in a longitudinal direction of the expanding collet; a center pin extending through the hole of the expanding collet, the expanding collet applying a force against the inner diameter of the bobbin in response to a position of the center pin in the hole of the expanding collet relative to the interior of the expanding collet; and a forming mandrel including a hole that extends through an interior in a longitudinal direction of the forming mandrel. The expanding collet extends through the hole in, and coaxial with, the forming mandrel. The expanding collet rotates the bobbin about the longitudinal direction of the expanding collet relative to the forming mandrel to form helical leadout regions of a voice coil about the bobbin.

A support and retainer system for a wired headphone is herein disclosed. The system includes a stand and a holding device. The stand includes a base, a cradle for supporting a mobile device, with the cradle coupled to the base, and a pair of arms extending from the cradle, with each arm configured to retain a respective headphone wire. The holding device is designed to windably maintain the wired headphone such that the wired headphone can be extended and retracted effectively, quickly, and without becoming tangled, in use.