Abstract: A textile device configured to cooperate with an electronic device including a first magnetic connection means, an electronic circuit including a connecting track, and a first positioning means; the textile device including: a textile including a conductive zone; a second magnetic connection means, connected to a first side of the textile, configured to cooperate with the first magnetic connection means to create a force of attraction with the first magnetic connection means; a second positioning means capable of cooperating with the first positioning means to position the textile device relative to the electronic device; wherein the positioning means of the textile device is arranged in so that the conductive area of the textile device is connected to the connection track of the electronic circuit on the second side of the textile. Also, the corresponding electronic device and a system including the textile device and the electronic device.

Abstract: A bone conduction speaker includes a housing, a vibration board and a transducer. The transducer is located in the housing, and the vibration board is configured to contact with skin and pass vibration. At least one sound guiding hole is set on at least one portion of the housing to guide sound wave inside the housing to the outside of the housing. The guided sound wave interfaces with the leaked sound wave, and the interfacing reduces a sound pressure level of at least a portion of the leaked sound wave. A frequency of the at least a portion of the leaked sound wave is lower than 4000 Hz.

Abstract: A bone conduction speaker includes a housing, a vibration board and a transducer. The transducer is located in the housing, and the vibration board is configured to contact with skin and pass vibration. At least one sound guiding hole is set on at least one portion of the housing to guide sound wave inside the housing to the outside of the housing. The guided sound wave interfaces with the leaked sound wave, and the interfacing reduces a sound pressure level of at least a portion of the leaked sound wave. A frequency of the at least a portion of the leaked sound wave is lower than 4000 Hz.

Abstract: A mic cord access system (10) is provided in a firefighter coat (14) having a storm flap (12). The system (10) includes a pocket (24) in the coat (14) and configured to enclose a radio (18) carried in an interior of the pocket (24), the pocket (24) including a notch (22) configured to allow a mic cord (16) to extend from the interior of the pocket (24), an opening (27) adjacent the notch (22) and configured to allow a mic cord (16) to extend from the notch (22) to an interior side (32) of the storm flap (12), and an interior mic mount (30) on the interior side (32) of the storm flap (12) and configured to hold a mic (20) with the storm flap (12) in a closed position.

Abstract: A device, to facilitate a user control of a computer system, includes a movable portion movable by a fluid flow of a generated by a user of the device, and a converter to convert movement of the movable portion into an electrical signal to facilitate control of the computer system.

Abstract: A listening device system includes two listening devices, each having its own separate housing. The first device includes an input transducer housed within the housing for converting an input sound to an electrical input signal which includes a direct and an acoustic feedback part, and a feedback cancellation system. The feedback cancellation system includes an adaptive FBC filter including a variable FBC filter part, and an FBC update algorithm part for updating the variable FBC filter part. The FBC update algorithm part receives first and second input signals influenced by the electrical input and the electrical output signals. The second listening device includes an input transducer housed within its housing producing an electrical update signal essentially consisting of the direct part of said electrical input signal. The update signal is conveyed from the second device to the first device, where feedback cancellation parameters are adjusted based on that signal.

Abstract: A multiband dynamics compressor implements a solution for minimizing unwanted changes to the long-term frequency response. The solution essentially proposes undoing the multiband compression in a controlled manner using much slower smoothing times. In this regard, the compensation provided acts more like an equalizer than a compressor. What is applied is a very slowly time-varying, frequency-dependent post-gain (make-up gain) that attempts to restore the smoothed long-term level of each compressor band.

Abstract: Vacuum tubes that receive output signals from microphone units through grids and with which the signals are output as outputs from cathode followers; FETs in cascade connection with the corresponding vacuum tubes and that define currents flowing in the vacuum tubes; and bias circuits that apply a bias voltage to the grids of the corresponding vacuum tubes are included. Pairs of such vacuum tubes, FETs, and fixed bias circuits are each symmetrically connected so that a balanced signal can be output from two cathode followers, and an adjuster is provided between the pair of fixed bias circuits, the adjuster adjusts currents flowing in the pair of vacuum tubes to achieve a balanced output.

Abstract: An impedance converter for a capacitor microphone includes: a vacuum tube that receives an output signal from a capacitor microphone unit through a grid and with which the signal is output as an output from a cathode follower; an FET in cascade connection with the vacuum tube and that defines a current flowing in the vacuum tube; and a bias circuit that applies a bias voltage to the grid of the vacuum tube. The bias circuit includes: a first diode and a second diode that apply the bias voltage to the grid of the vacuum tube; the first diode and the second diode being connected in inverse parallel; and a bias resistor for applying the bias voltage at a constant level to the grid of the vacuum tube via the first diode or the second diode.

Abstract: A system for adapting a hearing aid to a user includes a unit generating an image of the user's ear together with a model of the hearing aid, wherein the model of the hearing aid in-situ includes a physical model of the hearing aid inserted in the user's ear prior to generating the image. The system also generates a mesh based on the image, calculates acoustic response to a simulated acoustic signal in the mesh, calculates a frequency response curve for a fixed position in the mesh, and identifies an optimal position of a microphone of the hearing aid in-situ from the acoustic response. They system also includes a comparator configured to compare the frequency response curve for the fixed position in the mesh with a maximum frequency response curve for the mesh stored by the system.

Abstract: In one aspect, a hearing device is provided with a multi-stage activation circuit including a primary activation unit, an evaluation unit and a main activation unit. The primary activation unit monitors a sound-induced input level and forwards incoming signals to the evaluation unit when a threshold value of the input level is exceeded. The evaluation unit is activated when the threshold value is exceeded and determines a feature of incoming signals suitable for identifying and/or classifying a sound causing the incoming signals. The main activation unit is activated, for example, when the feature determined by the evaluation unit indicates a noise that should be perceptible to the wearer of the hearing device. The main activation unit activates further components of the hearing device including the signal processing and amplification circuit and the output unit.