A consumer electronics device is arranged for outputting a hearing loss compensated signal. The consumer electronics device comprises an operating system whereon at least one application can be run that yields a sound output signal. Wherein the consumer electronics device further comprises: a first software module adapted for rerouting the sound output signal, and a second software module adapted for receiving from the first software module the rerouted sound output signal, for performing hearing loss compensation on the rerouted sound output signal and for outputting the hearing loss compensated signal.

The invention discloses an earphone device comprising a first case, a first speaker unit, a first recording unit, and a second recording unit. The first speaker unit, disposed inside the first case, emits a first testing sound signal according to a test command. The first recording unit, disposed inside the first case, records a first environment sound signal according to a record command or a noise cancelling command. The second recording unit, disposed inside the first case, records a first feedback sound signal, related to the first testing sound signal, according to the test command.

A system and processes for a proximate-speaker audio compensation system include a first speaker and a second speaker that are proximate to a user. A control unit couples to at least one of the first speaker or the second speaker. The control unit adjusts audio signal based on a hearing-aid type adjustment. The control unit sends adjusted audio signal to the at least one of the first speaker or the second speaker.

An earpiece for reproducing audio has multiple drivers, including a bone conduction bass driver and an air conduction treble driver, attached to the ends of a malleable, yet stiff, tubing. The bass driver is placed behind or over the ear to provide a high quality bass output while the treble driver is placed so as to extend in proximity to the user's ear canal. The malleable, yet stiff, tubing enables a user to bend the earpiece and thereby position the earpiece comfortably and securely around the user's ear and to optimally position the drivers in the desired positions around the user's ear. The tubing also allows the earpiece, when not in use, to be reshaped for easy storage or to be worn as an accessory. The earpiece may also include one or more microphones with the treble and/or bass drivers.

At least one exemplary embodiment is directed to a method of determining hearing loss using audio cues whose spectrum is orthogonal to each other to identify a wearer's hearing loss, and using the information to adjust audio to normal listening levels.

Signal to noise ratio, SNR, is determined in an acoustic ambient environment of an against-the-ear audio device worn by a user, wherein the acoustic ambient environment contains speech by a talker. When the SNR is above a threshold, dynamic range control is applied, as positive gain versus input level, to an audio signal from one or more microphones of the audio device. When the SNR is below the threshold, the dynamic range control applies as zero gain or negative gain to the audio signal. Other aspects are also described and claimed.

An audio circuit with an integral hearing test is disclosed. The circuit includes at least one variable gain amplifier (VGA) coupled to receive an audio signal and a plurality of filters. Each filter is coupled to the at least one VGA and configured to filter an output signal from the at least one VGA. A processor is coupled to the VGAs and configured to apply a selected frequency to the at least one VGA in a test mode and to control a gain of the at least one VGA in a normal mode.

An audio signal control apparatus includes a sound input circuit, a sound output circuit, and a control circuit. The sound input circuit is configured to receive an ambient sound signal from a microphone that captures ambient sound. The sound output circuit is configured to generate an output sound signal and transmit the output sound signal to a speaker to generate sound based on the output sound signal. The control circuit is configured to determine characteristics of the ambient sound based on the ambient sound signal received by the sound input circuit, determine a frequency band of the sound to be generated by the speaker based on the characteristics of the ambient sound, and control the sound output circuit to generate an output sound signal corresponding to the sound of the determined frequency band.

A sound outputting apparatus which includes a communicator to communicate with an electronic apparatus and receive first audio data, an output module to output the first audio data received, and to output second audio data, which is modified data of the first audio data, a sensor to detect brainwave data of a user, and a processor to control so that the brainwave data of the user detected through the sensor is transmitted to the electronic apparatus through the communicator, and so that the second audio data is received from the electronic apparatus.

At least one exemplary embodiment is directed to a method of determining hearing loss using audio cues whose spectrum is orthogonal to each other to identify a wearer's hearing loss, and using the information to adjust audio to normal listening levels.