Abstract: Adhesive pad (10) for retaining an electrode against a patient's skin. The pad (10) includes an adhesive gel layer (16) for adhering to the skin, and a non-adhesive layer (18) carrying the gel layer (16). The gel layer (16) is configured to be water-soluble and define a non-tacky external shell. Methods for producing an adhesive pad for adhering to a patients skin, and tools for pressing an adhesive pad to a patients skin, are also disclosed.

Abstract: A capacitive test apparatus for testing an electronic device contained within a package, the apparatus comprising: a plurality of conductive pads in electrical communication with the processor, wherein the plurality of conductive pads are configured to align with electrodes of the electronic device during testing and capacitively couple electrical stimuli to the electrodes via the package; processing circuitry configured to: apply the electrical stimuli to the plurality of conductive pads; receive one or more response signals induced by the electrical stimuli coupled through the package; and determine one or more electrical characteristics of the electronic device based on the one or more response signals.

Abstract: Electrode array assembly (10) including a carrier assembly (12) and a connector assembly (14). The carrier assembly (12) includes an array of first electrical contacts (20) coupled to a plurality of electrodes (18), and a first housing (22) canying the array of first contacts (20) and configured to allow access to the first contacts (20). The connector assembly (14) includes an array of second electrical contacts (26), and a second housing (28) canying the second contacts (26) and configured to allow access to the second contacts (26). Each of the carrier assembly (12) and the connector assembly (14) include complementary retention elements (30) and complementary locating formations (32), whereby engaging the complementary locating formations (32) allows the complementary retention elements (30) to secure the first housing (22) to the second housing (28), and allows the first contacts (20) to couple with the second contacts (26).

Abstract: Technology presented herein increases a user's enjoyment of sound by personalizing an audio signal so that the user perceives the audio signal as if the user had ideal hearing and/or desired hearing. In one embodiment, headphones on a user's head include a sensor and a speaker. While the speaker plays an audio signal to the user, the sensor records the user's response to the audio signal. The sensor can be a microphone, a brainwave sensor, an EEG sensor, etc. The user's response can be the audio response inside the user's ear, the brainwave response associated with the user, electrical skin response associated with the user, etc. Based on the measured response, and based on the knowledge of how other people perceive sound, the audio signal is modified to compensate for the difference between the user's hearing and the ideal hearing and/or desired hearing, therefore increasing the user's enjoyment of sound.

Abstract: Technology presented herein improves the comfort of over ear headphones by reducing over ear heat and therefore sweat via an active ventilation mechanism. Headphones include two or more one-way valves: one valve at the bottom of the cup allowing air to flow in, and another valve at the top of the earcup allowing air to flow out of the earcup. In the audible frequency range the valves have high acoustic impedance in both directions to prevent the sound from escaping from the earcup into the environment. In the inaudible frequency range the valves operate as an upward pump because the upward direction has low impedance and the downward direction has high impedance. The pumping action is further aided by the natural tendency of warm air to rise, and by the speaker creating positive and negative pressure within the earcup and therefore expelling or sucking in air, respectively.

Abstract: Presented here is an apparatus and method to increase a listener's enjoyment of sound by combining in-ear headphones with either over-ear headphones or on-ear headphones. One embodiment is headphones that include an ear-cup with an ear-bud protruding toward the listener's ear-canal. The ear-cup substantially surrounds the listener's ear and delivers sub sonic and low-frequency vibrations to the listener's skin stimulating a vibrotactile response. The ear-bud is disposed within the listener's ear canal and delivers a full range of audible frequencies. Additionally, the headphones, along with the ear-cup in the ear-bud, provide both passive and active noise cancellation.

Abstract: Presented here is an apparatus and method to increase a listener's enjoyment of sound by combining in-ear headphones with either over-ear headphones or on-ear headphones. One embodiment is headphones that include an ear-cup with an ear-bud protruding toward the listener's ear-canal. The ear-cup substantially surrounds the listener's ear and delivers sub sonic and low-frequency vibrations to the listener's skin stimulating a vibrotactile response. The ear-bud is disposed within the listener's ear canal and delivers a full range of audible frequencies. Additionally, the headphones, along with the ear-cup in the ear-bud, provide both passive and active noise cancellation.

Abstract: Technology presented herein increases a user's enjoyment of sound by personalizing an audio signal so that the user perceives the audio signal as if the user had ideal hearing and/or desired hearing. In one embodiment, headphones on a user's head include a sensor and a speaker. While the speaker plays an audio signal to the user, the sensor records the user's response to the audio signal. The sensor can be a microphone, a brainwave sensor, an EEG sensor, etc. The user's response can be the audio response inside the user's ear, the brainwave response associated with the user, electrical skin response associated with the user, etc. Based on the measured response, and based on the knowledge of how other people perceive sound, the audio signal is modified to compensate for the difference between the user's hearing and the ideal hearing and/or desired hearing, therefore increasing the user's enjoyment of sound.

Abstract: Technology presented herein increases a user's enjoyment of sound by personalizing an audio signal so that the user perceives the audio signal as if the user had ideal hearing and/or desired hearing. In one embodiment, headphones on a user's head include a sensor and a speaker. While the speaker plays an audio signal to the user, the sensor records the user's response to the audio signal. The sensor can be a microphone, a brainwave sensor, an EEG sensor, etc. The user's response can be the audio response inside the user's ear, the brainwave response associated with the user, electrical skin response associated with the user, etc. Based on the measured response, and based on the knowledge of how other people perceive sound, the audio signal is modified to compensate for the difference between the user's hearing and the ideal hearing and/or desired hearing, therefore increasing the user's enjoyment of sound.

Abstract: Technology presented herein improves the comfort of over ear headphones by reducing over ear heat and therefore sweat via an active ventilation mechanism. Headphones include two or more one-way valves: one valve at the bottom of the cup allowing air to flow in, and another valve at the top of the earcup allowing air to flow out of the earcup. In the audible frequency range the valves have high acoustic impedance in both directions to prevent the sound from escaping from the earcup into the environment. In the inaudible frequency range the valves operate as an upward pump because the upward direction has low impedance and the downward direction has high impedance. The pumping action is further aided by the natural tendency of warm air to rise, and by the speaker creating positive and negative pressure within the earcup and therefore expelling or sucking in air, respectively.

Abstract: Technology presented herein increases a user's enjoyment of sound by personalizing an audio signal so that the user perceives the audio signal as if the user had ideal hearing and/or desired hearing. In one embodiment, headphones on a user's head include a sensor and a speaker. While the speaker plays an audio signal to the user, the sensor records the user's response to the audio signal. The sensor can be a microphone, a brainwave sensor, an EEG sensor, etc. The user's response can be the audio response inside the user's ear, the brainwave response associated with the user, electrical skin response associated with the user, etc. Based on the measured response, and based on the knowledge of how other people perceive sound, the audio signal is modified to compensate for the difference between the user's hearing and the ideal hearing and/or desired hearing, therefore increasing the user's enjoyment of sound.

Abstract: Technology presented herein increases a user's enjoyment of sound by personalizing an audio signal so that the user perceives the audio signal as if the user had ideal hearing and/or desired hearing. In one embodiment, headphones on a user's head include a sensor and a speaker. While the speaker plays an audio signal to the user, the sensor records the user's response to the audio signal. The sensor can be a microphone, a brainwave sensor, an EEG sensor, etc. The user's response can be the audio response inside the user's ear, the brainwave response associated with the user, electrical skin response associated with the user, etc. Based on the measured response, and based on the knowledge of how other people perceive sound, the audio signal is modified to compensate for the difference between the user's hearing and the ideal hearing and/or desired hearing, therefore increasing the user's enjoyment of sound.

Abstract: Presented here is an apparatus and method to increase a listener's enjoyment of sound by combining in-ear headphones with either over-ear headphones or on-ear headphones. One embodiment is headphones that include an ear-cup with an ear-bud protruding toward the listener's ear-canal. The ear-cup substantially surrounds the listener's ear and delivers sub sonic and low-frequency vibrations to the listener's skin stimulating a vibrotactile response. The ear-bud is disposed within the listener's ear canal and delivers a full range of audible frequencies. Additionally, the headphones, along with the ear-cup in the ear-bud, provide both passive and active noise cancellation.

Abstract: Technology presented herein increases a user's enjoyment of sound by personalizing an audio signal so that the user perceives the audio signal as if the user had ideal hearing and/or desired hearing. In one embodiment, headphones on a user's head include a sensor and a speaker. While the speaker plays an audio signal to the user, the sensor records the user's response to the audio signal. The sensor can be a microphone, a brainwave sensor, an EEG sensor, etc. The user's response can be the audio response inside the user's ear, the brainwave response associated with the user, electrical skin response associated with the user, etc. Based on the measured response, and based on the knowledge of how other people perceive sound, the audio signal is modified to compensate for the difference between the user's hearing and the ideal hearing and/or desired hearing, therefore increasing the user's enjoyment of sound.

Abstract: Technology presented herein increases a user's enjoyment of sound by personalizing an audio signal so that the user perceives the audio signal as if the user had ideal hearing and/or desired hearing. In one embodiment, headphones on a user's head include a sensor and a speaker. While the speaker plays an audio signal to the user, the sensor records the user's response to the audio signal. The sensor can be a microphone, a brainwave sensor, an EEG sensor, etc. The user's response can be the audio response inside the user's ear, the brainwave response associated with the user, electrical skin response associated with the user, etc. Based on the measured response, and based on the knowledge of how other people perceive sound, the audio signal is modified to compensate for the difference between the user's hearing and the ideal hearing and/or desired hearing, therefore increasing the user's enjoyment of sound.

Abstract: Visual prosthesis apparatus includes an image receiver, a processor coupled to the image receiver, a stimulation device coupled to the processor, and an eye monitoring device coupled to the processor. The image receiver receives a sequence of images and the processor produces a stimulation signal at least partially in accordance with the received images. The stimulation device receives the stimulation signal and stimulates visual neurons of a user accordingly to provide the user with a visual percept. The eye monitoring device monitors one or more ocular parameters at an eye region of the user, wherein one or more control functions are associated with the monitored ocular parameters. The processor controls the visual prosthesis apparatus in accordance with the monitored ocular parameters and the associated control functions. The one or more ocular parameters can include pupil size, state of closure of the user's eyelid and direction of eye gaze.

Abstract: Visual prosthesis apparatus includes an image receiver, a processor coupled to the image receiver, a stimulation device coupled to the processor, and an eye monitoring device coupled to the processor. The image receiver receives a sequence of images and the processor produces a stimulation signal at least partially in accordance with the received images. The stimulation device receives the stimulation signal and stimulates visual neurons of a user accordingly to provide the user with a visual percept. The eye monitoring device monitors one or more ocular parameters at an eye region of the user, wherein one or more control functions are associated with the monitored ocular parameters. The processor controls the visual prosthesis apparatus in accordance with the monitored ocular parameters and the associated control functions. The one or more ocular parameters can include pupil size, state of closure of the user's eyelid and direction of eye gaze.