The invention discloses a parametric system for testing a capability of auditory spatial positioning and a method of providing a parametric minimum audible angle. The system includes: an host computer system calculating spatial movement data and communicating with a slave computer; a spatial movement system realizing control of any spatial position through circumferential movement, radial movement and vertical movement; a real-time three-dimensional display system built into the host computer system; an audio system randomly generates a type of audio data of a sound source and a sound source with equal-difference decibels; and a test system for matching human spatial positioning results to sound source spatial data and providing an objective evaluation. The invention further provides a method of providing a parametric minimum audible angle for a capability of auditory spatial positioning, the invention improves the control accuracy.

Systems and methods are described for performing diagnostic procedures, such as vibrometric diagnostic procedures. An example system includes a handheld vibrometric device, a handheld controller, and a control and processing console. The handheld controller includes an input receiving mechanism for controlling the handheld vibrometric device and/or controlling a user interface generated by the console. The handheld controller is configured such that when the handheld vibrometric diagnostic device is supported by a first hand of an operator and the handheld controller is supported by a second hand of the operator, the input receiving mechanism is capable of being actuated by a digit of the second hand while maintaining support of the handheld controller by the second hand, in the absence of contact with the control and processing console and the handheld vibrometric diagnostic device, thereby facilitating control of the handheld vibrometric diagnostic device without mechanically perturbing the handheld vibrometric diagnostic device.

An apparatus and method for hearing analysis including a frequency setting part for setting a predetermined frequency at which there is a possibility of tinnitus of the subject; a signal generation part generates a pure tone signal of the set frequency and increase or decrease the level of the generated pure tone signal, and generates a complex tone signal including the frequency of the pure tone signal and increase or decrease a level of the generated complex tone signal; and a hearing analysis part to analyze hearing by using a pure tone recognition information and a complex tone recognition information of the subject obtained in reaction to the pure tone signal and the complex tone signal generated by the signal generation part. As a result, the apparatus and method can accurately determine the tinnitus region and also provide information from which point of the sound path the tinnitus originates.

Disclosed herein are examples of methods and systems for performing a calibration check of a personal hearing test system using a built-in calibration cavity, particularly for use by a non-expert user outside the clinical environment. The hearing test system includes a one or more earpieces. The hearing test system further includes a portable test unit having an acoustic calibration cavity for accommodating the earpiece at least partially therein. The acoustic calibration cavity may include an opening along an exterior surface of the portable test unit. The acoustic calibration cavity receives an acoustic calibration stimuli and the microphone provided within the acoustic calibration cavity produces a calibration signal input for measuring and performing a calibration check, or an automatic self-calibration.

A method of reversing hearing loss using a therapy stimulator machine that includes a first and second handheld probe electrode; using the hand held probe electrodes with water to apply pressure to locations and at the same time wiggle the probe electrodes around the patient's ear to stimulate hearing loss reversal. Simultaneously an isolated sound source is applied to the side of the ear under treatment so patient would be able to appreciate the improvement in the hearing capability instantly.

The present disclosure generally relates to techniques and user interfaces for interacting with research studies. In some embodiments, an electronic device displays a user interface that includes a task view with active tasks from multiple research studies. In some embodiments, an electronic device, while displaying a research study user interface, displays an indication of a problem that prevents enrollment in the research study when enrollment problem criteria are met. In some embodiments, an electronic device, while performing a hearing test, suspends the test and displays a restart affordance when the ambient noise level exceeds a threshold.

Embodiments herein disclose a method and electronic device for personalized audio enhancement. The method includes: receiving, by the electronic device, a plurality of inputs, in response to an audiogram test. The method includes generating, by the electronic device, a first audiogram representative of a first personalized audio setting to suit a first ambient context, based on the received inputs. The method also includes determining a change from the first ambient context to a second ambient context for an audio playback, analyzing a plurality of contextual parameters during the audio playback in the second ambient context, and generating a second audiogram representative of a second personalised audio setting to suit the second ambient context based on the analysis of the plurality of contextual parameters, by the electronic device.

An audiometric testing headband includes a strap, an anchor, an adult male sizing point, an adult female sizing point, a child sizing point, and an infant sizing point. The anchor is a first type of fastener on a first end of the strap. The sizing points are on the strap and a second type of fastener that mates with the anchor. The adult male sizing point is on a second end of the strap a first distance from the anchor. The adult female sizing point is a second distance from anchor. The child sizing point is a third distance from the anchor. The infant sizing point is a fourth distance from the anchor. Each distance is between a center of the anchor and a center of each respective sizing point.

The present invention provides a computer-implanted method and system for diagnosing sudden sensorineural hearing loss (SSNHL) of an ear in a subject; comprising on one or more processors of the computer the steps of: testing the hearing of two ears of the subject, and calculating the difference between them; and comparing the difference with a threshold to diagnose the subject as SSNHL or not.

A system and method for automatically and dynamically controlling the output (e.g., volume) of an audio headphone device is disclosed, which includes detecting the invocation of the acoustic reflex with an audio headphone device. The disclosed system can measure the response of the tympanic membrane and middle ear to various SPL and frequencies. That information may be used for automated or customized warning or limiting levels either within the headphone, or at the audio playback device.