A hearing aid service system includes a personal communication device (13) acting as a gateway for one or more hearing aids (10, 11) to a remote server (25) accessible via the Internet. The hearing aids (10, 11) have a processor (121) monitoring electrical hearing aid parameters for detecting a change indicating a replacement of a hearing aid component (132; 140), and report the hearing aid component replacement to the remote server (25). The remote server (25) is tracking the consumption of hearing aid components for individual user accounts and identifies a priority item for sale depending on recorded consumption. The priority item for sale is displayed on the hearing aid control application software interface on the personal communication device (13). The remote server (25) completes the transaction based on data stored in the user account. The invention further provides a method for maintenance of a hearing aid.

A system for monitoring the status and/or performance of one or more hearing devices is disclosed. The system comprises a number of access points configured to receive wireless signals transmitted by the hearing devices, wherein the access points are connected to a central unit communicatively connected to the Internet/cloud, wherein the system is configured to automatically monitor the status and/or performance of one or more parameter of the one or more hearing devices received by access points, wherein the monitored parameters are accessible from the central unit and/or from a cloud service.

The present invention regards a communication system (10; 10a; 10b; 10c) comprising at least one communication device (36, 36a, 36b, 36c) configured to connect to other communication devices (36, 36a, 36b, 36c) via an audio and data link (52). The communication device (36, 36a, 36b, 36c) comprises at least a receiver unit (40), an output transducer (32), a microphone (22, 22′), a transmitter unit (42), and a control unit (38). The receiver unit (40) is adapted to receive audio signals and data signals via the audio and data link (52). The output transducer (32) is adapted to stimulate the hearing of the user (12, 20, 30) according to the audio signals received via the audio and data link (52). The microphone (22, 22′) is adapted to receive input sound (44) and generate an audio signal from the received input sound (44). The transmitter unit (42) is adapted to transmit audio signals and data signals via the audio and data link (52). The control unit (38) is connected to the receiver unit (40), to the output transducer (32), to the microphone (22, 22′), and to the transmitter unit (42). The control unit (38) is adapted to control the signal transmission between the receiver unit (40), the output transducer (32), the microphone (22, 22′), and the transmitter unit (42). The control unit (38) is further adapted to generate a data signal corresponding to the communication device (36, 36a, 36b, 36c) for identifying the communication device (36, 36a, 36b, 36c). And the control unit (38) comprises a processor (46) which is adapted to process audio signals and data signals. The communication device (36, 36a, 36b, 36c) is connectable to an attachable digital receiver (26) via the audio and data link (52). The attachable digital receiver (26) has a shape that matches a shape of a hearing aid (28) in order to be attached to the hearing aid (28). The communication devices (36, 36a, 36b, 36c) of the communication system (10; 10a; 10b; 10c) can be Smartphones.

A portable hearing assistance device comprises an input unit, an output unit, a forward path between the input unit and the output unit, and an energy source for energizing components of the hearing assistance device. The hearing assistance device further comprises a control unit to control activation (or deactivation) of a low-power mode of operation of the hearing assistance device. When the low-power mode is activated—the draw of current from said energy source is reduced compared to a normal mode of operation of the device, the activation (or deactivation) being influenced by a combination of at least two different control input signals to the control unit, each control input signal being a signal selected from 1) signals relating to current physical environment, 2) signals relating to current acoustic environment, 3) signals relating to current wearer state, and 4) signals relating to current state or operation mode.

Disclosed in some examples are devices, methods, systems, and machine readable media that reduce the burden of a master device of a second wireless connection by utilizing the channel map of a first wireless connection. Since both the first and second wireless connections are located at nearly the same location, the “good channels” are very similar for both connections. Therefore a second wireless connection may take advantage of the channel assessment conducted by a first wireless connection in identifying channels by using one or more channels of the first wireless connection for communications in the second wireless connection.

A method (500) of testing microphone performance of a hearing aid system, based on a determined correspondence between a hearing aid microphone signal and a test signal provided by the hearing aid system, as well as a hearing aid system adapted to carry out such a method.

A system comprising a remotely programmable micromonitor with a wireless sensing system-on-module (SOM), one or more sensors to detect one or more conditions in a subject by monitoring one or more parameters associated with the conditions by comparing any monitored parameter to a baseline measurement of the monitored parameter from the subject, a plurality of sensors corresponding to a monitored parameter and connected to the micromonitor to convey measurements of all monitored parameters, the sensors including at least one of a non-optical pulse wave sensor or an electrocardiogram (ECG) sensor, a communications module capable of communicating with a wireless technology, wherein the module can send an alert signal to the subject or an attending physician or a remote service center or any other subject, and one or more algorithms for monitoring conditions and/or for predicting conditions, including at least one of a fall detection or fall prediction algorithm.

A hearing aid for placement in an ear canal of a user, includes: a shell; a faceplate comprising an upper face, and a lower face, and a circumference, the upper face being exposed when the shell is placed in an ear of the user; a coil arranged at the faceplate; and a button arrangement comprising a plunger configured to control an integrated circuit arranged below the coil, the coil comprising one or more windings, the one or more windings being circumferential of an inner cavity of the coil with respect to a center or longitudinal axis of the coil, the button arrangement being configured such that the plunger in at least one position extends through the inner cavity of the coil for engaging the integrated circuit.

A hearing device includes: a processing unit configured to compensate for hearing loss of a user of the hearing device; a memory unit; and an interface; wherein the processing unit is configured to obtain one or more security settings via the interface, the one or more security settings comprising a hearing device key identifier, verify the one or more security settings, and update the hearing device based on the one or more security settings if the one or more security settings are verified

Real time, remote access to and adjustment of the hearing aid of a patient while the patient is located in a normal life environment that is remote from a hearing professional. A session request initiates a programming session. Adjustable settings from the patient's hearing aid are wirelessly streamed to the patient's mobile device and from the mobile device to a streaming cloud server. The settings are stored on the cloud, streamed from the cloud to a hearing professional's computer or mobile device and displayed. The hearing professional then changes at least one of the adjustable hearing aid settings and the changed settings are streamed to the cloud, stored on the cloud, streamed from the cloud to the patient's mobile device, wirelessly transmitted to the hearing aid and stored there. A telephonic voice connection between the hearing professional and the patient's mobile device is used to transmit the patient's evaluation of changed settings to the hearing professional.