Abstract: The present disclosure relates to inclusion of a non-contact antenna. The non-contact antenna can allow a variety of antennas to be used on a hearing assistance device and can overcome issues associated with mounting an antenna internal to the case of a heating assistance device. A non-contact antenna may include a proximity coupled antenna, such as an antenna mounted on a hearing assistance device case (external to the case) near a feed line that will transfer energy between the antenna and an SMD internal to the case. A non-contact antenna may include an aperture coupled antenna, such as an antenna mounted external to the case on an antenna substrate, where the antenna substrate is on a feed substrate with a feed line, and where there is an aperture in a ground plane.

Abstract: Multiple antennas at the receiver and/or transmitter are commonly used in wireless communications systems to provide diversity in order reduce fading and other effects brought about by multi-path propagation. Due to the size of hearing aids and the wavelengths of the frequencies used for communication, it is difficult to achieve what is called spatial diversity by disposing the multiple antennas at different locations. Described herein are techniques for providing polarization diversity in hearing aids using antennas with different polarizations and applying the appropriate phase shifts to the received and/or transmitted signals to improve the signal quality.

Abstract: The present disclosure relates to inclusion of a non-contact antenna. The non-contact antenna can allow a variety of antennas to be used on a hearing assistance device and can overcome issues associated with mounting an antenna internal to the case of a hearing assistance device. A non-contact antenna may include a proximity coupled antenna, such as an antenna mounted on a hearing assistance device case (external to the case) near a feed line that will transfer energy between the antenna and an SMD internal to the case. A non-contact antenna may include an aperture coupled antenna, such as an antenna mounted external to the case on an antenna substrate, where the antenna substrate is on a feed substrate with a feed line, and where there is an aperture in a ground plane.

Abstract: Left/Right (L/R) hearing assistance device (HA) symmetrical performance of the antenna is highly desired when using the same HA design for both the left and the right ears. Physical symmetry and loading of the antenna, both internal and external to the HA, is usually not possible because the antenna should avoid the microphone, battery, and switch locations within the HA. Described herein are antenna structures, hearing assistance devices with integrated antennas, and methods of wireless communication in hearing assistance devices which create symmetrical (L/R) antenna performance with physically asymmetrical antenna designs.

Abstract: Multiple antennas at the receiver and/or transmitter are commonly used in wireless communications systems to provide diversity in order reduce fading and other effects brought about by multi-path propagation. Due to the size of hearing aids and the wavelengths of the frequencies used for communication, it is difficult to achieve what is called spatial diversity by disposing the multiple antennas at different locations. Described herein are techniques for providing polarization diversity in hearing aids using antennas with different polarizations and applying the appropriate phase shifts to the received and/or transmitted signals to improve the signal quality.

Abstract: Wireless communication antennas for hearing assistance devices are provided. In various embodiments, a hearing assistance device includes a housing configured to be worn on or behind the ear, hearing assistance electronics enclosed in the housing, an ear mold configured to be worn in the ear, a sound tube configured to connect to the earmold and to transmit an acoustic output to the earmold, and an earhook configured to connect the housing to the sound tube. At least one of the earmold, the sound tube, and the earhook includes a conductive polymer forming at least a portion of an antenna for wireless communication, in various embodiments.

Abstract: The present disclosure relates to inclusion of a non-contact antenna. The non-contact antenna can allow a variety of antennas to be used on a hearing assistance device and can overcome issues associated with mounting an antenna internal to the case of a hearing assistance device. A non-contact antenna may include a proximity coupled antenna, such as an antenna mounted on a hearing assistance device case (external to the case) near a feed line that will transfer energy between the antenna and an SMD internal to the case. A non-contact antenna may include an aperture coupled antenna, such as an antenna mounted external to the case on an antenna substrate, where the antenna substrate is on a feed substrate with a feed line, and where there is an aperture in a ground plane.

Abstract: Left/Right (L/R) hearing assistance device (HA) symmetrical performance of the antenna is highly desired when using the same HA design for both the left and the right ears. Physical symmetry and loading of the antenna, both internal and external to the HA, is usually not possible because the antenna should avoid the microphone, battery, and switch locations within the HA. Described herein are antenna structures, hearing assistance devices with integrated antennas, and methods of wireless communication in hearing assistance devices which create symmetrical (L/R) antenna performance with physically asymmetrical antenna designs.