Abstract: A bone conduction device, including a transducer and a housing, wherein the housing is directly flexibly connected to the transducer at a dynamic component of the bone conduction device and directly flexibly connected to a static component of the bone conduction device. In an exemplary embodiment, the bone conduction device is a percutaneous bone conduction device.

Abstract: A bone conduction device, including a transducer and a housing, wherein the housing is directly flexibly connected to the transducer at a dynamic component of the bone conduction device and directly flexibly connected to a static component of the bone conduction device. In an exemplary embodiment, the bone conduction device is a percutaneous bone conduction device.

Abstract: A bone conduction device, including a transducer and a housing, wherein the housing is directly flexibly connected to the transducer at a dynamic component of the bone conduction device and directly flexibly connected to a static component of the bone conduction device. In an exemplary embodiment, the bone conduction device is a percutaneous bone conduction device.

Abstract: Presented herein are techniques for acoustically charging an implantable rechargeable battery. In accordance with embodiments presented herein, a sound sensor is implanted in a recipient and is configured to detect sound signals. The sound sensor is configured to convert the detected sound signals into electrical signals that can be used to charge the implantable rechargeable battery.

Abstract: An implantable component, such as that utilized for a bone conduction device, the implantable component including a housing and a piezoelectric transducer, wherein the implantable component is configured to prevent the piezoelectric transducer from moving inside the housing. The implantable component can be configured to temporarily prevent the piezoelectric transducer from moving inside the housing.

Abstract: An external portion of an auditory prosthesis includes magnets, electronics, and other components. In bone conduction auditory prostheses, reducing the amount of mass subject to vibrations in an auditory prosthesis has a positive effect on tuning of the device. One way of reducing such mass is to resiliently more massive components within the auditory prosthesis housing. Such resilient mounting reduces the dampening effect that these massive components have on vibrations generated by the prosthesis. When electronic components are suspended, feedback to said components is also reduced, resulting improved performance.

Abstract: Presented herein are techniques for acoustically charging an implantable rechargeable battery. In accordance with embodiments presented herein, a sound sensor is implanted in a recipient and is configured to detect sound signals. The sound sensor is configured to convert the detected sound signals into electrical signals that can be used to charge the implantable rechargeable battery.

Abstract: In bone conduction auditory prostheses, a suspension of the electronic components relative to the vibrating mass is beneficial for a number of reasons. The suspension systems depicted also function as a seal, so as to prevent infiltration of direct, water, or other contaminants into the housing. The present technology utilizes a combination suspension and sealing system that seals the housing of an auditory prosthesis while still providing sufficient suspension functionality.

Abstract: An implantable component, such as that utilized for a bone conduction device, the implantable component including a housing and a piezoelectric transducer, wherein the implantable component is configured to prevent the piezoelectric transducer from moving inside the housing. The implantable component can be configured to temporarily prevent the piezoelectric transducer from moving inside the housing.

Abstract: In bone conduction auditory prostheses, a suspension of the electronic components relative to the vibrating mass is beneficial for a number of reasons. The suspension systems depicted also function as a seal, so as to prevent infiltration of direct, water, or other contaminants into the housing. The present technology utilizes a combination suspension and sealing system that seals the housing of an auditory prosthesis while still providing sufficient suspension functionality.

Abstract: An external portion of an auditory prosthesis includes magnets, electronics, and other components. In bone conduction auditory prostheses, reducing the amount of mass subject to vibrations in an auditory prosthesis has a positive effect on tuning of the device. One way of reducing such mass is to resiliently more massive components within the auditory prosthesis housing. Such resilient mounting reduces the dampening effect that these massive components have on vibrations generated by the prosthesis. When electronic components are suspended, feedback to said components is also reduced, resulting improved performance.