An implanted microphone is provided that has reduced sensitivity to vibration and attendant acceleration forces to differentiate between desirable and undesirable components of a transcutaneously received signal. More specifically, the microphone utilizes an output that is indicative of acceleration
An implanted microphone is provided that has reduced sensitivity to vibration and attendant acceleration forces to differentiate between desirable and undesirable components of a transcutaneously received signal. More specifically, the microphone utilizes an output that is indicative of acceleration forces acting on the implanted microphone to counteract and/or cancel the effects of acceleration-induced pressures in an output signal of a microphone diaphragm. In one arrangement, a microphone having two diaphragms pneumatically cancels acceleration pressures. In this arrangement, a first diaphragm receives and generates a response to commingled acoustic and acceleration forces and a second diaphragm is substantially isolated from the acoustic forces. That is, the second diaphragm generates a response to acceleration forces. The displacements of the first and second diaphragms are pneumatically combined. The result of such pneumatic combination is that the acoustic component of the first diaphragm is enhanced in a resulting output signal.
대표청구항▼
What is claimed is: 1. An implantable microphone, comprising: an implantable housing; a first diaphragm sealably positioned across a first recessed surface associated with said housing, wherein said first recessed surface and said first diaphragm collectively define a first chamber, and wherein sai
What is claimed is: 1. An implantable microphone, comprising: an implantable housing; a first diaphragm sealably positioned across a first recessed surface associated with said housing, wherein said first recessed surface and said first diaphragm collectively define a first chamber, and wherein said first diaphragm is operative to displace fluid within said first chamber in response to acoustic forces and acceleration forces impinging on said first diaphragm; a second diaphragm sealably positioned across a second recessed surface associated with said housing, said second diaphragm being substantially isolated from acoustic forces within said housing, wherein said second recessed surface and said second diaphragm collectively define a second chamber, and wherein said second diaphragm is operative to displace fluid in said second chamber in response to said acceleration forces acting on said second diaphragm; a conduit pneumatically connecting said first and second chambers, wherein said pneumatic connector is operative to pneumatically sum pressure fluctuations associated with said displaced fluids from said first and second chambers; and an electroacoustic transducer interconnected to said pneumatic connector, for detecting said pressure fluctuations in said pneumatic connector and generating an audio output signal in response thereto, said audio output signal being operative to actuate an actuator of a hearing instrument. 2. The microphone of claim 1, wherein said housing comprises a first aperture extending to said first recessed surface, wherein said first diaphragm is sealably positioned across said first aperture. 3. The microphone of claim 1, wherein said electroacoustic transducer is disposed along a length of said conduit. 4. The microphone of claim 3, wherein said electroacoustic transducer is equidistance from said first and second chambers. 5. The microphone of claim 1, wherein said conduit comprises a first bore interconnected to said first chamber, a second bore interconnected to said second chamber and a third bore interconnected to said electroacoustic transducer. 6. The microphone of claim 5, wherein said conduit comprises a T-shaped conduit. 7. The microphone of claim 1, wherein said first and second diaphragms are like shaped. 8. The microphone of claim 6, wherein a volume of said first and second chambers is substantially equal. 9. The microphone of claim 1, wherein said first and second diaphragms are disposed in a substantially parallel relationship. 10. The microphone of claim 9, wherein said electroacoustic transducer is disposed between said first and second chambers. 11. The microphone of claim 1, wherein said second diaphragm comprises a mass loaded diaphragm. 12. The microphone of claim 11, wherein a mass loading of said second diaphragm is substantially equal to a mass of media overlying said first diaphragm. 13. The microphone of claim 11, wherein the resonant frequencies of said first diaphragm and said second diaphragm are substantially equal. 14. The microphone of claim 11, wherein the resonant frequencies of said first diaphragm and said second diaphragm are below 2000 Hz. 15. The microphone of claim 11, wherein the resonant frequencies of said first diaphragm and said second diaphragm are below 200 Hz. 16. An implantable microphone, comprising: an implantable housing having a first internal chamber with an aperture thereto and a second internal chamber; a first diaphragm sealably positioned across said first aperture wherein said first diaphragm is exposed on an outside surface of said housing; a second diaphragm sealably positioned across the second internal chamber of said housing, wherein said second diaphragm is substantially isolated from acoustic forces within said housing; a conduit pneumatically connecting said first internal chamber and said second internal chamber, wherein said pneumatic connector pneumatically sums pressure fluctuations associated with displaced fluids from said first and second internal chambers; and at least one electroacoustic transducer operatively interconnected to said conduit, wherein said at least one electroacoustic transducer generates an audio output signal in response to said pressure fluctuations within said conduit, said audio output signal being operative to actuate an actuator of a hearing instrument. 17. The microphone of claim 16, wherein said first diaphragm is operative to move relative to said first internal chamber in response to an acoustic force and an acceleration force present in a media overlying said first diaphragm. 18. The microphone of claim 17, wherein said second diaphragm is operative to move relative to said second internal chamber in response to said acceleration force acting on said housing. 19. The microphone of claim 18, wherein said first and second diaphragms displace substantially equal and opposite volumes of fluid in response to acceleration forces. 20. The microphone of claim 18, wherein said output signal corresponds to said acoustic force. 21. The microphone of claim 16, wherein said second diaphragm comprises a mass loaded diaphragm. 22. The microphone of claim 16, wherein said first and second diaphragms are like shaped. 23. The microphone of claim 16, wherein a volume of said first and second chambers is substantially equal. 24. The microphone of claim 16, wherein said first and second diaphragms are disposed in a substantially parallel relationship. 25. The microphone of claim 24, wherein said electroacoustic transducer is disposed between said first and second internal chambers. 26. The microphone of claim 16, wherein said conduit comprises a first bore interconnected to said first internal chamber, a second bore interconnected to said second internal chamber and a third bore interconnected to said electroacoustic transducer. 27. The microphone of claim 26, wherein said conduit comprises a T-shaped conduit. 28. A method for use in an implantable microphone, comprising: displacing a first fluid volume in response to a transcutaneously received pressure signal at said implantable microphone, wherein said transcutaneously received pressure signal includes an acoustic component and an acceleration component; in conjunction with said displacing said first fluid volume, displacing a second fluid volume in response to an acceleration force acting on said implantable microphone; pneumatically summing said first and second fluid volumes at said implantable microphone to generate a resultant pressure; monitoring said resultant pressure to generate an audio output signal for use in actuating an actuator of a hearing instrument. 29. Said method of claim 28, wherein an acceleration component of said audio output signal is less than said acceleration component of said transcutaneously received pressure signal. 30. Said method of claim 28, wherein pneumatically summing comprises: receiving said first and second fluid volumes in a pneumatic connector extending between first and second chambers of an implantable microphone. 31. Said method of claim 30, wherein monitoring said resultant pressure comprises monitoring pressure fluctuations in said pneumatic connector. 32. Said method of claim 28, wherein said displacing said first fluid volume comprises: displacing a first diaphragm exposed to an outside surface of said housing of said implantable microphone. 33. Said method of claim 32, wherein said displacing said second fluid volume comprises: displacing a second diaphragm that is isolated form an outside surface of said housing, wherein said second diaphragm is substantially isolated from said acoustic component of said transcutaneously received signal.
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