Implant evaluation using acoustic emissions

We claim: 1. A method of identifying a loosened implant in a joint, the method comprising the steps of: positioning a plurality of acoustic sensors at a respective plurality of locations around the joint, causing the joint to be moved, receiving signals from the acoustic sensors during the movement of the joint, identifying signals from two or more of the plurality of acoustic sensors that correspond to a common acoustic event, identifying a position of the acoustic event within the joint, and providing a health indication related to the joint, wherein the step of identifying a position comprises: calculating a first time delay between a first time of receipt of a first signal from a first acoustic sensor of the plurality of acoustic sensors and a second time of receipt of a second signal from a second acoustic sensor of the plurality of acoustic sensors, and calculating a first geometric surface of possible locations of the acoustic event from the first time delay. 2. The method of claim 1 , wherein the step of identifying a position further comprises: calculating a second time delay between the first time of receipt and a third time of receipt of a third signal from a third acoustic sensor of the plurality of acoustic sensors, calculating a second geometric surface of possible locations of the acoustic event from the second time delay, and determining a line of intersection of the first and second geometric surfaces. 3. The method of claim 1 , wherein the step of identifying a position further comprises determining where the first geometric surface intersects the implant. 4. The method of claim 1 , wherein the step of calculating a first time delay comprises: identifying one or more types of tissue between the implant and the first acoustic sensor, identifying one or more signal paths from the implant to the first acoustic sensor, and adjusting the first time delay according to predetermined speeds of signal propagation within each of the one or more types of tissue and the signal paths. 5. The method of claim 4 , further comprising: adjusting the first time delay according to predetermined speeds of signal propagation within each of the one or more types of tissue and the signal paths. 6. The method of claim 1 , wherein the step of identifying a position comprises: calculating a first magnitude difference between a first signal amplitude of a first signal from a first acoustic sensor of the plurality of acoustic sensors and a second signal magnitude of a second signal from a second acoustic sensor of the plurality of acoustic sensors, and calculating a first geometric surface of possible locations of the acoustic event from the first amplitude difference. 7. A method of identifying a loosened implant in a joint, the method comprising the steps of: positioning an acoustic sensor at a location proximate to the joint, causing the joint to be moved, receiving a signal from the acoustic sensor during the movement of the joint, analyzing the signal to identify an attribute that is associated with a state of joint health, and providing a health indication related to the joint, wherein the step of analyzing the signal is performed only when the signal comprises a primary frequency within a predetermined band. 8. The method of claim 7 , wherein the predetermined band is associated with the implant. 9. A method of identifying a loosened implant in a joint, the method comprising the steps of: positioning an acoustic sensor at a location proximate to the joint, causing the joint to be moved, receiving a signal from the acoustic sensor during the movement of the joint, analyzing the signal to identify an attribute that is associated with a state of joint health, and providing a health indication related to the joint wherein the step of analyzing the signal comprises: calculating a power spectral density (PSD) of the signal, calculating a first partial power of the PSD within a predetermined first frequency band, comparing the first partial power to a first threshold, and determining that the signal is indicative of a loose implant when the first partial power exceeds the first threshold. 10. The method of claim 9 , wherein the predetermined band includes a resonant frequency associated with the implant. 11. A method of identifying a loosened implant in a joint, the method comprising the steps of: positioning an acoustic sensor at a location proximate to the joint, causing the joint to be moved, receiving a signal from the acoustic sensor during the movement of the joint, analyzing the signal to identify an attribute that is associated with a state of joint health, and providing a health indication related to the joint wherein the step of analyzing the signal comprises: calculating a power spectral density (PSD) of the signal, calculating a first partial power of the PSD within a predetermined first frequency band, calculating a second partial power of the PSD within a predetermined second frequency band, and comparing the first partial power to the second partial power. 12. The method of claim 11 , wherein the step of comparing comprises: calculating a ratio of the first partial power to the second partial power, and determining that the signal is indicative of a loose implant when the ratio exceeds a threshold. 13. The method of claim 11 , wherein the step of comparing comprises: calculating a difference between the first partial power and the second partial power, and determining that the signal is indicative of a loose implant is loose when the difference exceeds a threshold. 14. A method of identifying a loosened implant in a joint, the method comprising the steps of: positioning an acoustic sensor at a location proximate to the joint, causing the joint to be moved, receiving a signal from the acoustic sensor during the movement of the joint, analyzing the signal to identify an attribute that is associated with a state of joint health, and providing a health indication related to the joint wherein the step of analyzing the signal comprises: calculating a power spectral density (P SD) of the signal, calculating a first maximum value of the PSD within a predetermined first frequency band, calculating a second maximum value of the PSD within a predetermined second frequency band, and comparing the first maximum value to the second maximum value.