Anchor tracking for MEMS accelerometers

What is claimed is: 1. A micro electro-mechanical system (MEMS) accelerometer, comprising: at least one anchor coupled to a substrate; a proof mass connected to the at least one anchor; and a counter-balance mass connected to the proof mass and to the at least one anchor, wherein, in response to an acceleration of the MEMS accelerometer in a first direction, the proof mass is configured to move in the first direction and the counter-balance mass is configured to move in a second direction opposite from the first direction, and wherein, in response to displacement of the at least one anchor in the first direction, the proof mass and the counter-balance mass are configured to move in the first direction. 2. The MEMS accelerometer of claim 1 , further comprising: a sense capacitor comprising a fixed electrode and a finger having a free end and a fixed end connected to the proof mass, the sense capacitor being configured to sense motion of the proof mass. 3. The MEMS accelerometer of claim 1 , further comprising: a sense capacitor comprising a fixed electrode and a finger having a free end and a fixed end connected to the counter-balance mass, the sense capacitor being configured to sense motion of the counter-balance mass. 4. The MEMS accelerometer of claim 1 , wherein the proof mass is heavier than the counter-balance mass. 5. The MEMS accelerometer of claim 1 , wherein the proof mass is connected to the at least one anchor via one or more hinges. 6. The MEMS accelerometer of claim 1 , wherein the proof mass is suspended above the substrate. 7. The MEMS accelerometer of claim 1 , further comprising a beam, wherein the proof mass and the counter-balance mass are hingedly coupled to the beam. 8. The MEMS accelerometer of claim 1 , wherein the first and second directions are in-plane with respect to the proof mass. 9. A micro electro-mechanical system (MEMS) accelerometer, comprising: at least one anchor coupled to a substrate; a beam movably coupled to the at least one anchor; a proof mass coupled to the beam and a counter-balance mass coupled to the beam; and a first electrode and a second electrode, the first and second electrodes being coupled to the substrate, wherein the proof mass forms a first capacitive sensor with the first electrode and the counter-balance mass forms a second capacitive sensor with the second electrode. 10. The MEMS accelerometer of claim 9 , wherein the first and second electrodes are formed from a common mass. 11. The MEMS accelerometer of claim 9 , wherein the first and second electrodes are formed from separate masses. 12. The MEMS accelerometer of claim 9 , wherein the beam is coupled to the at least one anchor via a first hinge, the proof mass is coupled to the beam via a second hinge and the counter-balance mass is coupled to the beam via a third hinge, wherein the beam extends along a first direction, and wherein the first hinge is positioned between the second hinge and the third hinge in the first direction. 13. The MEMS accelerometer of claim 9 , wherein, in response to an acceleration of the MEMS accelerometer in a first direction, the proof mass is configured to move in the first direction and the counter-balance mass is configured to move in a second direction opposite from the first direction. 14. The MEMS accelerometer of claim 13 , wherein, in response to displacement of the at least one anchor in the first direction, the proof mass and the counter-balance mass are configured to move in the first direction. 15. The MEMS accelerometer of claim 9 , wherein the proof mass is heavier than the counter-balance mass. 16. The MEMS accelerometer of claim 9 , wherein the proof mass, the beam and the counter-balance mass are suspended above the substrate. 17. A method for detecting acceleration using a micro electro-mechanical system (MEMS) accelerometer, the method comprising: sensing motion of a proof mass in a first direction in response to acceleration of the MEMS accelerometer to obtain a first detection signal, the proof mass being coupled to at least one anchor; sensing motion of a counter-balance mass in a direction that is opposite from the first direction in response to the acceleration of the MEMS accelerometer to obtain a second detection signal, the counter-balance mass being coupled to the at least one anchor; sensing motion of the proof mass in a second direction in response to displacement of the at least one anchor to obtain a third detection signal; sensing motion of the counter-balance mass in the second direction in response to the displacement of the at least one anchor to obtain a fourth detection signal; and detecting the acceleration of the MEMS accelerometer using the first, second, third and fourth detection signals. 18. The method of claim 17 , wherein the second direction is parallel to the first direction. 19. The method of claim 17 , wherein: sensing motion of a proof mass in a first direction in response to acceleration of the MEMS accelerometer comprises sensing a variation in a capacitance of a first capacitive sensor; sensing motion of a counter-balance mass in a direction opposite the first direction in response to the acceleration of the MEMS accelerometer comprises sensing a variation in a capacitance of a second capacitive sensor; sensing motion of the proof mass in a second direction in response to displacement of the at least one anchor comprises sensing a variation in a capacitance of a third capacitive sensor; and sensing motion of the counter-balance mass in the second direction in response to the displacement of the at least one anchor comprises sensing the variation in the capacitance of the first capacitive sensor. 20. The method of claim 17 , wherein the first and second directions are in-plane with respect to the proof mass.