Microelectromechanical systems (MEMS) inertial sensors with energy harvesters and related methods

What is claimed is: 1. A microelectromechanical system (MEMS) apparatus comprising: a substrate having a top surface; an accelerometer comprising a proof mass coupled to the substrate and a capacitive sensor, the capacitive sensor of the accelerometer being configured to generate a sense signal in response to acceleration of the proof mass along at least one axis, the capacitive sensor having a first electrode coupled to the proof mass and a second electrode coupled to a beam; sense circuitry configured to receive the sense signal and to determine, based on the sense signal, a magnitude of the acceleration of the proof mass; and an energy harvester comprising a piezoelectric material layer coupled to the beam and formed between the substrate and the proof mass, wherein the piezoelectric material layer is configured to produce an electric signal in response to motion of the proof mass relative to the top surface of the substrate. 2. The MEMS apparatus of claim 1 , wherein the at least one axis is parallel to the top surface of the substrate. 3. The MEMS apparatus of claim 2 , wherein the accelerometer is a first accelerometer and the sense signal is a first sense signal, wherein the at least one axis is parallel to the top surface of the substrate, wherein the MEMS apparatus further comprises a second accelerometer comprising the proof mass, the second accelerometer being configured to generate a second sense signal in response to the acceleration of the proof mass along the at least one axis, and wherein the sense circuitry is configured to determine, in a differential manner and based on the first and second sense signals, the magnitude of the acceleration of the proof mass along the at least one axis. 4. The MEMS apparatus of claim 1 , further comprising a recess formed between the beam and the proof mass, wherein the first and second electrodes are disposed on opposite sides of the recess. 5. The MEMS apparatus of claim 1 , wherein the accelerometer is configured to generate the sense signal by sensing a variation in a capacitance of the capacitive sensor. 6. The MEMS apparatus of claim 1 , wherein the beam is configured to flex in response to motion of the proof mass relative to the top surface of the substrate. 7. The MEMS apparatus of claim 1 , wherein the proof mass and the beam form a recess, the recess being configured to deform in response to motion of the proof mass relative to the top surface of the substrate. 8. The MEMS apparatus of claim 1 , wherein the sense circuitry is integrated in the substrate. 9. A microelectromechanical system (MEMS) apparatus comprising: a substrate; a piezoelectric energy harvester comprising: a beam coupled to the substrate, wherein at least a portion of the beam comprises a piezoelectric material layer; a proof mass coupled to the beam; an accelerometer comprising a first electrode coupled to the proof mass and a second electrode coupled to the beam, wherein a recess separates the first electrode from the second electrode, the accelerometer being configured to generate a sense signal in response to acceleration of the proof mass; and sense circuitry configured to receive the sense signal and to determine, based on the sense signal, a magnitude of the acceleration of the proof mass. 10. The MEMS apparatus of claim 9 , wherein the piezoelectric material layer is configured to generate an electric signal in response to an out-of-plane motion of the proof mass. 11. The MEMS apparatus of claim 9 , wherein the accelerometer is configured to generate the sense signal in response to in-plane acceleration of the proof mass. 12. The MEMS apparatus of claim 9 , wherein the recess further separates the proof mass from the beam. 13. The MEMS apparatus of claim 9 , wherein the piezoelectric energy harvester further comprises third and fourth electrodes disposed on opposite sides of the piezoelectric material layer. 14. The MEMS apparatus of claim 9 , wherein the piezoelectric material layer exhibits a rotational symmetry relative to an axis perpendicular to a top surface of the substrate and comprises one or more gaps. 15. The MEMS apparatus of claim 9 , wherein the accelerometer is configured to generate the sense signal capacitively using the first and second electrodes. 16. The MEMS apparatus of claim 9 , wherein the accelerometer is a first accelerometer, the sense signal is a first sense signal and the beam is a first beam, wherein the acceleration of the proof mass is in-plane, wherein: the MEMS apparatus further comprises a second accelerometer having a third electrode coupled to the proof mass and a fourth electrode coupled to a second beam disposed between the substrate and the proof mass, wherein the second accelerometer is configured to generate a second sense signal in response to the in-plane acceleration of the proof mass, and wherein the sense circuitry is configured to determine, in a differential manner and based on the first and second sense signals, the magnitude of the in-plane acceleration of the proof mass. 17. A method for sensing motion using a microelectromechanical system (MEMS) apparatus, the method comprising: converting, to electric energy, vibrational energy of a proof mass coupled to a substrate by sensing mechanical stress in a piezoelectric material layer coupled to a beam and formed between the proof mass and the substrate; with a sense capacitor including a first electrode coupled to the proof mass and a second electrode coupled to the beam, generating a sense signal in response to acceleration of the proof mass along at least one axis; with a sense circuit, receiving the sense signal and determining, based on the sense signal, a magnitude of the acceleration of the proof mass; and powering the sense circuit at least in part with the electric energy. 18. The method of claim 17 , wherein the at least one axis is parallel to a top surface of the substrate. 19. The method of claim 17 , wherein sensing mechanical stress in the piezoelectric material layer comprises generating an electric signal in response to the mechanical stress. 20. The method of claim 19 , further comprising a recess formed between the proof mass and the beam, wherein the first and second electrodes are disposed on opposite sides of the recess.