Bistable force and/or acceleration sensor

The invention claimed is: 1. A device for use in sensing a force and/or acceleration, comprising: a proof mass; an elastic suspension comprising at least one initially curved beam anchored to the base at one end and to the proof mass at another end, and shaped such that motion of the proof mass applies tension to the curved beam along a line connecting the ends of the curved beam, and enables changing a configuration of the curved beam from a curved shape to a straight shape, thereby providing a stiffening nonlinearity of the dependence of the tension force on displacement of the proof mass; and an electrostatic actuator comprising an electrode assembly, and configured for producing a variable electrostatic force by applying a variable voltage to the electrode assembly for actuating motion of said proof mass according to a selected time profile of the variable voltage, wherein a magnitude of the variable voltage is such that a combination of mechanical and electrostatic forces applied to said proof mass by said elastic suspension and by said electrostatic actuator creates a bistable behavior of the proof mass including a first stable region and a second stable region of displacement of the proof mass under the variable electrostatic force, where a motion of said proof mass is stable, and an intermediate unstable region located between said first and second stable regions, where the proof mass moves in an unstable manner by snapping between the first and second stable regions; a sensing utility configured for (i) monitoring a snapping event of the proof mass in which said proof mass, while being actuated by said electrostatic actuator, snaps between said first stable region and said second stable region, and (ii) recording a value of an actuation voltage applied to the electrode assembly at which the snapping event occurs; and a processing utility configured and operable for (i) using data indicative of the snapping event for determining a deviation value being a deviation of the recorded actuation voltage corresponding to snapping in condition of acceleration from a reference actuation voltage corresponding to snapping in a condition of no acceleration and/or force, and (ii) using said deviation value for calculating the acceleration and/or force acting on the proof mass. 2. The device of claim 1 , wherein said elastic suspension is configured for limiting a movement of said proof mass such that said proof mass does not come into contact with any other element of the sensor. 3. The device of claim 1 , further comprising at least one folded suspension arranged transversely to the curved beams of the elastic suspension, and anchoring the proof mass to the base, the folded suspension being configured for limiting movement of said proof mass to a selected axis, wherein said electrostatic actuator is configured to actuate said proof mass only along said selected axis. 4. The device of claim 1 , wherein said elastic suspension comprises at least two initially curved beams, anchoring opposite sides of said proof mass to opposite sides of said base, such that, upon motion of said proof mass from an initial position thereof, one of said at least two beams is straightened and another beam is compressed. 5. The device of claim 1 , wherein said electrode assembly of the electrostatic actuator comprises: a first set of parallel electrodes joined to said proof mass and a second set of electrodes parallel to said electrodes of said first set, said second set of electrodes being joined to said base, such that application of potential difference between said first and second sets of electrodes produces said electrostatic force therebetween. 6. The device of claim 4 , wherein said electrostatic actuator comprises: a comb drive actuator comprising a third set of parallel electrodes joined to said proof mass and a fourth set of electrodes parallel to said electrodes of said third set, said third set of electrodes being joined to said base, such that application of potential difference between said third and fourth sets of electrodes produces an electrostatic force therebetween. 7. The device of claim 5 , further comprising a thermal actuator, wherein said second electrode set is joined to said thermal actuator, said thermal actuator being controllable for varying a position of said second electrode set joined to said base, in order to change a distance between said first electrode set joined to said proof mass and said second electrode set joined to said base, thereby tuning the distance between the electrode sets such that the device manifests bistable behavior. 8. The device of claim 5 , wherein said electrostatic actuator further comprises a second parallel plate actuator located on a side of said proof mass opposite to said first parallel set actuator for tuning a location of a boundary of at least one of said first and second stability regions, via an application of a desired constant DC voltage to said first parallel plate actuator, and an application of linearly increasing voltage to said second parallel plate actuator. 9. A device for use in sensing a force and/or acceleration, comprising: a proof mass; an elastic suspension comprising at least one initially curved beam anchored to the base at one end and to the proof mass at another end, and shaped such that motion of the proof mass applies tension to the curved beam along a line connecting the ends of the curved beam, and enables changing a configuration of the curved beam from a curved shape to a straight shape, thereby providing a stiffening nonlinearity of the dependence of the tension force on displacement of the proof mass; and an electrostatic actuator comprising an electrode assembly, and configured for producing a variable electrostatic force by applying a variable voltage to the electrode assembly for actuating motion of said proof mass according to a selected time profile of the variable voltage, wherein a magnitude of the variable voltage is such that a combination of mechanical and electrostatic forces applied to said proof mass by said elastic suspension and by said electrostatic actuator creates a bistable behavior of the proof mass including a first stable region and a second stable region of displacement of the proof mass under the variable electrostatic force, where a motion of the proof mass is stable, and an intermediate unstable region located between said first and second stable regions, where the proof mass moves in an unstable manner by snapping between the first and second stable regions, the profile of the variable voltage includes a component causing the device to oscillate within one of the two stable regions, and excite the device at a resonant frequency thereof, thereby a deviation between the device's resonant frequency and a reference resonant frequency corresponding to a condition of absence of force/acceleration is indicative of the force and/or acceleration acting on the device. 10. The device of claim 9 , wherein the device's resonant frequency is the proof mass' resonant frequency. 11. The device of claim 9 , wherein the device's resonant frequency is said beams' resonant frequency. 12. A method for determining an acceleration and/or a force applied on a proof mass, the method comprising: attaching the proof mass to a base via an elastic suspension comprising at least one initially curved beam anchored to the base at one end and to the proof mass at another end, and shaped such that motion of the proof mass applies tension to the curved beam along a line connecting the ends of the curved beam, and enables changing a configuration of the curved beam from a curved shape to a straight shape, thereby providing a s