Shock sensor with bistable mechanism and method of shock detection

The invention claimed is: 1. A shock sensor comprising: a supporting body; a bistable mechanism configured to switch from a first configuration to a second configuration in response to a shock force that is applied to a detection axis and is greater than a threshold value, the bistable mechanism including an elastic element that is coupled to the supporting body by at least two peripheral regions the elastic element being independently stable in the first configuration and the second configuration and defining a first concavity in the first configuration and a second concavity, opposite to the first concavity, in the second configuration; an electrode capacitively coupled to the elastic element to form a capacitor; and a detection device coupled to the bistable mechanism, and having a first state when the bistable mechanism is in the first configuration, and a second state after the bistable mechanism has switched from the first configuration to the second configuration. 2. The shock sensor according to claim 1 , wherein: the bistable mechanism is adjacent to at least a portion of the detection device; the first concavity is open at a first side of the elastic element facing the detection device; and the second concavity is open at a second side of the elastic element opposite to the detection device. 3. The shock sensor according to claim 1 , comprising an auxiliary mass configured to cooperate with the bistable mechanism to switch the bistable mechanism from the first configuration to the second configuration in response to the shock force. 4. The shock sensor according to claim 3 , wherein the auxiliary mass is rigidly coupled to the bistable mechanism. 5. The shock sensor according to claim 3 , wherein the auxiliary mass is movable with respect to the supporting body and to the bistable mechanism. 6. The shock sensor according to claim 5 , wherein the auxiliary mass is coupled to the supporting body through elastic elements configured to provide the auxiliary mass at least one degree of freedom with respect to the supporting body. 7. The shock sensor according to claim 6 , wherein the elastic elements are configured to provide the auxiliary mass a first degree of freedom and a second degree of freedom with respect to the supporting body according to respectively independent first detection axis and second detection axis. 8. The shock sensor according to claim 7 , wherein the bistable mechanism is two first bistable mechanisms, respectively arranged adjacent to first and second sides of the auxiliary mass and activatable by oscillations of the auxiliary mass in opposite directions. 9. The shock sensor according to claim 8 , comprising two second bistable mechanisms, respectively arranged adjacent to third and fourth sides of the auxiliary mass and activatable by oscillations of the auxiliary mass in opposite directions; wherein the first bistable mechanisms are activatable by oscillations of the auxiliary mass in opposite directions according to the first detection axis and the second bistable mechanisms are activatable by oscillations of the auxiliary mass in opposite directions according to the second detection axis. 10. The shock sensor according to claim 1 , wherein the bistable mechanism is a first bistable mechanism, the shock sensory comprising a second bistable mechanism arranged adjacent to the auxiliary mass, the first bistable mechanism being activatable by clockwise oscillations of the auxiliary mass about the detection axis, and the second bistable mechanism being activatable by counter-clockwise oscillations of the auxiliary mass about the detection axis. 11. The shock sensor according to claim 1 , wherein the elastic element is a flexible beam of a semiconductor material having an arched shape in the first configuration and in the second configuration, and having opposite ends fixed to the supporting body. 12. The shock sensor according to claim 1 , wherein the bistable mechanism includes a first plate elastic element and a second plate elastic element defined by respective flexible beams of a semiconductor material and having an arched shape in the first configuration and in the second configuration and having opposite ends fixed to the supporting body. 13. The shock sensor according to claim 12 , wherein the bistable mechanism includes at least a bridge element coupling the first plate elastic element and the second plate elastic element. 14. A shock sensor comprising: a supporting body; a bistable mechanism configured to switch from a first configuration to a second configuration in response to a shock force that is applied to a detection axis and is greater than a threshold value, the bistable mechanism including an elastic element that is coupled to the supporting body by at least two peripheral regions the elastic element being independently stable in the first configuration and the second configuration and defining a first concavity in the first configuration and a second concavity, opposite to the first concavity, in the second configuration, the elastic element including an elastic membrane, of a semiconductor material, arranged to cover a recess in the supporting body; and a detection device coupled to the bistable mechanism, and having a first state when the bistable mechanism is in the first configuration, and a second state after the bistable mechanism has switched from the first configuration to the second configuration. 15. The shock sensor according to claim 14 , wherein the elastic membrane has a peripheral edge constrained to the supporting body at a margin of the recess. 16. The shock sensor according to claim 14 , wherein the elastic membrane is bell-shaped in the first configuration and in the configuration. 17. The shock sensor according to claim 1 , wherein: the conductive structure includes an electrode structure capacitively coupled to the elastic element and a capacitance between the electrode structure and the elastic element has a first value in the first state and a second value, different from the first value, in the second state. 18. The shock sensor according to claim 17 , wherein the detection device includes a reading unit configured to determine a state of the detection device based on a capacitance value of the conductive structure. 19. The shock sensor according to claim 1 , wherein the initial configuration is the first configuration and the final configuration is the second configuration. 20. An electronic system comprising: a control unit; and a shock sensor coupled to the control unit, the shock sensor including: a supporting body; a bistable mechanism that includes opposing ends that are coupled to the supporting body, the bistable mechanism being configured to switch from a first configuration to a second configuration in response to a shock force that is applied along a detection axis of the supporting body and is greater than a threshold value, the bistable mechanism forming a first concavity in the first configuration and a second concavity, symmetrically mirrored to the first concavity, in the second configuration; a detection device coupled to the bistable mechanism and including a conductive structure and configured to measure a first value when the bistable mechanism is in the first configuration, and a second, different value when the bistable mechanism has switched from the first configuration to the second configuration; and a sharp element included in the bistable mechanism that is carried by the elastic element, the sharp element being co