Method and circuit for determining resonant frequencies of a resonant device

The invention claimed is: 1. A method of determining a resonance frequency of a shock sensor, comprising: providing to the shock sensor a periodic input signal having a frequency in a frequency interval, the shock sensor being configured to detect a shock imparted to the shock sensor; calculating a frequency value for said periodic input signal in said frequency interval for which a phase difference between said periodic input signal and a corresponding periodic output signal of the shock sensor is minimum, the corresponding periodic output signal being an electrical response of the shock sensor to the periodic input signal being provided to the shock sensor; generating a signal indicating that the resonance frequency has been determined; and generating a signal representing said resonance frequency of the shock sensor as the calculated frequency value of said periodic input signal. 2. The method of claim 1 , wherein calculating the frequency value includes: comparing said phase difference with a threshold; the method further comprising: when said threshold is not crossed, choosing a different frequency value for said periodic input signal in said frequency interval before providing to the shock sensor the periodic input signal having the different frequency value. 3. The method of claim 2 , wherein said threshold corresponds to the absolute value of said phase difference of about 45° or greater. 4. The method of claim 1 , wherein said periodic input signal is a square-wave input signal. 5. The method of claim 4 , wherein calculating the frequency value includes: comparing said phase difference with a threshold; the method further comprising: when said threshold is not crossed, choosing a different frequency value for said periodic input signal in said frequency interval before providing to the shock sensor the periodic input signal having the different frequency value; generating a logic XOR signal corresponding to a logic XOR between said square-wave input signal and the corresponding periodic output signal; comparing a duty-cycle of said logic XOR signal with a corresponding level; and assessing upon said comparing whether said phase difference surpassed said threshold. 6. The method of claim 1 , wherein said frequency interval is a signal bandwidth of the shock sensor. 7. A circuit for generating a signal representing a resonance frequency of a shock sensor, comprising: a square-wave generator configured to provide to said shock sensor a square-wave input signal having a frequency in a frequency interval; a phase detection circuit configured to calculate a phase difference between said periodic input signal and a corresponding periodic output signal of the shock sensor; and a phase check circuit configured to calculate a frequency value for said periodic input signal in said frequency interval for which the phase difference between said periodic input signal and the corresponding periodic output signal of the shock sensor is minimum, the corresponding periodic output signal being an electrical response of the shock sensor to the periodic input signal. 8. The circuit of claim 7 , wherein the phase detection circuit includes: an XOR gate configured to be input with said square-wave input signal and with a corresponding periodic output signal generated by the shock sensor and configured to output a logic XOR signal; and a processor configured to receive the logic XOR signal, determine a duty-cycle of said logic XOR signal, determine a phase difference based on said duty-cycle, cause said square-wave generator to adjust a frequency of said square-wave input signal, and generate said signal representing said resonance frequency of the shock sensor. 9. A method, comprising: filtering an output of a shock sensor with a notch filter, the filtering including: determining a resonance frequency of said shock sensor, the determining including: providing to the shock sensor a periodic input signal having a frequency in a frequency interval; calculating a frequency value for said periodic input signal in said frequency interval for which a phase difference between said periodic input signal and a corresponding periodic output signal of the shock sensor is minimum, the corresponding periodic output signal being an electrical response of the shock sensor to the periodic input signal being provided to the shock sensor; generating a signal indicating that a resonance frequency has been determined and generating a signal representing said resonance frequency as a value of the frequency of said periodic input signal; tuning said notch filter using said signal representing said resonance frequency; and filtering the output of said shock sensor using said tuned notch filter. 10. The method of claim 9 , wherein calculating the frequency value includes: comparing said phase difference with a threshold; when said threshold is not crossed, choosing a different frequency value for said periodic input signal in said frequency interval before providing to the shock sensor the periodic input signal having the different frequency value. 11. The method of claim 9 , wherein said threshold corresponds to the absolute value of said phase difference of about 45° or greater. 12. The method of claim 9 , wherein said periodic input signal is a square-wave input signal. 13. The method of claim 12 , wherein calculating the frequency value includes: comparing said phase difference with a threshold; when said threshold is not crossed, choosing a different frequency value for said periodic input signal in said frequency interval before providing to the shock sensor the periodic input signal having the different frequency value; generating a logic XOR signal corresponding to a logic XOR between said square-wave input signal and the corresponding periodic output signal; comparing a duty-cycle of said logic XOR signal with a corresponding level; and assessing upon said comparing whether said phase difference surpassed said threshold. 14. The method of claim 9 , wherein said frequency interval is a signal bandwidth of said shock sensor. 15. The method of claim 9 , further comprising: generating a phase modulus signal representing an absolute value of the phase difference between said periodic input signal and the corresponding periodic output signal of the shock sensor; and generating a phase sign signal representing a sign of the phase difference between said periodic input signal and the corresponding periodic output signal of the shock sensor, wherein the calculating of the frequency value includes calculating the frequency value based at least in part on the phase modulus signal and the phase sign signal. 16. The method of claim 9 , wherein the providing includes providing to a first terminal and a second terminal of the shock sensor the periodic input. 17. The method of claim 1 , further comprising: generating a phase modulus signal representing an absolute value of the phase difference between said periodic input signal and the corresponding periodic output signal of the shock sensor; and generating a phase sign signal representing a sign of the phase difference between said periodic input signal and the corresponding periodic output signal of the shock sensor, wherein the calculating of the frequency value includes calculating the frequency value based at least in part on the phase modulus signal and the phase sign signal. 18. The method of claim 1 , wherein the providing includes providing to a first terminal and a second terminal of the s