Health state monitoring device and method

The invention claimed is: 1. A device of monitoring the health state, comprising: a semiconductor die, including: an electric potential sensor configured to detect potential variations present on a body of a living being and associated with a heart rhythm and to generate a cardiac signal; and cardiac parameter determination circuitry configured to receive the cardiac signal and determine cardiac parameters indicative of a health state, wherein the cardiac parameter determination circuitry is configured to detect triggering events and to determine features of the cardiac signal in time windows defined by the triggering events; one or more electrodes electrically coupled to the electric potential center; and a personal computer, wherein the one or more electrodes include a first and second key of the personal computer. 2. The health monitoring device according to claim 1 , further comprising decision circuitry configured to receive the cardiac parameters and generate a health signal based on a comparison with threshold values. 3. The health monitoring device according to claim 1 , wherein the cardiac parameters include heart rate and QRS-complex. 4. The health monitoring device according to claim 1 , wherein the triggering events include threshold exceeding and the cardiac parameter determination circuitry is configured to detect a time distance between two triggering events exceeding the thresholds. 5. The health monitoring device according to claim 1 , wherein the cardiac parameter determination unit includes heart rate detection circuitry, the heart rate detection circuitry being configured to: a) initialize a first counter configured to provide a count value; b) receive a sample of the cardiac signal, the sample having a value; c) verify whether the sample value is a peak value; d) increase the first counter and repeat steps b) and c) if the verification c) gives a negative result; e) verify whether the sample value exceeds a heart rate threshold if the verification c) gives a positive result; f) acquire the count value of the first counter as heart rate information if the verification e) gives a positive result; g) increase the first counter and repeat steps b)-e) if the verification e) gives a negative result. 6. The health monitoring device according to claim 5 , wherein the cardiac parameter determination unit further comprises QRS-complex detection circuitry, the QRS-complex detection circuitry being configured to: h) receive the cardiac signal; i) filter the cardiac signal through a high-pass filter to obtain a filtered signal; j) initiate a second counter configured to provide a count value; k) acquire a sample of the filtered signal having a value; l) verify whether the sample value of the filtered signal is a peak value; m) increase the second counter and repeat steps k)-l) if the verification l) gives a negative result; n) verify whether the sample value of the filtered signal exceeds a QRS threshold if the verification 1 ) gives a positive result; o) acquire the count value of the second counter as heart rate information if the verification n) gives a positive result; p) increase the second counter and repeat steps k)-n) if the verification e) gives a negative result. 7. The health monitoring device according to claim 5 , wherein initiating includes resetting the count value. 8. The health monitoring device according to claim 2 , further comprising a MEMS movement sensor and movement parameter determination circuitry coupled to the MEMS sensor and to the decision circuitry, wherein the MEMS movement sensor is configured to generate an inertial signal; the movement parameter determination circuitry is configured to detect movement parameters of the inertial signal; and the decision circuitry is configured to receive the movement parameters, detect a movement condition or a rest condition from the movement parameters and generate a movement signal in response to detection of the movement condition and provide a health state information on the basis of cardiac parameters in response to detecting the rest condition. 9. The health monitoring device according to claim 8 , wherein the MEMS movement sensor is an accelerometer or a gyroscope and is integrated in a further die coupled to the semiconductor material die. 10. The health monitoring device according to claim 2 , wherein the cardiac parameter determination circuitry and the decision circuitry include a machine learning core. 11. The health monitoring device according to claim 10 , wherein the machine learning core is configured to receive an input signal and includes at least one of: a) a positive zero-crossing detection module, configured to detect when the input signal goes from negative to positive; b) a negative zero-crossing detection module, configured to detect when the input signal goes from positive to negative; c) a peak detection module, configured to detect when the input signal assumes a maximum or minimum value; d) a positive peak detection module, configured to detect when the input signal assumes a maximum value; or e) a clock generation module, configured to generate a clock event, and at least one of the following triggered feature detection modules: f) a mean calculation module, configured to calculate a mean of values of the input signal in a window delimited between two triggering events; g) a variance calculation module, configured to calculate a variance of the input signal between two triggering events; h) an energy calculation module, configured to calculate an energy of the input signal within a window delimited between two triggering events or a window of predetermined duration from a triggering event; i) a peak-to-peak value calculation module, configured to calculate the difference between a maximum value and a minimum value of the input signal in a window delimited between two triggering events or in a window of predetermined duration from a triggering event; j) a negative zero-crossing number calculation module, configured to calculate a number of negative crossings in a window delimited between two triggering events or in a window of predetermined duration from a triggering event; k) a peak calculation module, configured to calculate a peak number of the input signal in a window delimited between two triggering events; l) a positive peak calculation module, configured to calculate a positive peak number of the input signal in a window delimited between two triggering events; m) a negative peak calculation module, configured to calculate a negative peak number of the input signal in a window delimited between two triggering events; n) a minimum detection module, configured to detect a minimum value of the input signal in a window delimited between two triggering events; o) a maximum detection module, configured to detect a maximum value of the input signal in a window delimited between two triggering events; or p) a duration calculation module, configured to calculate a duration of the input signal in a window delimited between two triggering events. 12. An electronic apparatus, comprising: a health monitoring device, including: a semiconductor die, including: an electric potential sensor configured to detect potential variations present on a body of a living being and associated with a heart rhythm and to generate a cardiac signal; and cardiac parameter determination circuitry configured to receive the cardiac signal and determine cardiac parameters indicative of a health state, wherein the cardiac parameter determination circuitry is configured to detect triggering events including threshold exceeding and to determi