Method of calibrating a standby duration of a proximity detection sensor and associated sensor

The invention claimed is: 1. A method of calibrating a standby duration of a proximity detection sensor configured to detect the proximity of a user, said sensor alternating between: (i) a first measurement phase of measuring a representative value of the user's proximity that is a variation in capacitance of an electrode of the proximity detection sensor, during an evaluation duration that varies according to said value, said evaluation duration being measured using a first oscillator, having a first oscillation frequency, and (ii) a standby phase for a predetermined standby duration, the predetermined standby duration being longer than the evaluation duration, and being controlled by a second oscillator, having a second oscillation frequency, which varies with respect to a second nominal oscillation frequency according to parameters external to the sensor, the calibration method comprising the following steps: step 1: consecutively after the first measurement phase performed by the first oscillator, measuring, in a second measurement phase, a second evaluation duration by the second oscillator; step 2: calculating a ratio between a second number of oscillations generated by the second oscillator during the second measurement phase and a first number of oscillations generated by the first oscillator during the first measurement phase; step 3: comparing the calculated ratio with a predetermined ratio; step 4: calculating a deviation between the ratio and the predetermined ratio; and step 5: during the standby phase, correcting the number of oscillations of the standby phase according to the calculated deviation in order to calibrate a new standby duration to correct a drift in the second oscillation frequency of the second oscillator, and thus a drift of the new standby duration caused by the variation in the second oscillation frequency in order to reduce an electrical consumption of the proximity detection sensor and improve a reaction time of the proximity detection sensor. 2. The calibration method as claimed in claim 1 , wherein the predetermined ratio is equal to the ratio between the second nominal frequency and the first frequency. 3. The calibration procedure as claimed in claim 1 , wherein steps 1 through 5 are performed at each power up of the proximity detection sensor. 4. The calibration procedure as claimed in claim 1 , wherein steps 1 through 5 are repeated at a set period of the order of 120 s. 5. The calibration method as claimed in claim 1 , further comprising: step 1b: after step 1, consecutively after the second measurement phase, measuring, in a third measurement phase, a third evaluation duration by the first oscillator, step 1c: when the first number of oscillations of the first measurement phase is equal to a third number of oscillations generated during the third measurement phase, then repeating Steps 2-5, and when the first number of oscillations of the first measurement phase is not equal to the third number of oscillations generated during the third measurement phase, then stopping the calibration procedure. 6. The calibration method as claimed in claim 5 , wherein the predetermined ratio is equal to the ratio between the second nominal frequency and the first frequency. 7. The calibration procedure as claimed in claim 5 , wherein steps 1 through 5 are performed at each power up of the proximity detection sensor. 8. The calibration procedure as claimed in claim 5 , wherein steps 1 through 5 are repeated at a set period of the order of 120 s. 9. A capacitive proximity detection sensor comprising: a microcontroller including one or more processors configured to measure; a detection electrode; a first oscillator, having a first oscillation frequency measuring evaluation durations during phases of measuring a variation in capacitance of the electrode; a second oscillator controlling predetermined standby durations during standby phases of the capacitive sensor, the second oscillator having a second oscillation frequency that varies with respect to a second nominal oscillation frequency according to parameters external to the capacitive sensor; and a switching device connected to the first and second oscillators, and to the one or more processors configured to measure, wherein the one or more processors is configured to calibrate, is connected to the switching device and is configured to perform, consecutively to a first one of the measurement phases, a second measurement phase, measure a second evaluation duration using the second oscillator, calculate a ratio between a second number of oscillations generated by the second oscillator during the second measurement phase and a first number of oscillations generated by the first oscillator during the first measurement phase, compare between the calculated ratio and a predetermined ratio, calculate a deviation between the calculated ratio and the predetermined ratio, and correct, during the standby phase, the number of oscillations of the standby phase according to the calculated deviation in order to calibrate the standby duration to correct a drift in the second oscillation frequency of the second oscillator, and thus a drift of the new standby duration caused by the variation in the second oscillation frequency in order to reduce an electrical consumption of the proximity detection sensor and improve a reaction time of the proximity detection sensor. 10. A motor vehicle door handle comprising: the capacitive proximity detection sensor as claimed in claim 9 . 11. A motor vehicle, comprising: the capacitive proximity detection sensor as claimed in claim 9 . 12. A capacitive proximity detection sensor: a microcontroller including one or more processors configured to measure; a detection electrode; a first oscillator, having a first oscillation frequency measuring evaluation durations during phases of measuring a variation in capacitance of the electrode; a second oscillator controlling predetermined standby durations during standby phases of the capacitive sensor, the second oscillator having a second oscillation frequency that varies with respect to a second nominal oscillation frequency according to parameters external to the capacitive sensor; and a switching device connected to the first and second oscillators, and to the one or more processors configured to measure, wherein the one or more processors is configured to calibrate, is connected to the switching device and is configured to perform, consecutively to a first one of the measurement phases, a second measurement phase, measure a second evaluation duration using the second oscillator, perform, consecutively to the second measurement phase, a third measurement phase, measure a third evaluation duration using the first oscillator, compare between the first number of oscillations of the first measurement phase and a third number of oscillations generated during the third measurement phase, calculate a ratio between a second number of oscillations generated by the second oscillator during the second measurement phase and a first number of oscillations generated by the first oscillator during the first measurement phase, compare between the calculated ratio and a predetermined ratio, calculate a deviation between the calculated ratio and the predetermined ratio, during the standby phase, the number of oscillations of the standby phase according to the calculated deviation in order to calibrate the standby duration to correct a drift in the second oscillation frequency of the second oscillator, and thus a drift of the new standby duration caused by the variation in the second oscillation frequency in order t