LOW CONSUMPTION DEVICE FOR MEASURING A VARIATION OF A CAPACITANCE AND ASSOCIATED METHOD

The present invention relates to a charge-transfer capacitive sensor. More particularly, it pertains to the application of such a sensor in the door handles of a vehicle for so-called “hands free” access of an authorized user to his vehicle.

Nowadays, certain motor vehicles are equipped with “hands free” access; that is to say the authorized user of the vehicle no longer needs a key to open the doors and other openable panels (hood, trunk, etc.) of his vehicle. In place of a key, he possesses an identification badge (or remote control) with which the vehicle electronic system interacts.

To invoke the opening of a door, for example, the driver approaches the handle of the door. A capacitive presence sensor, in this instance a charge-transfer capacitive sensor situated in the handle, detects the presence of the drivers hand. This sensor is connected to the electronic computer of the vehicle (ECU: English abbreviation for “Electronic Control Unit”) and sends it a presence detection signal. The electronic computer of the vehicle has beforehand identified the user as being authorized to access this vehicle, or alternatively, subsequent to the reception of this detection signal, it undertakes this identification. Accordingly, it sends by way of an LF (English abbreviation for “Low Frequency”) antenna an identification request to the badge (or to the remote control) worn or carried by the user. This badge sends in response, by RF (radio frequency) waves, its identification code to the electronic computer of the vehicle. If the electronic computer recognizes the identification code as that authorizing access to the vehicle, it triggers the opening of the door. If, on the other hand, the electronic computer has not received any identification code or if the identification code received is erroneous, opening does not occur.

As illustrated in FIG. 1, a capacitive sensor 3 such as this consists of an electrode 4 integrated into the handle 6 of the door and of a second electrode linked to ground. This second electrode can include a part of the body of a user and of a close environment linked directly or indirectly to ground. This may be, for example, the hand M of the user, the presence of which near the handle 6 of the door has to be detected.

When the user's hand M approaches the handle 6 of the door, that is to say it passes from position 1 to position 2 along the direction of the arrow illustrated in FIG. 1, the capacitance C_Xof the electrode 4 integrated into the handle 6 increases. The variation ΔC_Xis measured with the aid of a reference capacitance C_S, situated on a printed circuit 5 connected to the electrode 4. If the value of the capacitance C_Xcrosses a threshold, this gives rise to the validation of the detection. Indeed this means that the users hand M is in position 2, on the handle 6 of the door or sufficiently close to this handle 6 and that he is requesting access to the vehicle.

From the prior art it is known that the charge-transfer capacitive sensor 3 makes it possible to measure the variation ΔC_Xof the capacitance C_Xof the electrode 4 integrated into the handle 6 of the door by performing a charge transfer consisting of a large number of charges and of discharges of this capacitance C_Xinto the reference capacitance C_S, until a fixed threshold of voltage is attained across the terminals of the reference capacitance C_S. The estimation of the variation ΔC_Xof the capacitance C_Xof the electrode 4 with respect to the previous cycle is carried out on the basis of the variation of the number of discharges of the capacitance C_Xof the electrode 4 into the reference capacitance C_Sthat had to be performed so as to attain this threshold of voltage across the terminals of the reference capacitance C_S. These capacitive sensors 3 involve switching means which make it possible to direct the current so as firstly to charge the capacitance C_Xof the electrode 4 by way of the supply voltage and thereafter to discharge it into the reference capacitance C_S. The charge transfer, that is to say the succession of charges and discharges, according to the prior art, and illustrated in FIG. 2, breaks down into four steps:

- 1st step: the first step consists in charging the capacitance C_Xof the electrode 4 on the basis of the supply voltage V_CC. Accordingly the first switch S1 is closed and the second switch S2 is opened.
- 2nd step: once charging has finished, the first switch S1 is opened.
- 3rd step: then the discharging of the capacitance C_Xof the electrode 4 into the reference capacitance C_Scan begin. Accordingly, the first switch S1 remains open and the second switch S2 is closed.
- 4th step: once discharging has been carried out, the second switch S2 is opened.

The charge transfer is repeated until the voltage V_Sacross the terminals of the reference capacitance C_Sattains the threshold voltage V_TH. The number of discharges x of the capacitance C_Xof the electrode 4 to the reference capacitance C_Srequired to attain this threshold V_THgives an image of the capacitance C_Xof the electrode 4. The reference capacitance C_Sis thereafter completely discharged by way of the switch S in preparation for the next measurement.

A counter of the number of discharges x and a microcontroller (neither of which is represented in FIG. 2) make it possible to determine the capacitance C_Xof the electrode 4.

The equation governing the operation of the capacitive sensor 3 is the following:

$V_{S} (x) = \frac{C_{X}}{C_{S}} \times V_{CC} + V_{S} (x - 1) \times (1 - \frac{C_{X}}{C_{S}})$

The evolution of the voltage V_Sacross the terminals of the reference capacitance C_Sconstitutes a mathematical series according to the number of discharges x of the capacitance C_Xof the electrode 4 to the reference capacitance C_S, and is given by equation (1):

$\begin{matrix} V_{S} (x) = V_{CC} \times (1 - {(1 - \frac{C_{X}}{C_{S}})}^{x}) & (1) \end{matrix}$

At the end of the charge transfer, the voltage V_Sacross the terminals of the reference capacitance C_Shas reached the threshold voltage V_TH, and a number of discharges x is obtained, defined by equation (2):

$\begin{matrix} x = - \frac{C_{S}}{C_{X}} \times \ln (1 - \frac{V_{TH}}{V_{CC}}) & (2) \end{matrix}$

Th is defined as a detection threshold, corresponding to a number of charge transfers between the two states of the capacitance C_Xof the electrode 4, that is to say between C_Xand C_X+ΔC_X.

Th is equal to the variation of the number of discharges x, between the value of the capacitance C_Xand the value of the capacitance C_X+ΔC_X.

Consequently:

$Th = - \frac{C_{S}}{C_{X}} \times \ln (1 - \frac{V_{TH}}{V_{CC}}) + \frac{C_{S}}{C_{X} + Δ C_{X}} \times \ln (1 - \frac{V_{TH}}{V_{CC}})$

This gives:

$Δ C_{X} = \frac{- Th \times C_{X}^{2}}{C_{S} \times \ln (1 - \frac{V_{TH}}{V_{CC}}) - Th \times C_{X}}$

As the reference capacitance C_Sis, according to the prior art, appreciably greater than the capacitance C_Xof the electrode 4, the following equation is obtained for the variation ΔC_Xof the capacitance C_X:

$\begin{matrix} Δ C_{X} \approx \frac{- Th \times C_{X}^{2}}{C_{S} \times \ln (1 - \frac{V_{TH}}{V_{CC}})} & (3) \end{matrix}$

This equation (3) is known to the person skilled in the art.

Consequently, the variation ΔC_Xof the capacitance C_Xmeasurable by the capacitive sensor 3, (stated otherwise, the sensitivity of the latter), defined by equation (3) depends on numerous parameters: the value of the storage capacitance C_S, the supply voltage V_CC, the voltage threshold for stopping measurement V_THand especially chiefly on the capacitance of the electrode squared C_X². Now, the capacitance C_Xof the electrode 4 is difficult to control and varies as a function of the environment (temperature, humidity, etc.), thus degrading the value of the variation ΔC_Xof the capacitance C_Xand therefore the sensitivity and the performance of the capacitive sensor 3.

Moreover, the number of discharges x which conditions the duration of measurement, is proportional to the reference capacitance C_S(cf. equation (2)), which is itself dependent on the other parameters and in particular on the desired variation ΔC_X(cf. equation (3)). Thus for a variation ΔC_Xof the capacitance C_Xwhich is given, there corresponds a value of the reference capacitance C_Sand therefore a fixed number of discharges x (Th, V_CC, V_TH, and C_Xbeing fixed parameters). Consequently, the number of discharges x, that is to say the duration of charge transfer, or the duration of measurement of the variation ΔC_Xof the capacitance C_Xuntil detection, is fixed and cannot be optimized. Indeed, if the number of discharges x is reduced by two, for example, to reduce the duration of measurement, the reference capacitance C_Sis divided by two according to equation (2), and consequently, the variation ΔC_Xof the capacitance C_Xis degraded, since it is multiplied by two according to equation (3). With such a device, there is therefore no means of optimizing the duration of measurement of the capacitive sensor 3 without impacting the variation ΔC_Xof the capacitance C_X, that is to say the sensitivity of the capacitive sensor 3.

However, the duration of measurement of the capacitive sensor must be extremely fast, since:

- the door opening mechanism must be completely transparent to the driver. Indeed, the latter expects the opening of the door to be as fast as in the case of opening a mechanical handle, not equipped with a capacitive sensor 3,
- the consumption of the capacitive sensor 3 must be minimized, since it operates for long periods when the vehicle is stopped. Now, consumption being related to the duration of measurement, if the duration of measurement is reduced, consumption decreases.

However, as detailed hereinabove, given that the reduction in the duration of measurement brings about a degradation in the sensitivity of the capacitive sensor 3, this can cause overly late detections. Indeed, a degradation in the sensitivity of the sensor signifies that detection was carried out only when a large variation ΔC_Xof the capacitance C_Xwas measured. A necessary compromise therefore exists between the duration of measurement and the sensitivity desired, that is to say the variation ΔC_Xof the capacitance C_Xdesired. It will have been understood that there is a significant advantage in producing a capacitive sensor 3 for which the variation ΔC_Xof the capacitance C_Xis independent of the duration of measurement.

A device for measuring a variation ΔC_Xof the capacitance C_Xmaking it possible to alleviate these drawbacks is known from the prior art (cf. FIG. 3). In this instance, document FR 2 938 344 A1 describes a device for measuring a variation ΔC_Xof the capacitance C_Xfurthermore comprising:

- a third capacitance, called the measurement capacitance C_M, linked to ground,
- means (a switch S3) for charging this measurement capacitance on the basis of the supply voltage V_CC, and
- means (a switch S4) for discharging the measurement capacitance C_Mto the reference capacitance C_Sin a variable number of discharges n.

This measurement capacitance C_Mmakes it possible to carry out the measurement of the variation ΔC_Xof the capacitance C_Xin such a way that this variation is independent of the capacitance C_Xof the electrode 4 measured. This allows the optimization of the duration of measurement until the detection (that is to say the optimization of the number of charges and/or discharges) of the capacitive sensor 3 without impacting its variation ΔC_X.

According to the invention described in document FR 2 938 344 A1, the charge transfer breaks down into two phases: acquisition and measurement.

The acquisition phase consists of a conventional transfer of charge from the capacitance C_Xof the electrode 4 into the reference capacitance C_S. The difference with conventional charge transfer, described above, is that the charge transfer stops after a fixed number of discharges x and not when the voltage V_Sacross the terminals of the reference capacitance C_Sattains a voltage threshold V_TH.

The measurement phase consists of a transfer of charge, of a variable number of discharges n, of the measurement capacitance C_Minto the reference capacitance C_Suntil the voltage V_Sacross the terminals of the reference capacitance C_Sreaches the threshold voltage V_TH.

During the acquisition phase, the charge of the capacitance C_Xof the electrode 4 is transferred into the measurement capacitance C_Sin the following manner:

- 1st step: the first step consists in charging the capacitance C_Xof the electrode 4 on the basis of the supply voltage V_CC. Accordingly the first switch S1 is closed and the second switch S2 is opened,
- 2nd step: once the charging of the capacitance C_Xof the electrode 4 has terminated, the first switch S1 is opened,
- 3rd step: the discharging of the capacitance C_Xof the electrode 4 into the reference capacitance C_Scan begin. Accordingly, the first switch S1 remains open and the second switch S2 is closed,
- 4th step: once the discharging of the capacitance C_Xof the electrode 4 into the reference capacitance C_Shas been carried out, the second switch S2 is opened.

The third and the fourth switch S3 and S4 are open during this acquisition phase. Consequently, the measurement capacitance C_Mis neither charged, nor discharged during this acquisition phase.

This charging and discharging cycle is repeated a predetermined and fixed number of times x.

During the measurement phase, the charge of the measurement capacitance C_Mis transferred into the reference capacitance C_Suntil the voltage V_Sacross the terminals of this capacitance attains a threshold V_TH.

- 1st step: the first step consists in charging the measurement capacitance C_M. Accordingly the third switch S3 is closed and the fourth switch S4 is opened,
- 2nd step: once the charging of the measurement capacitance C_Mhas terminated, the third switch S3 is opened,
- 3rd step: the discharging of the measurement capacitance C_Minto the reference capacitance C_Scan begin. Accordingly, the third switch S3 remains open and the fourth switch S4 is closed,
- 4th step: once the discharging of the measurement capacitance C_Minto the reference capacitance C_Shas been carried out, the fourth switch S4 is opened.

The first and the second switch S1 and S2 are open during this measurement phase. Consequently the capacitance C_Xof the electrode 4 is neither charged, nor discharged during this measurement phase.

This cycle is repeated until the voltage V_Sacross the terminals of the reference capacitance C_Sattains the threshold voltage V_TH. The variable number of discharges (called n) required to attain the threshold represents an image of the capacitance C_X. The reference capacitance C_Sis thereafter completely discharged by closing the switch S in preparation for the next measurement.

Thus, according to document FR 2 938 344 A1, the variation ΔC_Xof the capacitance C_Xis no longer dependent on the capacitance C_Xof the electrode 4, but it is defined according to equation (4):

$\begin{matrix} Δ C_{X} = \frac{Th \times C_{M}}{x} & (4) \end{matrix}$

That is to say the variation ΔC_Xof the capacitance C_Xdepends on the measurement capacitance C_M, on the fixed number of discharges x of the electrode C_Xinto the measurement capacitance C_Sand on the detection threshold Th. And n, the variable number of discharges of the measurement capacitance C_Mto the reference capacitance C_Sis defined by:

$\begin{matrix} n = - \frac{C_{S} \times \ln (1 - \frac{V_{TH}}{V_{CC}}) + x \times C_{X}}{C_{M}} & (5) \end{matrix}$

The measurement capacitance C_Mbeing fixed, so is the fixed number of discharges x, and the detection threshold Th also being determined and fixed (since it is equivalent to a number of discharges n of the measurement capacitance C_Minto the reference capacitance C_Scorresponding to the threshold for detecting the driver's hand on the handle 6 of the door), it is therefore possible to choose the variation ΔC_Xof the capacitance C_Xby choosing in correspondence the values of C_M, x, and of Th, independently of the value of the capacitance C_X. Thus the variation ΔC_Xof the capacitance C_Xno longer depends on the value of this capacitance C_X.

However, a major drawback of this device is the presence of parasitic residual capacitances originating from the switches S3 and S4 used to charge and discharge the measurement capacitance C_M. The consequence of these residual capacitances is to limit the minimum value of the measurement capacitance C_M, below which the variation ΔC_Xof the capacitance C_Xcan no longer be improved (decreased). Generally, a switch exhibits a residual capacitance of 5 pF. The two switches S3 and S4 therefore exhibit an aggregate residual capacitance of 2×5=10 pF. The value of the measurement capacitance C_Mmust be chosen as a function of this cumulated residual capacitance, and generally its value is chosen to be equal to this residual capacitance, i.e. of the order of 10 pF. The variation ΔC_Xof the capacitance C_X(the smallest value of the variation ΔC_Xmeasurable) therefore attains a minimum when the measurement capacitance C_M=10 pF and it can no longer be optimized with the prior art device described in document FR 2 938 344 A1. In an exemplary use, if Th=5, if x=170 and if C_M=10 pF (minimum value due to the residual capacitances of the two switches S3 and S4), then the variation ΔC_Xof the capacitance C_Xis equal to 0.3 pF. Now, if it were possible to lower the value of the measurement capacitance C_M, the variation ΔC_Xof the capacitance C_Xwould be improved (decreased) proportionately but this is not possible since the circuit already exhibits a residual capacitance of 10 pF.

The invention proposes a device for measuring a variation ΔC_Xof a capacitance C_Xmaking it possible to alleviate this drawback. More precisely, the invention proposes a device in which the variation ΔC_Xof the capacitance C_Xis improved with respect to that obtained in the prior art.

Accordingly, the invention proposes a device for measuring a variation ΔC_Xof a capacitance, comprising:

- a supply voltage,
- means for charging the capacitance on the basis of the supply voltage,
- means for discharging the capacitance into a reference capacitance C_Sin a fixed number of discharges x,
- means for measuring a voltage V_Sacross the terminals of the reference capacitance C_S,
- means for detecting a threshold of voltage V_THacross the terminals of the reference capacitance C_S,
  
  the invention residing in the fact that the device furthermore comprises:
- means for charging with current the reference capacitance C_Son the basis of the supply voltage V_CCfor a duration t, after the capacitance C_Xhas been charged and discharged in a fixed number of discharges x into the reference capacitance C_S,
- means R_Cfor calibrating the current, charging the reference capacitance C_S,
- means for:
  - measuring the duration t with a temporal resolution Δt, and
  - computing the variation of this duration t with respect to a previously measured duration, this variation being representative of the variation ΔC_Xof the capacitance C_X.

According to the invention, a predetermined threshold of detection Th of a number of intervals of the temporal resolution over the duration t is defined, corresponding to the variation ΔC_Xof the capacitance.

Advantageously, the fixed number of discharges x of the capacitance to the reference capacitance C_Sis defined by:

$x = \frac{Th \times Δ t}{Δ C_{X} \times R_{c}}$

The duration t is defined by the duration required for the voltage V_Sacross the terminals of the reference capacitance C_Sto be equal to the voltage threshold V_THand is equal to:

$t = - R_{C} \times C_{S} \times \ln (\frac{V_{CC} - V_{TH}}{V_{CC} - V_{S} (x)})$

The measurement of the capacitance variation ΔC_Xis independent of the capacitance C_Xand is equivalent to:

$Δ C_{X} = \frac{Th \times Δ t}{R_{C} \times x}$

In a preferential embodiment, the reference capacitance C_Sexhibits a greater capacitance than that of the capacitance.

The invention also relates to any capacitive sensor for detecting the presence of a user of an apparatus, implementing a device for measuring a variation of the capacitance according to any one the characteristics hereinabove, such that the capacitance whose capacitance variation ΔC_Xis measured comprises a detection electrode disposed within said apparatus, the capacitance being measured between said detection electrode and a close environment of said detection electrode.

Judiciously, the apparatus in which the detection electrode is disposed is a door handle of a vehicle.

The invention applies to any motor vehicle comprising a capacitive sensor such as described previously as well as the associated method for measuring a variation ΔC_Xof the capacitance C_X.

Other characteristics and advantages of the invention will become apparent on reading the description which follows and on examining the appended drawings in which:

FIG. 1 represents a schematic view, described previously, of a door handle of a vehicle integrating a charge-transfer capacitive sensor,

FIG. 2 represents a schematic view, described previously, of a charge-transfer capacitive sensor according to the prior art,

FIG. 3 represents a schematic view of a charge-transfer capacitive sensor according to the prior art, described in FR 2 938 344 A1,

FIG. 4 represents a schematic view of a charge-transfer capacitive sensor, according to the invention.

The invention proposes the device, such as illustrated in FIG. 4, for measuring a variation ΔC_Xof the capacitance C_Xand which comprises, furthermore, a charge resistance R_C, placed between the supply voltage V_CCand the measurement capacitance C_S.

The charge transfer according to the invention breaks down into two phases: acquisition and measurement.

The acquisition phase is identical to that of the prior art. During this acquisition phase, the capacitance C_Xof the electrode 4 charges and discharges into the reference capacitance C_Sin a fixed number of discharges x, as described previously.

During the measurement phase, according to the invention, a charge current I_Cpassing through the charge resistance R_Ccharges the reference capacitance C_Suntil the voltage V_Sacross the terminals of the latter attains the threshold value V_TH.

The single step of this measurement phase consists in the charging of the reference capacitance C_Sby the charge current I_Cpassing through the charge resistance R_C. Accordingly, the third switch S3 is closed.

The first and the second switches S1 and S2 are open during this measurement phase. Consequently the capacitance C_Xof the electrode 4 is neither charged, nor discharged during this measurement phase.

Charging continues until the voltage V_Sacross the terminals of the reference capacitance C_Sattains the threshold voltage V_TH. The duration t of charging required to reach the threshold V_THrepresents an image of the capacitance C_X. The duration t is therefore measured between the closing of the third switch S3 and detection (that is to say the instant corresponding to V_S=V_TH). The charge current I_Ccharging the reference capacitance C_Sis constant and calibrated by passage through the charge resistance R_C.

By changing the value of the charge resistance R_C, the intensity of the charge current I_Calso changes as well as the duration t of charging into the reference capacitance C_S.

The reference capacitance C_Sis thereafter completely discharged by closing the switch S in preparation for the next measurement.

According to the invention, the equations governing the operation of the capacitive sensor 3 at low consumption are the following:

- during the acquisition phase, the evolution of the voltage V_Sacross the terminals of the reference capacitance C_Sis given by equation (1),
- during the measurement phase, the duration t of charging required in order that V_S=V_THis defined.

$V_{TH} = (V_{CC} - V_{S} (x)) \times (1 - e^{- \frac{t}{R_{C} \times C_{S}}}) + V_{S} (x)$

Which is equivalent to:

$\frac{V_{CC} - V_{TH}}{V_{CC} - V_{S} (x)} = e^{- \frac{t}{R_{C} \times C_{S}}}$

Then to:

$- \frac{t}{R_{C} \times C_{S}} = \ln (\frac{V_{CC} - V_{TH}}{V_{CC} - V_{S} (x)})$

And finally:

$\begin{matrix} t = - R_{C} \times C_{S} \times \ln (\frac{V_{CC} - V_{TH}}{V_{CC} - V_{S} (x)}) & (6) \end{matrix}$

The duration t is measured with a time base Δt, which is the temporal measurement precision of a clock of the printed circuit 5. This time base Δt (or temporal resolution) is therefore fixed by the clock of the printed circuit 5. The number of intervals of precision At included in the duration t is called y, i.e. y=t/Δt, and we obtain:

$y \times Δ t = - R_{C} \times C_{S} \times \ln (\frac{V_{CC} - V_{TH}}{V_{CC} - V_{S} (x)})$

Which is equivalent to:

$y \times Δ t = - R_{C} \times C_{S} \times \ln (\frac{V_{CC} - V_{TH}}{V_{CC} - V_{CC} \times (1 - {(1 - \frac{C_{X}}{C_{S}})}^{x})})$

$Then, y \times Δ t = - R_{C} \times C_{S} \times \ln (\frac{V_{CC} - V_{TH}}{V_{CC} \times {(1 - \frac{C_{X}}{C_{S}})}^{x}})$

Isolating y, we obtain:

$y = - \frac{R_{C} \times C_{S}}{Δ t} \times [\ln (1 - \frac{V_{TH}}{V_{CC}}) - \ln ({(1 - \frac{C_{X}}{C_{S}})}^{x})]$

$Then, y = - \frac{R_{C} \times C_{S}}{Δ t} \times [\ln (1 - \frac{V_{TH}}{V_{CC}}) - x \times \ln (1 - \frac{C_{X}}{C_{S}})]$

The finite series expansion of

$\ln (1 - \frac{C_{X}}{C_{S}}) ≅ - \frac{C_{X}}{C_{S}},$

since the value of the reference capacitance C_Sis appreciably greater than the value of the capacitance C_Xof the electrode 4. We thus obtain:

$y = - \frac{R_{C} \times C_{S}}{Δ t} \times [\ln (1 - \frac{V_{TH}}{V_{CC}}) + x \times \frac{C_{X}}{C_{S}}]$

$Then, y = - \frac{R_{C}}{Δ t} \times [C_{S} \times \ln (1 - \frac{V_{TH}}{V_{CC}}) - x \times C_{X}]$

We define Th to be the variation of y giving rise to a detection, hence Th is equivalent to:

$Th = \frac{R_{C}}{Δ t} \times [- C_{S} \times \ln (1 - \frac{V_{TH}}{V_{CC}}) - x \times C_{X} + C_{S} \times \ln (1 - \frac{V_{TH}}{V_{CC}}) + x \times (C_{X} + Δ C_{X})]$

i.e. also:

$Th \times \frac{Δ t}{R_{C}} = x \times Δ C_{X}$

And finally:

$\begin{matrix} Δ C_{X} = \frac{Th \times Δ t}{Δ C_{C} \times x} & (7) \end{matrix}$

Thus, according to equation (7) of the invention, the variation ΔC_Xof the capacitance C_X, is determined by:

- the fixed number of discharges x of the acquisition cycle,
- the value of the charge resistance R_C, and
- the time base Δt (temporal resolution of the printed circuit 5 clock).

It is thus possible to increase the value of the charge resistance R_Cso as to improve the variation ΔC_Xof the capacitance C_X, that is to say so as to improve the sensitivity of the capacitive sensor 3.

It is also possible, by way of software, to reduce the temporal resolution At of the clock of the printed circuit 5 so as to improve the variation ΔC_Xof the capacitance C_X.

The advantage of the invention is therefore a reduction in detection time (and therefore a reduction in the consumption of the capacitive sensor 3) with respect to the prior art and/or an increase in detection precision due to the reduction in the variation ΔC_Xof the capacitance C_Xof the electrode 4 which is measurable by the capacitive sensor 3.

An example of gain in time and precision is illustrated hereinbelow.

Consider a capacitive sensor 3 with the following characteristics:

- C_X=35 pF,
- Th=5,
- V_TH=1.1V,
- V_CC=3.3V,
- C_S=20 nF,
- x=170.

According to the solution of the prior art, that is to say according to the invention described in FR 2 938 344 A1, by using a measurement capacitance C_M, of minimum value, i.e. C_M=10 pF (residual capacitance), then according to equation (5), the number n of charge transfers until V_S=V_TH, is equal to n=215.

And the total cycle number N=(n+x) to carry out the charge transfer is equal to 385. With a clock having a resolution of Δt=2 μs, a charge transfer lasts 12 μs. The duration of the 385 charge transfers, that is to say the duration of detection is therefore 4.6 ms (385×0.12). And according to equation (4), the variation ΔC_Xof the capacitance C_Xis equal to ΔC_X=0.3 pF.

According to the invention of the present patent application, by fixing the charge resistance R_C=200 kΩ and a resolution of the clock of the printed circuit 5 identical to that of the previous example (Δt=2 μs), then:

- V_S(x) according to equation (1) equals V_S(170)=0.849 V,
- according to equation (6), the duration t is equal to t=430 μs, i.e. 0.43 ms,
- the duration of the x=170 charge transfers of the capacitance C_Xinto the reference capacitance C_Sis equal to 2.04 ms (170×0.12),
- the total duration of detection is therefore equal to 2.47 ms (2.04+0.43) i.e. a duration of detection 1.84 times shorter than that of the prior art (4.6 ms).

The charge transfer device according to the invention makes it possible to significantly reduce the measurement time t and consequently the consumption of the capacitive sensor 3.

In another example, by increasing the value of the charge resistance R_Cto R_C=800 kΩ so as to decrease the value of the variation ΔC_Xof the capacitance C_X, then:

- according to equation (6), the variable duration t=1.723 ms, and
- the total duration of detection is equal to 3.76 ms (1.723+2.04), i.e. a duration 0.82 times shorter than that of the prior art (4.6 ms), and variation ΔC_Xof the capacitance C_X, according to equation (7) is equal to ΔC_X=0.073 pF, i.e. a variation ΔC_Xdivided by four with respect to that of the prior art.

The invention therefore allows faster and/or much more precise detection of approach of the user's hand by the capacitive sensor than the prior art solution described in document FR 2 938 344 A1.

The invention is not limited to the embodiments described. In particular, the invention applies to any device for measuring a variation of a capacitance and is not limited to the detection of the approach of a user's hand to a door handle of a vehicle.

LOW CONSUMPTION DEVICE FOR MEASURING A VARIATION OF A CAPACITANCE AND ASSOCIATED METHOD

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