FR2756048A1 - FLOATING CAPACITIVE MEASUREMENT BRIDGE AND ASSOCIATED MULTI-CAPACITIVE MEASUREMENT SYSTEM - Google Patents

Abstract

Floating capacitive measuring bridge (10) comprising a capacitive sensor (C) comprising a measuring electrode (15), a guard electrode (17) surrounding said measuring electrode (15), and an earth electrode (16), a charge amplifier (3), a chain for processing the output signal of the charge amplifier (3, 23, 33, 43) to deliver a capacitive measurement signal with respect to an earth reference, and a device for supply (100) of the charge amplifier (3) with respect to the floating potential (PF) of the guard electrode (17). The charge amplifier (3) further comprises an excitation capacitor (7) connected on the one hand to the first input (-) and on the other hand to an excitation device (5, 8, 13 ) to produce an excitation signal at a predetermined frequency. The charge amplifier (3) and the feedback (6) and excitation (7) capacitors are included in a full guard (2) connected to the guard electrode (17). Use, in particular, for deviation gauges or thickness sensors.

Description

"Floating capacitive measuring bridge and measuring system
associated multi-capacitive "
DESCRIPTION
The present invention relates to a floating capacitive measuring bridge. It also relates to a multi-capacitive measurement system produced from measurement bridges according to the invention.

 In capacitive measurement systems, to guarantee satisfactory characteristics of accuracy, dynamics and resolution of the sensors, it is essential to minimize the influence of stray capacitances linked to the charge amplifier placed downstream of the capacitive sensor and to the connections entry. A known solution consists in not referencing the charge amplifier to earth, but to supply it by a floating DC voltage source with high resistive and capacitive electrical insulation1 relative to earth, the assembly being included in a guard. brought to the potential of the sensor guard as taught in French patent application n086 17898.

 This document thus discloses a capacitive dimensional measurement chain in which the charge amplifier is not referenced to earth but supplied by a floating DC voltage source with high resistive and capacitive electrical isolation from earth, all being included. in a guard brought to the guard potential of the capacitive sensor. This capacitive measurement chain includes a power transformer whose windings are coaxial conductors. The conductor of the primary winding of this transformer is connected to the output of a sinusoidal generator.

 Furthermore, the document FR 2640373 describes a capacitive dimensional measurement chain with linear output.

This measurement chain includes a bias voltage source using a triaxial transformer.

The measurement circuit of this chain includes a charge amplifier, a level amplifier, a synchronous demodulator and an integrator. The secondary of the triaxial transformer is placed between the capacity to measure and the charge amplifier, the primary of this triaxial transformer being connected to a synchronous modulator. The negative input of the charge amplifier is subjected to a reference alternating voltage through an excitation capacitor. The reference voltage source, the synchronous modulator and the synchronous demodulator are synchronized by the same time base.

 The disclosed capacitive bridges however have the drawback of requiring the use of a triaxial isolation transformer, which leads to high costs and constitutes an obstacle to any integration of the electronics within a sensor device.

 The object of the invention is to remedy these drawbacks by proposing a floating capacitive measuring bridge, which allows easy integration of the electronics, while being less costly to produce.

It is a floating capacitive measuring bridge comprising:
- a capacitive sensor comprising a first
measuring electrode, a guard electrode
surrounding said measurement electrode, and a
earth electrode
- a charge amplifier having a first input
(-) connected to the measuring electrode and a second
input (+) connected to the guard electrode, and
having a feedback capacitor
arranged between its first entry and its exit,
means for processing the output signal from
the charge amplifier, in order to deliver a
capacitive measurement signal with respect to a
earth reference, and
- Means for supplying said amplifier
charge with respect to the floating potential of
the guard electrode.

 According to the invention, the charge amplifier further comprises an excitation capacitor connected on the one hand to its first input (-) and on the other hand to means for producing an excitation signal at a predetermined frequency, and the charge amplifier and the feedback and excitation capacitors are included in a full guard connected to the guard electrode.

 There was thus obtained, for a floating capacitive bridge according to the invention, a consumption of approximately 2.5 mA under a supply voltage of 30 V with a carrier frequency equal to 4 kHz. It even becomes possible to reduce the supply voltage of the charge amplifier to 15 V, if protection is provided for it.

This consumption can thus reach 0.2 mA at a voltage of + 2.5 V. I1 then becomes possible to integrate the conditioning electronics within the sensor.

In a floating bridge according to the invention, the processing means preferably comprise
- means for amplifying the output signal from
charge amplifier,
- means for demodulating the output signal
amplified in synchronism with the means
of excitement,
- and means for integrating the demodulated signal into
view of delivering a measurement signal.

 These processing means further comprise differential amplification means inserted at any point of the processing chain, and having, on the one hand, their input referenced to the floating potential, and on the other hand, their output referenced to the ground. .

The excitation means generally comprise
- oscillator means for delivering a voltage
oscillation at a predetermined frequency,
- first switching means for applying to
the measuring electrode via the capacitor
excitation, i.e. a modulation voltage from
synchronous modulating means, i.e. the voltage
oscillation from the oscillator means, and
- second switching means for applying to
the guard at floating potential, i.e. the voltage
oscillation, or the modulation voltage.

The first and second switching means cooperate to provide either of the following measures
- a measure representative of the inverse of a
capacity, when the floating potential is at the
modulation voltage, and
- a measure representative of a capacity, when the
floating potential is at the oscillation voltage.

 Thus, when the capacitive bridge according to the invention is provided for measuring a capacity, the oscillator means control the floating potential. When the capacitive bridge is provided for measuring the inverse of a capacity, in particular for measuring the distance with a capacitive sensor, modulator means placed downstream of the demodulator means and integrator means placed in cascade, ensure the control of the floating potential.

These modulating means are synchronized by the oscillating means. When the capacitive bridge according to the invention is intended to carry out the two aforementioned types of measurement, it then comprises switching means for applying to the guard a floating potential coming from either oscillating means for measuring a capacity, or means modulators for measuring the inverse of a capacity.

 In a first embodiment corresponding to a fully floating capacitive bridge, the guard contains the charge amplifier, amplification means, the demodulation means, and integrator means downstream of said charge amplifier, and the means of differential amplification have their first differential input connected to the output of said integrating means. The oscillator means and the modulator means are preferably included in the guard. The floating capacitive bridge further comprises an excitation capacitor disposed between the negative input of the charge amplifier and the output of the means generating the floating potential, and switching means for connecting the excitation capacitor, either to the oscillator means. , or with modulating means.

 With a capacitive bridge of this type, a consumption of approximately 20 mA has been obtained experimentally under a supply voltage of 30 V, with a square carrier of 4 kHz. For a 50 kHz sinusoidal carrier, the power consumption is approximately 40 mA. When the carrier frequency reaches 1.2 MHz, the power consumption is only about 120 mA.

 In a second embodiment corresponding to a semi-floating capacitive bridge, the guard contains the charge amplifier, amplification means and the demodulation means downstream of said charge amplifier, the differential amplification means have their first differential input directly connected to the output of said demodulator means, and this capacitive bridge further comprises, downstream of said differential amplification means, integrator means at the output of which the output voltage of the capacitive bridge is taken. In this embodiment, the oscillator means are located outside the guard.

 In a third embodiment corresponding to a capacitive bridge with low energy consumption, the guard contains the charge amplifier and amplification means downstream of it, the differential amplification means have their first differential input directly connected to the output of said amplification means, and this capacitive bridge further comprises, downstream of said differential amplification means, the demodulator means and integrator means at the output of which the output voltage of said capacitive bridge is taken.

 In a fourth embodiment corresponding to an energy consumption in situ, the guard contains the charge amplifier, the differential amplification means have their first differential input directly connected to the output of said charge amplifier, and this method comprises in addition, downstream of said differential amplification means, amplification means, demodulator means and integrator means at the output from which the output voltage of the capacitive bridge is taken.

 According to another aspect of the invention, there is provided a multi-capacitive measurement system produced from a set of floating bridges according to the invention, comprising a set of capacitive sensors associated with a set of charge amplifiers. This system further comprises a single processing chain and multiplexer means having their multiple inputs connected at the output of said charge amplifiers and their output connected at the input of said processing chain.

 It is also possible to provide a multicapacitive measurement system produced from a floating bridge according to the invention, comprising a set of capacitive sensors, characterized in that it also comprises a single charge amplifier and its associated processing chain, and multiplexer means having their multiple inputs connected to the output of said capacitive sensors and their output connected to the input of said charge amplifier, the respective electrodes of said capacitive sensors being surrounded by a common guard electrode.

Other features and advantages of the invention will appear in the description below. In the appended drawings given by way of nonlimiting examples:
- Figure 1 is a diagram of a capacitive bridge
fully floating according to the invention;
- Figure 2 is a diagram of a semi capacitive bridge
floating according to the invention ;;
- Figure 3 is a diagram of a capacitive bridge
floating with low consumption according to the invention;
- Figure 4 is a diagram of a capacitive bridge
minimum floating according to the invention;
- Figure 5 illustrates an exemplary embodiment of a
floating power supply implemented in a bridge
floating capacitive according to the invention; and
- Figure 6 is a diagram of a measurement system
multi-capacitive according to the invention produced under the
form of a hybrid circuit combining components
analog and a digital circuit.

 We will now describe several embodiments of a floating capacitive bridge according to the invention, with reference to the aforementioned figures.

 In a first embodiment shown in FIG. 1, a fully floating capacitive bridge 10 comprises a floating part 1 in a guard 2 and a differential amplifier 14 delivering an output voltage Vs. The floating part 1 comprises an amplifier 3 mounted as a capacitive bridge , having its negative input connected to a first electrode 15, called the measurement electrode, (with a capacity to measure C, the other electrode 16 of which is connected to a reference ground), and its positive input connected to a total guard 2 which has a floating potential with respect to the earth and is which is electrically connected, for example by a coaxial sheath, to a guard electrode 17 surrounding the measurement electrode 15. The output of the operational amplifier 3 is connected on the one hand, at its negative input through a capacitor 6 according to a conventional capacitive bridge diagram, and on the other hand, at the input of an amplifier 4 upstream successively nt of a demodulator 9, an integrator 11 and a modulator 12. The demodulator 9 and the modulator 12 are controlled by an oscillator 5 also present in the guard 2 and referenced to earth.

The various elements referenced to floating potential
PF are supplied by a continuous / continuous conversion unit 100 disposed outside of the floating part 1, this unit receiving, for example, a voltage Vcc with respect to the reference mass (earth) and delivering, in floating mode , a positive continuous supply voltage V + and a continuous supply voltage V- with respect to the floating potential PF of the enclosure. The differential amplifier 14 external to the floating part 1 receives as input on the one hand, the output signal of the integrator 11, and on the other hand, the floating potential PF. This differential amplifier 14 must provide excellent common mode rejection at the oscillation frequency.

 Switches 8, 13 are also provided within the floating part 1 to apply to the negative input of the charge amplifier 3 through an excitation capacitor 7, ie the output voltage of the oscillator 5 in order to d '' obtain an image output voltage of the inverse of the capacitance C, i.e. the output voltage of the modulator 12 in order to obtain an image output voltage of the capacitance C.

 In a second embodiment according to the invention, corresponding to a semi-floating capacitive bridge 20, with reference to FIG. 2, the floating part 27 includes, inside a total guard 22, an operational amplifier 23 whose input negative is connected to a measuring electrode 15 of the capacitance to be measured C and whose positive input is connected to the total guard 22 to which is also connected a guard electrode 17 of the capacitance to be measured C, a capacitor 26 being conventionally disposed between the output and the negative input of this operational amplifier. The output signal from the operational amplifier 23 is applied to the input of an amplifier 24, the output of which is connected to the input of a demodulator 29 in the floating part 27.

The output of the demodulator 29 is applied, outside the floating part 27, to an input of a differential amplifier 28, the other input of which is at the potential PF of the floating part 27. The output of the differential amplifier 28 is applied at the input of an integrator 21 at the output of which the output Vs of the capacitive bridge 20 is taken. The output of the integrator 21 is also applied at the input of a modulator 212 whose output can be applied, via a switch 250, to the floating part 27 to determine the floating potential PF when the bridge is used to make measurements representative of the inverse of the capacity. An oscillator 25 located outside the floating part 27, controls both the modulator 29 and the demodulator 212. The output voltage of the oscillator 25 can also be applied to the floating part 27 by means of the switch 250, when the capacitive bridge 20 is provided for carrying out measurements representative of the capacity to be measured.

 A switch 206 is also provided within the floating part 27 to apply to the negative input of the charge amplifier 23 through an excitation capacitor 205, ie the output voltage of the oscillator 25 supplied in floating mode by a differential amplifier 204 in order to obtain an image output voltage of the inverse of the capacitance C, ie the output voltage of the modulator 212 supplied in floating mode by a differential amplifier 203 in order to obtain an image output voltage of capacity C.

 As in the first embodiment described above, the capacitive bridge 20 is provided with a DC / DC conversion unit 100 to supply inside the guard 22 the DC voltages necessary to supply the electronic components, in particular the charge amplifier 23, gain amplifier 24 and demodulator 29.

 The semi-floating capacitive bridge 20 which has just been described, in which only the operational amplifier, the amplifier and the demodulator are placed in the floating part 27, is particularly suitable when it is necessary to minimize the consumption of electrical energy in the guard.

In a third embodiment corresponding to a low-consumption floating capacitive bridge 30 with reference to FIG. 3, only the charge amplifier 33 and the amplifier 34 are included in the floating part 37 and are supplied in floating mode by a continuous conversion unit 100. Only the charge amplifier 33 and its two feedback 36 and excitation 305 associated capacitors are provided with full guard 32. The other components of the capacitive bridge are external to the floating part 37 and referenced to the earth. The total guard 32 includes the charge amplifier 33 which has its negative input connected to an electrode 15 of the capacity to measure C and its positive input directly connected to the guard and thus placed at the floating potential.
PF, its output being connected to its negative input by the feedback capacitor 36 according to a conventional diagram. The floating part 37 also includes the voltage amplifier 34, the output of which is connected to an input of a differential amplifier 38, the other input of which is connected to the floating potential PF. This differential amplifier 38, referenced with respect to the earth, delivers an output signal which is applied to a demodulator 39 upstream of an integrator 31 and of a modulator 312 whose output voltage can be applied, depending on the state a switch 350, on guard 37 as floating potential, in the case of a measurement representative of the inverse of the capacity. The demodulator 39 and the modulator 312 are both synchronized by an oscillator 35 referenced to earth.

The output voltage of oscillator 35 can also be applied, via switch 350, to the mass of floating part 37 to determine the floating potential.
PF. A second switch 306 makes it possible to apply to the negative input of the charge amplifier 33, through the excitation capacitor 305 and a differential amplifier 303 included in the floating part 37, ie the output voltage of the oscillator 35 in the case of a measurement representative of the inverse of the capacitance C, ie the output voltage of the modulator 312 in the case of a measurement representative of the capacitance C.

 This embodiment of a floating capacitive bridge is particularly suitable when it comes to considerably reducing the electrical energy consumed in the floating part. In fact, if the input of the operational amplifier is protected, it becomes possible to reduce the supply voltage and consequently reduce consumption in situ. The common mode of the differential amplifier 38, however, generates an additional measurement error.

 In a fourth embodiment of a floating capacitive bridge 40 according to the invention, with reference to FIG. 4, only the charge amplifier 43, the feedback capacitor 46 and the excitation capacitor are included in a total guard 42 and supplied in floating mode by a continuous / continuous conversion unit 100. All the other components of the capacitive bridge are located outside this guard 42 and referenced to earth. A differential amplifier 48 has one of its inputs connected to the output of the operational amplifier 43 and its other input connected to the total guard 42. The output of the differential amplifier 48 is amplified in an amplifier 44, then applied to a demodulator 49 upstream of an integrator 41 and a modulator 412. An oscillator 45 controls the demodulator 49 and the modulator 412, the output of which can be connected, as a function of the respective states of a first switch 406 and of a second switch 450, either at full guard 42 to determine the floating potential PF, or at the input of a differential adapter 403 located in a floating part 47, to inject via the excitation capacitor 405 an excitation signal on the first input of the charge amplifier 43. This embodiment has the advantage of leading to minimal consumption in situ. In addition, if protection for the operational charge amplifier 43 is provided, the supply voltage can then be reduced.

However, a differential amplifier of low input noise will preferably be used, the error generated by the common mode of the differential amplifier 48 being multiplied by the gain of the amplifier 44, by comparison with the capacitive bridge shown in FIG. 3.

 The DC power supply units intended for supplying the floating circuits of the electronic circuits arranged in the guard can be produced using different technologies, provided that they have an input-output electrical charge of value greater than the minimum load that the excitation means, in this case either the oscillator for capacitance measurements, or the modulator for capacitance inverse measurements. We can thus consider electronic DC / DC conversion units available for example in the form of DIL, CMS or other boxes, solar cells, cells or batteries. It is also possible to provide a supply in floating mode of an electronic circuit with switched capacities, preferably in integrated form, or else a supply (V +, V- / + Vcc, -Vcc) 200 comprising, according to a known structure illustrated in FIG. 5, shock inductors L coupled with capacitances at bridge C.

 Furthermore, in order to reduce the leaks due to line effects at the input of a floating capacitive bridge according to the invention, it is possible to envisage the use of a monitoring of the measurement electrode. This has the effect of considerably reducing phase and quadrature leaks due to the sensor-electronic line and to the measurement frequency.

 It is also possible to provide for a multi-capacitive measurement system implementing a multiplexing of different measurement channels, a single guard being provided for the different measurement electrodes. This multiplexing can be carried out either upstream of a single charge amplifier, or downstream of a set of charge amplifiers each dedicated to a single capacitive sensor. This second option makes it possible to increase the speed of multiplexing.

 Such a multi-capacitive measurement system can advantageously be produced in the form of a hybrid circuit associating analog components and a microcircuit, as illustrated in the diagram of FIG. 6.

The multi-capacitive measurement system 60, which can also be designated under the term of tomographic bridge "C and 1 / C", thus comprises:
a multiplexer circuit 70 comprising, by way of nonlimiting example, 32 measurement inputs connected to as many measurement electrodes (not shown), a control bus input BC, and a carrier EPM input for this multiplexer;
a charge amplifier A1, the inverting input of which is connected to the output of the multiplexer circuit 70, the non-inverting input being connected to ground;
- a DC / DC 100 power supply to provide floating power supplies, and
a microcontroller 80 for controlling the various components of the system and for processing the analog signals measured.

 It is also possible to provide a floating power supply generated by a DC / DC converter placed outside the hybrid circuit 60 which then has three inputs provided for this purpose.

The microcontroller 80 integrates a control and processing unit 86, a memory 81 of EEPROM type, a random access memory 82 of RAM type, an analog / digital converter 83 having a resolution of 12 bits, a clock 84, a divider 85, and a serial link circuit (which can be optional). The control and processing unit 85 (CPU) generates commands transmitted on an internal control bus BC to the multiplexer circuit 70, and a command signal from the switches.
S1, S2, S3 which respectively have the following functions: demodulation, modulation and oscillator.

 A DC / DC 100 power supply module provides, from an external + 5V voltage source, + 5V and -5V floating power supplies for internal use within the hybrid circuit 60.

The hybrid circuit or mixed bridge 60 has several outputs, in particular analog outputs: an output
TEST (amplifier output test), an analog output SA, a reference voltage output Vref, a modulator output MOD and an inverted output MOD, and a digital output of the serial link circuit 87. It has several inputs, in particular analog inputs (for example 32 in number), a multiplexer carrier EPM input, and two Cext pins to connect an external capacitor. The hybrid circuit 60 also includes an amplifier mounted as a SUI follower, a temperature probe 71, a circuit 73 for generating a reference voltage Vref and a Cref pin for connection to a reference capacitor for the charge amplifier.

 The analog / digital converter 83 within the digital circuit 80 receives as input via a multiplexer 88 either an analog signal from the analog processing chain downstream of the charge amplifier Al, or an analog signal emitted by the temperature probe 71, and the reference voltage Vref. The internal switches S1, S2 and S3 respectively demodulator, modulator and oscillator, are controlled by the divider circuit 85.

 The output of the head multiplexer 70 as well as the capacitor C2 is surrounded by a guard 74 connected to ground. The analog and digital components of the composite bridge 60 are supplied in floating mode thanks to the DC / DC 100 power supply.

 The composite bridge 60 can be used either in "C" mode or in "1 / C" mode. In "C" mode, the follower is powered by the oscillator, while in "1 / C" mode, it is powered by the modulator, by cables (not shown) external to the hybrid circuit.

 The mixed bridge 60 operates as a synchronous demodulator.

The amplitude of the carrier is approximately 5 Vpp or twice using two Zener diodes. The frequency can be between 4 kHz and 20 kHz, with a bandwidth of 1 kHz for one channel. The noise (peak to peak) corresponds to 10-5 pF at a frequency of 1 kHz.

 When operating in floating mode, the galvanic isolation of the serial link can be ensured by means of optocouplers.

 The hybrid circuit which has just been described can advantageously be produced by using SOI (silicon on insulator) technology.

 Of course, the invention is not limited to the examples which have just been described and numerous modifications can be made to these examples without departing from the scope of the invention. Thus, the electrodes of the capacitive sensors can have any shape and structure. Furthermore, the electronic components used in the processing chain can be chosen without any other limitation than usual considerations of precision and cost.

Claims (18)

 1. Floating capacitive measuring bridge (10, 20, 30, 40) including  - a capacitive sensor (C) comprising an electrode  measure (15), a guard electrode (17) surrounding  said measuring electrode (15), and a measuring electrode  earth (16),  - a charge amplifier (3, 23, 33, 43) having a  first input (-) connected to the measuring electrode  (15) and a second input (+) connected to the electrode  guard (17), and comprising a capacitor  feedback (6, 26, 36, 46) disposed between its  first entry (-) and exit,  - means (4, 24, 34, 44; 9, 29, 39, 49; 11, 21, 31,  41) to process the output signal from  the charge amplifier (3, 23, 33, 43), in order to  deliver a capacitive measurement signal with respect to  an earth reference, and  - means (100) for supplying said amplifier  load (3, 23, 33, 43) with respect to the potential  floating (PF) of the guard electrode (17),  characterized in that the charge amplifier (3, 23, 33, 43) further comprises an excitation capacitor (7, 205, 305, 405) connected on the one hand to the first input (-) and on the other hand to excitation means (5, 8, 13; 25, 206, 250, 203, 204; 35, 306, 350, 303; 45, 450, 406, 403) to produce an excitation signal at a predetermined frequency, and in that said charge amplifier (3, 23, 33, 43) and the feedback (6, 26, 36, 46) and excitation (7, 205, 305, 405) capacitors are included in a total guard (2, 22, 32, 42) connected to the guard electrode (17).  2. A floating bridge (10, 20, 30, 40) according to claim 1, the processing means of which comprise  - means (4, 24, 34, 44) for amplifying the signal  charge amplifier output (3, 23, 33,  43),  - means (9, 29, 39, 49) for demodulating the signal  output amplified in synchronism with the means  excitement (5, 25, 35, 45),  - And means (11, 21, 31, 41) to integrate the  demodulated signal to deliver a signal  measurement (Vs), characterized in that these processing means further comprise differential amplification means (14, 28, 38, 48) inserted at any point of the processing chain, and having on the one hand, their input referenced to floating potential (PF), and secondly, their output referenced to earth.  3. Floating bridge (10, 20, 30, 40) according to claim 2, the processing means of which further comprise, downstream of the integrating means (II, 21, 31, 41), means (12, 212, 312 , 412) to modulate the integrated signal in synchronism with the excitation means, characterized in that these excitation means comprise  - oscillator means (5, 25, 35, 45) for  deliver an oscillation voltage at a frequency  predetermined,  - first switching means (8, 206, 306, 406)  to apply to the measuring electrode (15) via  the excitation capacitor (7, 205, 305, 405)  either a modulation voltage from the means  synchronous modulators (12, 212, 312, 412), i.e. the  oscillation voltage from oscillator means  (5, 25, 35, 45), and  - second switching means (8, 206, 306, 406)  to apply on the guard (2, 22, 32, 42), either  the oscillation voltage, i.e. the voltage of  modulation;  The first (8, 206, 306, 406) and second (8, 206, 306, 406) switching means cooperating to provide one or the other of the following measures  - a measure representative of the inverse of a  capacity, when the floating potential (PF) is at  the modulation voltage, and  - a measure representative of a capacity, when the  floating potential (PF) is at voltage  oscillation.  4. Floating bridge (10) according to claim 3, characterized in that the oscillator means (5) and the processing means (4, 9, 11, 12) are referenced to the floating potential (PF) and are supplied by the means floating power supply (100).  5. Floating bridge (10) according to claim 4, characterized in that the differential amplification means (14) are arranged downstream of the integration means (11) and output the capacitive measurement signal (Vs).  6. Floating bridge (20) according to claim 3, characterized in that the amplifier means (24) and the synchronous demodulator means (29) are referenced to the floating potential (PF), the oscillator means (25), the integrator means ( 21) and the modulator means (212) are referenced to the earth, and in that the differential amplification means (28) are arranged between the output of the demodulator means (29) and the input of the integrator means (21).  7. Floating bridge (20) according to claim 6, characterized in that the excitation means further comprise first differential adaptation means (204) disposed between on the one hand the output of the oscillator means (25) and d on the other hand, a control input of the demodulator means (29) and a first input pole of the first switching means (206), and second differential adaptation means (203) arranged between the output of the modulator means (212) and a second input pole of said first switching means (206)  8. Floating bridge (30) according to claim 3, characterized in that the amplifying means (34) are referenced to the floating potential (PF) and are supplied by the floating supply means (100), and in that the means differential amplification (38) are arranged between the output of the amplifier means (34) and the input of the demodulator means (39).  9. Floating bridge (40) according to claim 3, characterized in that the differential amplification means (48) are arranged at the output of the charge amplifier (48).  10. Floating bridge (30, 40) according to one of claims 8 or 9, characterized in that the excitation means further comprise differential adaptation means (303, 403) disposed between the output of the first switching means (306, 406) and the excitation capacitor (305, 405).  11. Floating bridge (10, 20, 30, 40) according to one of the preceding claims, characterized in that the floating supply means (100) comprise shock inductors.  12. Floating bridge (10, 20, 30, 40) according to one of claims 1 to 10, characterized in that the floating supply means (100) comprise switched capacities.  13. Floating bridge (10, 20, 30, 40) according to one of claims 1 to 10, characterized in that the floating supply means (100) comprise electronic DC / DC conversion units.  14. Floating bridge (10, 20, 30, 40) according to one of claims 1 to 10, characterized in that the floating supply means (100) comprise cells, batteries, or solar cells.  15. Multi-capacitive measurement system produced from a set of floating bridges according to one of the preceding claims, comprising a set of capacitive sensors associated with a set of charge amplifiers, characterized in that it comprises further a single processing chain and multiplexer means having their multiple inputs connected at the output of said charge amplifiers and their output connected at the input of said processing chain.  16. Multi-capacitive measurement system produced from a floating bridge according to one of claims 1 to 14, comprising a set of capacitive sensors, characterized in that it further comprises a single charge amplifier and its chain associated processing, and multiplexer means having their multiple inputs connected at the output of said capacitive sensors and their output connected at the input of said charge amplifier, the respective electrodes of said capacitive sensors being surrounded by a common guard electrode.  17. Multi-capacitive measurement system according to claim 16, characterized in that it further comprises digital control and processing means programmed to control said system and to provide capacitive measurement data in digitized form.  18. System according to claim 17, characterized in that its analog and digital components are produced within a single hybrid circuit.