FR2624325A1 - Correcter amplifier, in particular for high bit rate baseband digital links - Google Patents

Abstract

The correcter-amplifier applies, in particular, to high bit rate baseband digital links over wire line or cable. It comprises plural high-pass filtering stages with operational amplifier, which are mounted in series and assigned to the correction of different parts of the transmission band. The output S1 of such a stage ET1 is earthed through a network of resistors RA to RT mounted in series with a battery of switchable parallel capacitors CJ-1 whilst an intermediate point of the resistor network is connected to the inverting input of the operational amplifier AO1 by a jumper V1. The batteries of capacitors of the successive stages are different, whilst the network of resistors is identical for all the stages.

Description

CORRECTOR AMPLIFIER, IN PARTICULAR FOR LINKS
HIGH SPEED BASIC BAND DIGITAL.

The invention relates to an amplifier-corrector which applies, in particular, to digital links in baseband, at high speed, on wire or cable line.

An amplifier-corrector of this kind and allowing a lower flow rate is described in French Patent Application No. 85 05735 in the name of the Applicant. This amplifier comprises input and output circuits, intended to be connected respectively to the upstream and downstream sides of the link, and, between these, selective amplification means intended to compensate for the unevenness of signal transmission on the link in frequency function.

In the prior application, the means of selective amplification comprise corrective cells which, each one, makes it possible to compensate for the distortion of the line in a particular frequency zone. These cells comprise a network of diodes in which a variable current is passed, making the diodes more or less conductive and acting on their dynamic resistance therefore on the gain of each cell.

This adjustment principle can be either manual, by inserting resistors, or automatic and is difficult to implement. In addition, it does not make it possible to obtain a fine and absolutely independent adjustment from one cell to another because the control current acts globally on the entire array of diodes. This is a drawback when one wants to effectively correct lines whose length can be large and variable and which can, moreover, have sections of different diameter. In this case, the weakening curve can then have a complex shape as a function of the frequency and will not be effectively corrected by an amplifier of the type described in the patent application cited above.

In addition, this amplifier-corrector only effectively corrects lines carrying an information rate of between 2.4 and 144 kilobits per second. Nowadays, information rates of the order of 2,000 kilobits per second can be used.

Thus, an object of the invention is to provide a correcting amplifier making it possible to correct, in a precise manner, the attenuation characteristics of cables while offering an extremely simple gain adjustment.

Another object of the invention is to be able to adapt to extremely long lines and which may have a variable diameter depending on the sections, which requires a selective adjustment of the gain according to the section considered.

The object of the invention is also to relay digital links in baseband of rate between 64 and 2048 kilobits per second.

The subject of the invention is therefore an amplifier-corrector, in particular for digital baseband links on wire or cable line, such as a symmetrical metallic pair, of the type comprising - input and output circuits, intended to be connected respectively to the upstream and downstream sides of the link, and between them, - selective amplification means intended to compensate for the unevenness of signal transmission on the link, as a function of frequency, characterized in that that these selective amplification means comprise several stages of high-pass filtering with operational amplifier connected in series, each stage comprising an input connected to the non-inverting input of the operational amplifier, and an output, connected to the output of the operational amplifier, as well as to ground through a potentiometric means connected in series with a switchable parallel capacitor bank, while an intermediate point of the potentiometric means is connected to the inverting input of the amplifier, and in that the capacitor banks of the successive stages are different, these stages being thus assigned to correct different parts of the transmission band.

Advantageously, the potentiometric means of a stage consists of a series of resistors in series, identical for all the stages, and of a switch, such as a jumper, allowing the connection of the common point of two resistors of each sequence at the inverting input of the corresponding amplifier, the parallel capacitors also being switchable using switches such as jumpers.

According to one aspect of the invention, the link between the stage input and the non-inverting input of the associated operational amplifier comprises a switchable attenuator, making it possible to bring the signal back into the dynamic range acceptable for the operational amplifier associated.

Preferably, the first of the high-pass filtering stages is provided, at its input, with a DC component suppression, while the interconnections with the other stages are made with direct current.

Advantageously, the series of high-pass filtering stages is followed by a power amplifier, equipped with low-pass filtering means.

Preferably, the amplifier stages are supplied between a DC line voltage and ground.

According to another aspect of the invention, the amplifier-corrector comprises bypass means placed between the two input and output circuits1 in parallel with the selective amplification means, intended to convey possible continuous components of the signal .

Advantageously, the amplifier-corrector according to the invention comprises display means actuated as a function of the level of the signal at the output of the amplifier stages.

The amplifier-corrector according to the invention can consist of at least four high-pass filtering stages and, in a preferred embodiment, the potentiometric means of each stage comprises twenty resistances, chosen so that the resistive value resistors placed in series between the inverting input of the associated amplifier and the associated capacitor bank added to the resistive value of the other resistors, ie a constant sum whatever the position of the intermediate point of the potentiometric means; thus the change of position of the switch within the potentiometric means makes it possible to have at least a gain variation of one decibel.

According to this same preferred embodiment; each capacitor bank includes five capacitors.

Other advantages and characteristics of the invention will appear on examining the detailed description below and the appended drawings in which - FIG. 1 is a functional block diagram of an amplifier-corrector according to the invention, - FIG. 2 is a schematic diagram of the mounting of an operational amplifier of a high pass filtering stage of the amplifier-corrector of FIG. 1, - Figure 3 is a detailed diagram of a high pass filtering stage of the amplifier -corrector of Figure 1, - Figure 4 is a detailed diagram of a switchable attenuator of the amplifier-corrector of Figure 1, - Figure 5 is a detailed diagram of a particular circuit of the amplifier-corrector of Figure 1, - Figure 6 is a detailed diagram of a power stage of the amplifier-corrector of Figure 1, - Figure 6a is a detailed diagram of another particular circuit of the amplifier-corrector of Figure 1; FIG. 7 is a detailed diagram of the display means of the amplifier-corrector of FIG. 1, FIG. 8 is a detailed diagram of an input circuit of the amplifier-corrector of FIG. 1, - Figure 9 is a detailed diagram of an output circuit of the amplifier-corrector of Figure 1, - Figure 10 is a detailed diagram of derivative means of the amplifier-corrector of Figure 1, - Figure 11 is a detailed diagram of a power supply unit of the amplifier-corrector of FIG. 1, FIGS. 12 and 13 represent two gain curves as a function of the frequency making it possible to better understand the operation of the amplifier-corrector according to the invention, and, - Figures 14A to 14D represent a nomenclature of the main components used in a particular embodiment of the amplifier-corrector of Figure 1.

Insofar as they essentially contain elements of a certain character, the appended drawings form an integral part of the description, not only to make it easier to understand, but also to contribute to the definition of the invention if applicable.

Although the invention can be applied in general to different types of transmission, and to different types of medium for this transmission, it will now be assumed that it is a digital baseband link carried out on a pair symmetrical metallic.

The upstream part of the transmission line arrives in
AM in figure 1. Its downstream part goes AV in the same figure.

The amplifier-corrector according to the invention comprises, upstream, an input circuit CE, downstream an output circuit CSO, and, between these two circuits, selective amplification means MA intended to compensate for signal inequalities on the link depending on the frequency.

This amplifier-corrector also includes display means MAF, actuated, as described below, as a function of the level of the signal at the output of the amplification means MA, and of the derivative means MD, placed between the two circuits CE, CSO , in parallel with the amplification means MA and intended, as explained below, to convey a possible continuous component of the signal.

All of these constituent elements are supplied by a power supply unit BA.

The selective amplification means MA comprise five high-pass filtering stages ET1 to ET5 connected in series, of which only three have been shown for obvious drawing reasons. Upstream of each stage ETi is placed in series an attenuator Ai and, between the first attenuator Al and the first stage ET1 is placed in series a particular circuit S whose composition and function will be explained below.

Downstream of the fifth high-pass filtering stage ET5 is mounted in series a power stage EP and downstream of this stage EP another particular circuit S 'whose composition and function will be explained below.

In each of the blocks shown in Figure 1 are shown connection terminals whose references will be recalled in the detailed diagrams of each of the blocks.

The principle of mounting a high-pass filtering stage
ETi is shown in FIG. 2. Each stage ETi comprises an operational amplifier AOi. The input Ei of this stage ETi is connected to the non-inverting input of the operational amplifier AOi and the output Si of this stage ETi is connected to the output of the operational amplifier
AOi as well as to mass through a potentiometric means
MPi connected in series with an adjustable capacitor
Cj-i. An intermediate point Ii of the potentiometric means
MPi is connected to the inverting input of the operational amplifier AOi. If we designate by RIII the part of the potentiometric means placed between the capacitor Cj-i and the point Ii and RIV the part of the potentiometric means placed between the point Ii and the output of the operational amplifier AOi, the assembly of the assembly is such that the sum RIII + RIV is constant and equal to a value R.

The transmittance function is of the form h l + bRCj ~ iw (w is the pulse of the signal) I + bRIIICj-iw (b is the complex number such that b2 = -1)
The stage ETi is responsible for compensating for the distortion of the line in a particular frequency zone. The variation in cutoff frequency is obtained by a variation in Cj-i because the value R is constant. The gain variation is obtained by varying the RIII / RIV ratio.

The operational amplifier AOi is chosen to meet the characteristics required by the frequency operating range of the correcting amplifier, in this case from 1 kilohertz to 1300 kilohertz.

FIG. 3 shows in detail the mounting of such a stage ETi, for example the stage ET1.

The potentiometric means MP1 consists of a series of twenty resistors RA to RT in series and a jumper V1 allowing the connection of the common point of two resistors of each series to the inverting input of the operational amplifier AO1. The values of these resistors vary from approximately 50 ohms to approximately 1000 ohms and allow the gain of the operational amplifier to be selected.
AO1 from zero to twenty decibels in steps of one decibel.

The variable capacity capacitor is obtained with a battery of five capacitors C1-l to C5-1 selectable by a jumper U1. As an indication, the capacitance values of capacitors Cl-1 to C5-1 range from around 2000 picofarads to around 10,000 picofarads. Of course, an intermediate capacity value can be selected by using several jumpers U1 to put several capacitors Cj-1 in parallel. The wiring of a sixth capacitor C6-1 is planned but its installation has not been deemed necessary, for the moment, by the Applicant.

A capacitor C19 is mounted in feedback on the operational amplifier AO1 and ensures a reduction of the bandwidth outside the useful area assigned to this stage. The non-inverting input of the operational amplifier AO1 is connected to ground via a capacitor C100.

The amplifier AO1 is supplied between ground and a negative line voltage (-15V) at the level of terminal AL1. Between the terminal AL1 and the power supply terminal of the amplifier AO1 is placed a resistor
R1O and the power supply terminal of the amplifier AO1 is also connected to ground through a capacitor C18.

The other four stages ET2 to ET5 are mounted in a strictly analogous manner. The resistances RA to RT are identical for all the stages, on the other hand the value of the capacitors Cj-i varies according to the stages.

Thus each stage ETi compensates for the distortion of the line in a particular frequency zone.

FIG. 4 shows in detail the diagram of the attenuator A1 placed upstream of the pass filtering stage ET1. This attenuator A1 comprises a divider bridge made up of two resistors RA1 and RA10 placed in series between the input terminal EA1 and the ground terminal AA1 of this attenuator. The output terminal SA1 of the attenuator
Al is constituted by the terminal of the resistance RA1 opposite to EA1. This attenuator is put into service by a jumper
ZAl connecting SA1 to resistance RA10. In addition, the assembly (resistor RA1-capacitor C100) constitutes a low-pass filtering cell which intervenes in the stability of the amplifier-corrector.

This attenuator allows attenuation of six decibels and has the function of maintaining an output level of the stage ET1 compatible with good harmonic distortion of the output signal of the amplifier-corrector. Thus the output level of each stage ETi must remain below 1.5 volts peak to peak for bit rates lower than 512 kilobits per second and 1 volt peak to peak for bit rates higher than 640 kilobits per second. The output level of each stage ETi is measured at the test point TPi such as the test point TP1 shown in FIG. 3.

The other attenuators Ai amplification means
MA are analogous in their constitution to the attenuator
Al; on the other hand, their terminal AAi is not connected to ground but to the terminal BS of the particular circuit S, the constitution of which will now be described.

This circuit S comprises, on the one hand, a DC component suppression of the signal and, on the other hand, a bias stage of all of the operational amplifiers AOi. The suppression of the DC component of the signal is acquired by a capacitor CSP of which one terminal ES, constituting the input terminal of the circuit S, is connected to the terminal SA1 of the attenuator Al, and of which the other terminal
SS, constituting the output terminal of circuit S, is connected to the non-inverting input of the operational amplifier
AO1.

The polarization stage of all the operational amplifiers AOi consists of a first resistor
RS1 connected to the terminal SS of the capacitor CSP, a second resistor RS2 connected in series with the first resistor RS1 and an electrochemical capacitor CS mounted between ground and read common point BS of the two resistors RS1 and RS2. This polarization stage provides a central and unique potential of -15 volts. Each stage ETi transmits this reference to the following by resistive link RAi as it appears in FIG. 4 in resistance RA1.

Figure 6 now shows the ETP power stage.

This stage includes, on the one hand, a power amplifier
AOP and, on the other hand, low-pass filtering means.

The first low-pass filter consists of a cell
RC adjustable by ZX jumpers. The resistance of this cell is resistance R69 and the switchable capacitors are capacitors C80, C81, C82, C83 and C84 connected between resistance R69 and ground. A single ZX jumper has been shown in FIG. 6, but it is possible to select several capacitors at the same time. The common point of connection between the resistor R69 and the capacitor bank C8O to C84 is connected to the non-inverting input of the power amplifier AOP and the other terminal of the resistor R69 constitutes the input terminal EP of the ETP power stage. This low-pass filter is intended to attenuate the noise located beyond the useful frequency spectrum.

The second low-pass filter is produced at the power amplifier AOP by switching capacitors C66, C67, C68 connected in parallel between the inverting input and the output of the power amplifier.
PDO. These capacitors are switchable by one or more ZY jumpers and significantly reduce the gain of frequencies outside the useful area.

The AOP power amplifier is mounted almost analogously to the AOi operational amplifiers.

 I1 includes a resistor placed between the inverting input and the output chosen using a jumper P in a group of three resistors R66, R67, R68 mounted between the inverting input and the output of the AOP amplifier.

The AOP amplifier also includes a resistor and a capacitor connected in series between the inverting input and ground. This resistor is chosen from a group of six resistors R60 to R65 connected in parallel and selectable by a jumper ZZ. The capacitor located between resistors R60, R65 and ground is an electrochemical capacitor C60.

An aperiodic gain power amplifier was therefore produced. This gain is adjustable both by switching resistors R60 to R65 (jumper ZZ) which provides a step of about one decibel and by switching resistors
R66, R67, R68 (jumper P) which gives a pitch of about six decibels. The combination of the two settings ensures a gain dynamic of twenty decibels.

The C9O capacitor mounted in feedback without the AOP amplifier also ensures a reduction of the pass-through terminal outside the useful area. This amplifier is also supplied between ground and a direct current line. I1 also includes an assembly R70, C7O between the output ALP terminal of the ETP stage and the power supply terminal of the AOP amplifier. The output terminal SP of the ETP stage also constitutes a TPP test terminal.

FIG. 6a represents the other particular circuit S '.

This circuit S 'comprises an electrochemical transistor CS' mounted in series on the output terminal SP of the stage ETP and which has the function, like the capacitor CS of the particular circuit S, of suppressing a DC component. This DC component results from the supply between ground and a negative DC voltage (-15V) of all the operational amplifiers. The capacitor terminal
CS 'connected to the output SP of the stage ETP constitutes the input terminal ES'1 of the stage of the particular circuit
S ', and its other terminal constitutes the output terminal SS' connected to the input terminal ECS of the output circuit. Between the input terminal ES'1 of this particular circuit S 'and the ground is placed a resistor RS '2 and a capacitor CS'1 capable of being connected by an OEIL test jumper allowing the modulation eye to be viewed at the output of the AOP power amplifier.

FIG. 7 now shows in detail the diagram of the display means MAF. These MAF means comprise on the one hand a full-wave rectifier, on the other hand a comparator and finally a light-emitting diode.

The full-wave rectifier is conventionally constituted by a transistor QF, resistors RF6, RF7, RF8, capacitors CF1 and CF2 and a diode DF1. The voltage -15 volts is present on the anode of the diode DF1 which constitutes the input terminal EAF2 of the means MAF. The signal at the output of the power amplifier AOP taken at the terminal SP is connected to the input terminal EAF3 of the monoalternation rectifier. The operational amplifier AOAF and all of the resistors RF1, RF2, RF4, RF5 conventionally show a comparator assembly. The voltage -15 volts is present at one terminal of the resistance RF1, resistance whose other terminal is connected to the non-inverting input of the amplifier AOAF. The output of this amplifier
AOAF attacks by means of a resistance RF3 the anode of a light-emitting diode DS2, the cathode of which is connected to the input terminal EAF1 of the means MAF, terminal delivering the voltage -30 volts.

The full-wave rectifier supplies a negative voltage with respect to -15 volts equal to the peak-to-peak amplitude of the output signal from the AOP amplifier. For a certain level detected; the AOAF comparator switches and activates the light-emitting diode DS2. Display means actuated according to the level of the signal at the output of the power amplifier stage have therefore been produced.
AND P.

The output circuit CSO of this amplifier-corrector whose input terminal ECS is connected to the output terminal SS 'of the particular circuit S' described above, is represented in FIG. 8. This output circuit CSO consists conventionally by protective elements. These protection elements are two RT4, RT5 thermistors placed on each branch of the AV downstream line, bi-directional protection elements CR7 and CR6 placed in shunt at the terminals of a TCS isolation transformer fitted with an RCS impedance adaptation , CCS selectable by a jumper
ZW. This impedance matching makes it possible to adjust the output impedance of the operational power amplifier
PDO. The AV downstream link can be isolated by a double ST jumper and is fitted with a TPST test socket.

There is a practically similar diagram for the input circuit CE shown in FIG. 9. This circuit also includes two thermistors RT1 and RT2 mounted on each branch of the upstream link AM as well as bidirectional protection elements CR1, CR2, mounted in bypass on a TCE isolation transformer fitted with an impedance matching consisting of an RCE resistor and a CCE capacitor mounted in parallel across the terminals of the TCE transformer. The upstream link can be isolated by a double CET jumper and is equipped with a test socket
TPET.

The transmission of any continuous components of the signal, for example the remote controls in direct current, is ensured by means of bypass MD represented in FIG. 10. These means MD consist of two low-pass filters constituted for the first by a coil
LD and a capacitor CD1 and for the second by the same coil LD and a capacitor CD2. These low-pass filters can be put into service by a WD jumper. The capacitor CD1 is mounted in parallel to the terminals D1 of the isolation transformer TCE of the input circuit while the capacitor CD2 is mounted in parallel to the terminals D2 of the isolation transformer TCF of the output circuit
Show Jumping. The means MD are galvanically isolated from the rest of the card and provide ohmic continuity between the arrival and departure lines.

This amplifier-corrector is supplied by a power supply unit BA shown in FIG. 11. This power supply unit BA is a simple diode stabilizer
Zener CRB1, CRB2 and QBA series transistor. This stabilizer provides the two voltages necessary for the operation of the amplifier, that is to say the -30 volts available on the emitter of the transistor QBA (terminal SBA1) and the -15 volts available on the cathode of the Zener diode. CRB1 (terminal
SBA2). This voltage -30 Volts is connected to all the terminals ALi of the operational amplifiers AOi as well as to the terminal ALP of the amplifier AOP. The flow rate of the voltage -15 volts is lower than the milliampere which explains the absence of a second transistor lowering of impedance.A light-emitting diode DS1, of presence -48 volts, is mounted on the collector of the transistor
QBA. It consumes no additional energy since it is connected in series, on the non-stabilized side of the regulator. A resistor with a positive temperature coefficient RT3 limits the total consumption to approximately one hundred milliamps and switches over. It therefore avoids the use of a fuse. The other resistors RB1, RB2, RB3 and other electrochemical capacitors CB1, CB2, CB3, CB4, as well as the capacitor CB5 are conventional constituent elements of such an assembly.

When you want to make a correction for the attenuation of a line, the first operation to do is to measure this line and draw curves of attenuation of the gain as a function of the frequency. Such a curve is given in FIG. 12. Once this curve is obtained, we determine for each frequency zone, therefore for each high-pass filtering stage ETi, gain-frequency correction curves such as that shown in FIG. 13. this kind of curve for each high-pass filtering stage and at the same time the appropriate position of the different gain and frequency adjustment jumpers is provided. Once the jumpers are correctly positioned, the signal is transmitted on the link and the quality of the signal received downstream is checked.

This signal is observed using the EYE test socket and it can thus be determined whether the line is correctly corrected. On the other hand, using the different test ports TPi and TPP, it is checked that at the output of each operational amplifier the maximum authorized level is not exceeded. If it is exceeded, an Aj attenuator is then inserted using the corresponding jumper.

During the operation of this amplifier-corrector, the light-emitting diode of present -48 volts must be lit and the light-emitting diode DS2 lights up when the output signal reaches at least a level equal to zero decibel.

Those skilled in the art will then understand that an amplifier-corrector has actually been produced allowing fine adjustment and absolutely independent of one pass-through filtering stage to the next. This amplifier-corrector is therefore perfectly suited to very long lines of variable diameter having complex attenuation curves.

A nomenclature of the main components of the amplifier-corrector described above is provided in FIGS. 14A to 14D. In this nomenclature - the acronym "LNZ" designates the standard LNZ 4404 approved by the National Center for Telecommunications Studies. The acronym "LNZ" placed next to certain components means that these components must be approved "LNZ" and supplied from approved suppliers "LNZ"; - the acronym "RTC" designates the French company "RTC"; - the acronym "LCC" designates the French company "LCC"; - the acronym "AETA" designates the Applicant; - the acronyms "SGS", "MOTOROLA", "NSC"; respectively designate the companies of the United States "SGS", "MOTOROLA"
I1NSC "; - the abbreviations nF, pF, PF denote nanofarads, picofarads and microfarads respectively.

 It is understood that the invention described above may have variants, in particular in the number of resistors and capacitor banks used.

Claims (11)

Claims. 1. Amplifier-corrector, in particular for digital baseband links on wire or cable line, of the type comprising - input (CE) and output (CSO) circuits, intended to be connected respectively to the upstream sides ( AM) and downstream (AV) of the link, and, between them, - selective amplification means (MA) intended to compensate for the unevenness of signal transmission on the link, as a function of frequency, characterized in that that these selective amplification means (MA) comprise several high-pass filtering stages (ETi) with operational amplifiers (AOi) connected in series, each stage (ETi) comprising an input (Ei) connected to the non-inverting input of the operational amplifier (AOi) and an output (Si) connected to the output of the operational amplifier, as well as to ground through a potentiometric means (MPi) connected in series with a bank of switchable parallel capacitors (Cj -i) while an intermediate point (Ii) of the means can iometric (MPi) is connected to the inverting input of the amplifier (AOi), and in that the capacitor banks of the successive stages are different, these stages (ETi) being thus assigned to correct different parts of the band of transmission. 2. Amplifier-corrector according to claim 1, characterized in that the potentiometric means (MPi) of a stage (ETi) consists of a series of resistors in series (RA to RT), identical for all the stages (ETi ), and a switch (Vi) such as a jumper, allowing the connection of the common point of two resistors of each sequence to the inverting input of the corresponding amplifier (AOi), the parallel capacitors (Cj-i) also being switchable using switches (Ui) such as jumpers. 3. Amplifier according to one of claims 1 and 2, characterized in that the connection between the input (Ei) of stage (ETi) and the non-inverting input of the associated operational amplifier (AOi) comprises a switchable attenuator (Ai) allowing the signal to be brought back into the dynamic range acceptable for the associated operational amplifier (AOi). 4. Amplifier-corrector according to one of claims 1 to 3, characterized in that the first (ET1) of the high-pass filtering stages is provided at its input with a continuous component suppression (CSP), while the interconnections with the other stages (ETi) are made in direct current. 5. Amplifier-corrector according to one of claims 1 to 4, characterized in that the series of high-pass filtering stages (ETi) is followed by a power amplifier (AOP), equipped with pass filtering means -low. 6. Amplifier-corrector according to one of claims 1 to 5, characterized in that the amplifier stages (ETi, ETP) are supplied between a DC line voltage and ground. 7. Amplifier-corrector according to one of claims 1 to 6, characterized in that it comprises bypass means (MD) placed between the two input (CE) and output (CSO) circuits, in parallel with the selective amplification means (MA), intended to convey a possible continuous component of the signal. 8. Amplifier-corrector according to one of the preceding claims, characterized in that it comprises display means (MAF) actuated as a function of the level of the signal at the output of the amplifier stages. 9. Amplifier-corrector according to one of claims 1 to 8, characterized in that it consists of at least four high-pass filtering stages, in that the potentiometric means (MPi) of each stage (ETi) comprises twenty resistors (RA to RT) such as the resistive value of the resistors placed in series between the inverting input of the amplifier (AOi) and the associated capacitor bank (Cj-i) added to the resistive value of the other resistors, i.e. one constant sum whatever the position of the intermediate point (Ii) of the potentiometric means (MPi). 10. Amplifier-corrector according to one of the preceding claims, characterized in that each capacitor bank (Cj-i) comprises five capacitors. 11. Amplifier-corrector according to one of the preceding claims, characterized in that the connection is defined by a symmetrical metal pair.