FR2517494A1 - Inter-modulation corrector for HF single side band amplifier - has pre-corrector for odd order cross-modulations, whose amplitude is measured for analysis by microprocessor, and test signal generator - Google Patents

Abstract

An intermodulation measuring circuit (13) is connected to the output of an HF amplifier (2). The measuring circuit output passes through an A/D converter (16) to a microprocessor (14) to which a logic interface (15) is connected. This allows communication with an operator and also enables the highest intermodulation order to be selected. This interface also allows a test signal to be applied via a gating circuit (19) to the input of a modulator (1). D/A converters (17) provide gain adjustment signals from the microprocessor to a pre corrector (4) upstream of the amplifier. The correction is initiated by an operator command and the correction signal is applied until the measuring circuit indicates that the intermodulation has reduced to below a threshold level.

Description

AUTOMATIC INTERMODULATION CORRECTION DEVICE
PRODUCED BY A HIGH SIGNAL AMPLIFIER
FREQUENCY IN A SINGLE BAND TRANSMITTER
The present invention relates to an automatic intermodulation correction device produced by a high frequency signal amplifier in a single sideband transmitter (SSB) regulated in peak level and having amplitude non-linearities.

 The non-linearity of an amplifier causes, when it is simultaneously excited by several signals of different frequencies, spurious signals called intermodulation products.

 When the high frequency signals to be amplified are modulated signals, the intermodulation phenomenon is then manifested, outside the modulation band, by a disturbance of communications using neighboring channels, and in the modulation band, by a phonic distortion. and especially by an increase in the error rate in the case of multi-carrier digital transmission.

 We have long tried to minimize the consequences of the phenomenon of non-linearity. Thus, we thought of having upstream of the amplifier, a precorrector having a transfer function complementary to that of the amplifier. However, given the changes in the non-linearities of an amplifier according to its conditions of use (frequency, power and aging of its components), it turns out to be necessary to frequently reset the precorrector associated with this amplifier.

 We then thought of automating these adjustments, in particular using a microprocessor which, depending on the analysis it makes of the amplified signal, decides to act in this or that way on the adjustment of the precorrector.

 Such a system is described in French patent application No. 78 36488 filed in the name of the applicant. However, in this system, the precorrector is of the type described above, that is to say having a transfer function complementary to that of the amplifier to be corrected, that is to say also making it possible to globally remedy the phenomenon of nonlinearity. However, this precorrector presents a great complexity of production and development, which also results in a great complexity of the algorithms for operating the microprocessor. This complexity is judged to be unjustified when the aim is only, as is the case in the present application. patent, to correct the intermodulation products, and more particularly the odd order intermodulation products, the only generators of intermodulation products in the vicinity of the transmission frequencies.

 In this regard, a precorrector of intermodulation products of odd orders, having a very simplified production and development, was the subject of French patent application No. 8110 451 filed in the name of the applicant.

 The present invention aims to automate the settings of such a precorrector of intermodulation products by using the analysis by a microprocessor, of the amplitude of the intermodulation lines of odd orders measured by an intermodulation measurement device. .

 According to the invention, the automatic intermodulation correction device produced by a high frequency signal amplifier in a single sideband transmitter regulated in peak level and having amplitude non-linearities comprises firstly, upstream of the amplifier, an intermodulation precorrector capable of developing, from the signal to be amplified, correction signals, of adjustable amplitude, at the frequencies of the intermodulation products of odd orders, this precorrector providing the input signal of the amplifier , the product of the transfer functions of the intermodulation precorrector and of the amplifier not necessarily giving a linear transfer function, secondly, downstream of the amplifier, a device for measuring the amplitude of the intermodulation products d odd orders produced by the amplifier, thirdly a microprocessor capable of analyzing the amplitude of the intermodulation products of odd orders measured by the intermodulation measuring device and controlling the intermodulation precorrector accordingly so as to reduce the amplitude of the intermodulation products of odd orders, and fourthly means for supplying the amplifier either by means of a signal test consisting of the sum of two high frequency tones, either by means of the high frequency signal to be amplified, depending on whether or not one is in an intermodulation correction phase.

Other objects and characteristics of the invention will appear more clearly on reading the following description of exemplary embodiments, said description being made in relation to the attached drawings in which:
- Figure 1 is a diagram of an automatic intermodulation correction device according to the invention;
- Figure 2 is a diagram of a first alternative embodiment of the intermodulation precorrector entering an automatic intermodulation correction device according to the invention;
- Figure 3 is a diagram of a second alternative embodiment of the intermodulation precorrector entering an automatic intermodulation correction device according to the invention;
Identical elements shown in different figures bear identical references.

 In Figure 1 there is shown a high frequency transmission chain into which is inserted a high frequency signal amplifier intended to be corrected by an automatic intermodulation correction device according to the invention.

 This high frequency transmission chain comprises a modulator 1 capable of transforming a low frequency signal s into a high frequency signal S modulated according to a modulation of the single sideband type, a high frequency amplifier 2 capable of ensuring the amplification of the high signal frequency S, and a transmitting antenna 3 capable of transmitting the amplified high frequency signal A. Elements 1, 2 and 3 do not constitute the subject of the present invention and will therefore not be described in more detail .

 Between the modulator 1 and the amplifier 2 is interposed an intermodulation precorrector 4 able to develop, from the signal to be amplified, correction signals, of adjustable amplitude, at the frequencies of the intermodulation products of odd orders. When the signal to be amplified comprises two tones of frequencies fl and t is meant by intermodulation products of odd orders the lines of the spectrum of the amplified signal which are situated at the frequencies nfl- (nl) f2 and (nl) fl-nf2, where n is an integer.

 A first alternative embodiment of the intermodulation precorrector, in which the precorrector operates from the envelope of the high frequency signal S, is shown in FIG. 2. By way of example, it is a precorrector for intermodulation products of orders 3 and 5, that is to say derived from the terms of powers equal to 3 and 5 from the transfer function of amplifier 2.

 The precorrector 4 comprises a first multiplier 5 provided with two inputs connected to the output of a detector 5 ′ of the envelope of the high frequency signal S, and a second multiplier 6 provided with two inputs connected to the output of the first multiplier 5. The precorrector 4 also includes a first adjustable gain amplifier 7, provided with an input connected to the output of the first multiplier 5, and a second adjustable gain amplifier 8, provided with an input connected to the output of the second multiplier 6. Amplifiers 7 and 8 are linear amplifiers, for example operational amplifiers looped using a resistor.

 The precorrector 4 also includes a summing circuit 9 provided with a first input connected to the output of the amplifier 7, a second input connected to the output of the amplifier 8 and a third input intended to receive a value constant K determined by the operator according to the desired operating point. The summing circuit 9 is intended to perform additions or subtractions between the values available on each of its inputs, the choice between addition and subtraction relative to each of these values being determined by the operator.

 More generally, for the precorrection of intermodulation products of any odd order, the precorrector 4 comprises N multipliers, the first of which is provided with two inputs connected to the output of the envelope detector, the second of which is provided with two connected inputs at the output of the first and whose nth (n being an integer between 3 and N) is provided with two inputs connected respectively to the output of the first and (nl) th N linear gain adjustable amplifiers each provided with an input connected to the output of one of the N multipliers, and a summing circuit with N + 1 inputs, of which N are connected to the outputs of the linear amplifiers with adjustable gain, and the (N + 1) th of which is intended to receive the value constant K.

 The precorrector 4 also comprises a mixer 10 provided with a first input which receives the high frequency signal S, with a second input connected to the output of the summing circuit 9, and with an output which constitutes the output of the precorrector 4 and which is connected to the input of amplifier 2. Mixer 10 is intended to carry out the product of the signals present on its two inputs.

 A second alternative embodiment of the precorrector, in which the precorrector operates directly from the high frequency signal S is shown in FIG. 3.

 By way of example, it is also a precorrector of intermodulation products of orders 3 and 5.

 The precorrector 4 comprises a first multiplier 4 'provided with two inputs which receive the high frequency signal S, a second multiplier 5 provided with an input connected to the output of the first multiplier 4' and an input intended to receive the signal S , and a third multiplier 6 provided with two inputs connected respectively to the output of the first and of the second multiplier. The precorrector 4 also comprises two amplifiers with adjustable gain 7 and 8 connected respectively to the outputs of the multipliers 5 and 6. The precorrector 4 also comprises a summing circuit 9 provided with a first input intended to receive the high frequency signal to be amplified, a second input connected to the output of the amplifier 7, and a third input connected to the output of the amplifier 8. The summing circuit 9 is also intended to perform additions or subtractions between the values available on each of its inputs, the choice between addition and subtraction relative to each of these values being determined by the operator. The precorrector 4 finally comprises two variable phase shifters 11 and 12 interposed respectively between the multiplier 5 and the amplifier 7, and between the multiplier 6 and the amplifier 8.

 More generally, for the precorrection of intermodulation products of any odd order, the precorrector 4 comprises firstly N multipliers, the first of which is provided with two inputs intended to receive the high frequency signal to be amplified, the second of which is provided with '' an input intended to receive the high frequency signal to be amplified and an input connected to the output of the first, and of which the first (n being an integer between 3 and N) is provided with an input connected to the output of the first and (nl) th, second Nl linear gain adjustable amplifiers each provided with an input connected to the output of one of the multipliers of rank n greater than 1, thirdly a summing circuit 9 provided with N inputs of which Nl are connected to the outputs of linear amplifiers with adjustable gain and the Nth of which is intended to receive the high frequency signal to be amplified, and fourthly Nl variable phase shifters interposed between the outputs of the Nl multipliers of rank n greater than i and the inputs of the corresponding adjustable gain amplifiers.

 The operating mode of the intermodulation precorrector shown in FIG. 2 is as follows. By acting on the gain adjustment of amplifiers 7 and 8 and on the adjustment of the signs to be assigned to the input signals of the summing circuit 9, the amplitude and the sign of each of the output components of the summing circuit 9 are controlled. adjustment is made in descending order of the intermodulation lines to be eliminated by observing at each step of the adjustment the evolution of the output signal of the amplifier 2. It consists first of all in minimizing the amplitude of the intermodulation lines of order 5 per action on the linear amplifier with adjustable gain 8, which also modifies the amplitude of the intermodulation lines of order 3. I1 then consists in minimizing the new intermodulation lines of orders 3 per action on the Linear amplifier with adjustable gain 7, which plays a little on the level of the frequencies of the signal S, but this is not annoying. At the end of the adjustment, the spectrum of the output signal of amplifier 2 comprises very weak intermodulation lines.

 The operating mode of the intermodulation precorrector represented in FIG. 3 is similar to that of the intermodulation precorrector represented in FIG. 5 except that one obtains directly at the output of the different multipliers of the lines corresponding to the different intermodulation products. to be corrected, unlike the case where the precorrector operates from the envelope, in which case a mixer must be used.

 Furthermore, since the intermodulation precorrector shown in FIG. 3 operates directly on the high frequency signal, it is necessary to insert variable phase shifters, adjustable by the operator, between the multipliers and the amplifiers with adjustable gain, so as to compensate for the phase delays which the signal undergoes in the various multipliers and thus to establish a synchronism of the various input signals of the summing circuit. This adjustment is made once and for all independently of the intermodulation correction operation.

 Referring now to FIG. 1. A device 13 for measuring the amplitude of the intermodulation lines of odd orders is connected at the output of the amplifier 2. This intermodulation measurement can be carried out in known manner, by example by transposition to intermediate frequency followed by filtering.

 A microprocessor 14 is provided between the intermodulation measurement device 13 and the intermodulation precorrector 4, so as to automate the settings of the precorrector 4.

 The microprocessor 14 is provided with first inputs connected to first outputs of a logic interface with the exterior 15 and of second inputs connected to the outputs of the intermodulation measurement device 13 via an analog to digital converter 16. The measurement device intermodulation 13 is also provided with a control input intended to select the intermodulation line to be measured.

This control input is connected to a second output of the logic interface 15.

The microprocessor 14 is provided with first outputs connected to the control input of a first amplifier with adjustable gain of the precorrector 4 via a digital analog converter 171 - etc, of nth outputs connected to the control input of a nth amplifier gain adjustment of precorrector 4 via a 17n digital to analog converter
The microprocessor 14 is also provided with outputs connected to the inputs of a digital analog converter 18 itself provided with an output connected to a first signal input of an analog gate 19. The analog gate 19 is also provided with a second signal input which receives the low frequency signal, from an output connected to the input of the modulator 1 and from a control input connected to a third output of the logic interface 15.

 The microprocessor 14 is also provided with outputs connected to inputs of the logic interface 15, the logic interface 15 being moreover provided with inputs and outputs allowing a dialogue with the operator.

 The automatic intermodulation correction device shown in FIG. 1 operates as follows.

 An operation for adjusting the precorrector is triggered by decision of the operator, and this decision is transmitted to the microprocessor 14 via the logical interface 15. This event launches the execution of a program contained in the read-only memory of the microprocessor, which results in the following operations. The analog gate 19 is positioned so that the transmission chain is supplied by a test signal, generated by the microprocessor 14, applied to the first signal input of the analog gate 19, and consisting of the sum of two tones low frequency.

 This microprocessor selects the output of the intermodulation measurement device 13, via the logic interface 15, the intermodulation line of the highest order, then the signal applied to the input of adjustment of the corresponding precorrector. to this order is modified until the amplitude of this intermodulation line is less than a threshold.

 The microprocessor proceeds in the same way for the other intermodulation lines by treating them in decreasing order.

 The adjustment being completed, the microprocessor 14 positions the analog gate 19 so that the transmission chain is supplied by the low frequency signal s, and maintains on the precorrector 4 the adjustment coefficients found and transmitted by the converters 171 to 7n .

 The operator is notified of the beginning and end of the adjustment, as well as of any incident occurring during adjustment, via the logic interface 15.

 By judiciously choosing the adjustment coefficients of the precorrector used at initialization, that is to say before any intermodulation measurement, the duration of the adjustment phase can be reduced. For this, it suffices to store the adjustment coefficients found for each state, and to start the adjustment with the coefficients found for a comparable state.

Claims (3)

 1. An automatic intermodulation correction device produced by an amplifier (2) of high frequency signals in a single sideband transmitter regulated in peak level and having amplitude non-linearities, characterized in that it firstly, in upstream of the amplifier (2), an intermodulation precorrector (4) capable of developing, from the signal to be amplified, correction signals, of adjustable amplitude, at the frequencies of the intermodulation products of odd orders, this precorrector (4) providing the input signal of the amplifier (1), the product of the transfer functions of the intermodulation precorrector (4) and of the amplifier (2) not necessarily giving a linear transfer function , secondly, downstream of the amplifier (2), a device (13) for measuring the amplitude of the intermodulation products of odd orders produced by the amplifier (2), thirdly a microprocessor (14) capable to analyze the amplitude of pr odd order intermodulation products measured by the intermodulation measuring device (13) and to control the intermodulation precorrector (4) accordingly so as to reduce the amplitude of the odd order intermodulation products and fourth means (19) for supplying the amplifier (2) either by means of a test signal consisting of the sum of two high frequency tones, or by means of the high frequency signal to be amplified, depending on whether one is or not in an intermodulation correction phase.  2. Device according to claim 1, characterized in that the intermodulation precorrector (4) comprises firstly an envelope detector (5 ') of the signal to be amplified, secondly N multipliers (5,6), of which the first is provided two inputs connected to the output of the envelope detector (5 '), the second of which is provided with two inputs connected to the output of the first and whose Nleme (n being between 3 and N) is provided with two connected inputs respectively at the output of the first and (N- 1) th, third N linear amplifiers with adjustable gain (7, 8) each provided with an input connected to the output of one of the N multipliers, fourth with a summing circuit ( 9) provided with N + 1 inputs, N of which are connected to the outputs of the linear amplifiers with adjustable gain, and the (N + 1) th of which is intended to receive an adjustable constant value, and an output which constitutes the output of the precorrector ( 4), the summing circuit (9) being able to operate as an adder or subtract actor relative to each of its inputs, and fifth a mixer (10) provided with a first input intended to receive the input signal, with a second input connected to the output of the summing circuit (9), and with a output connected to the amplifier input (2).  3. Device according to claim 1, characterized in that the intermodulation precorrector (4) comprises firstly N multipliers (4 ', 5, 6), the first of which is provided with two inputs intended to receive the signal to be amplified, of which the second is provided with an input intended to receive the signal to be amplified and with an input connected to the output of the first, and the nth of which (n being an integer between 3 and N) is provided with two inputs connected respectively to the output of the first and (nw eme, second (Nl) adjustable gain linear amplifiers each provided with an input connected to the output of one of the multipliers of rank n greater than 1, and thirdly a summing circuit (9) provided with n inputs of which nl are connected to the outputs of the linear amplifiers with adjustable gain and the Nth of which is intended to receive the high frequency signal to be amplified, and of an output connected to the input of the amplifier (2).