DE2526064A1 - REINFORCEMENT DEVICE - Google Patents

Description

Laboratoire General des Telecommunications
51, vol. De la Republique
78400 CHATOU / France

Our reference: L 964

Reinforcement device

The invention relates to a gain device linearized by automatic correction of the gain of an amplifier.

Small and medium-sized TV channels and intermediate channels
Power generally have output stages which consist of power amplifiers which, since they are supposed to be linear, are only used in a small part of their transmission curve. The apparent efficiency of these systems generally does not exceed 10%.

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Devices which allow the utilization of a larger part of the characteristic curve of these amplifiers are already in place has been proposed.

These devices generate a predistortion at the input of the amplifier, by means of which the through the amplifier distortion generated in the non-linear part of its characteristic curve is to be compensated for.

These facilities require numerous adjustments that must be performed frequently as the shape changes the non-linearities of the amplifiers with time and depending on the temperature, the mean value of the over- transmitted signal and a certain number of other parameters changes.

Devices for linearization by negative feedback have also already been proposed. At these institutions However, there are generally stability problems; they cause a considerable reduction the amplification of the amplifier when they act on the signal in its entirety, and when they act alone with the difference between the output and input signals of the amplifier work, they still have errors, which result from the negative feedback principle (phase problem and partial correction of the distortions as a matter of principle).

The device called "feedforward" in Anglo-Saxon literature eliminates the disadvantages of negative feedback by correcting behind the amplified signal. However, this arrangement requires a linear power amplifier for the correction signal. In addition, the correction signal and the amplified main signal are added

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mm "i mt

difficult to implement. This results in high system costs.

The aim of the invention is an amplification device which corrects the nonlinearities and which, at low cost, achieves the Avoiding the disadvantages of the above facilities allowed. In particular, the device according to the invention has which allows a very stable correction to be achieved, the advantages of the looped systems, without the disadvantages (phase and bandwidth problems).

According to the invention, a reinforcement device is provided an amplifier characterized by a damping circuit whose input is connected to the output of the amplifier is connected, by a first and a second channel, whose inputs are connected to the input of the amplifier or are connected to the output of the damping circuit, through a comparator which has two inputs that are connected to are connected to the output of one or the other channel, and through a correction circuit, the one Correction input connected to the output of the comparator, a signal input forming the input of the device and has an output connected to the input of the amplifier, the output of the amplifier being the output the reinforcement device forms.

Further features and advantages of the invention emerge from the following description of exemplary embodiments the invention. In the drawings show:

Fig. 1 shows a narrow band reinforcement

device according to the invention,

Fig. 2 shows broadband gain

direction to strengthen the

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modulated signals,

Fig. 3 is a detailed circuit diagram of a

Member of the device of Fig. 2, and

Fig. 4 for a damping circuit, the characteristic

line of attenuation as a function of the current.

In Fig. 1 the various members of a device according to the invention are shown.

The input 1 of the device / which receives a voltage u, (t) is connected to the first input of an adder circuit 2 connected, the output of which is connected to the input of an amplifier 3. This amplifier has a transfer characteristic * —J- = G'f [u (t) J, where u (t) is the input voltage

of the amplifier and u (t) its output voltage, G is the amplification of amplifier 3 on the linear part of its characteristic curve and f (u) is a non-linear function of the input voltage u (t). The output of the amplifier 3 forms the output 4 of the amplification device. The output 4 is connected to the input of a damping circuit 5, the damping factor of which is - . The input of the amplifier 3 and the output of the damping circuit 5 are connected to the two inputs of a comparator 6, the output of which is connected to the second input of the adder circuit 2 and which supplies the difference between the voltages applied to its two inputs. The optimal amplification to be given to the comparator 6 is established experimentally in such a way that the amplification device receives a linear transfer characteristic between the input 1 and the output 4, so that ^u s * = const.

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This reinforcement device is particularly useful when the bandwidth of the amplifier is small. The limitation of the operating range results from the phase rotation problems, if the length of the connections is not negligible compared to the wavelength, and off the delay times in the amplifiers.

This device finds a particularly advantageous application in the automatic correction of the nonlineari— the amplification of an amplifier fed with amplitude-modulated RF signals.

A corresponding embodiment of the device according to the invention is indicated by the overall circuit diagram of FIG.

The same elements as in FIG. 1 are denoted by the same reference numerals, which, however, are increased by IO. The input 11 is thus connected to an input of a correction circuit 12 shown in FIG. 2 by dashed lines. The exit the correction circuit 12 is connected to the input of an amplifier 13 via a preamplifier 18.

The output 14 of the power amplifier 13 forms the output of the amplification device. The output 14 is with connected to a damping circuit 15 whose damping « factor - is. The input of the amplifier 13 and the output of the damping circuit 15 are connected to the inputs connected by two demodulators 26 and 27, the outputs of which are connected to the two inputs of a comparator 16. The output of the comparator 16 is with the second input of the correction circuit 12 connected.

The actual correction circuit 12 contains two identical ones

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modulatable damping circuits 24 and 25. The characteristic curve of these damping circuits as a function of the one connected to them applied control voltage is shown in FIG. the Control inputs of these two damping circuits are connected to the output of the comparator 16.

The correction circuit 12 also has a first 3 dB coupler 20, one input of which is connected to the input 11 of the correction circuit 12 and the second input of which is terminated with its characteristic impedance 30. Of the Output of the coupler 2O, which delivers a signal that is with the Input signal is in phase is connected to one input of a second 3 dB coupler 22, the second input of which with its wave impedance 32 is completed.

The outputs of coupler 22 that are in phase and 90 ° out of phase are connected to the inputs of the damping circuits 24 and 25, respectively. These damping circuits produce a weak phase shift φ. Their outputs are connected to the two inputs of a 3 dB coupler 23. The output which is 90 ° out of phase with the input connected to the output of the attenuation circuit 24, is terminated with the characteristic impedance 33 of the coupler 23. The output, which is connected to the output of the attenuation circuit 24 Input is in phase is connected to one input of a 3 dB coupler 21, the other input of which is connected to the 90 phase shifted output of the coupler 20 is connected via a phase shifter 28, which is applied to it Signal shifted in phase by φ (the phase shift introduced by the attenuator circuits). The phase shifter 28 can consist of a line section. The coupler 21, whose input signals are 90 out of phase there is one of its exits, the one with the

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Characteristic impedance 31 is completed, no power. Its other output forms the output of the correction circuit 12th

This arrangement works as follows: input 11 the device receives a modulated radio frequency signal with low value. This signal is transmitted through the correction circuit 12, in which it is replaced by the output signal of the comparator 16 and is modified by the transfer characteristic of the correction circuit 12, as further explained in more detail below. The signal with low value is amplified by the preamplifier 18, which is used for the weak signals applied to it is perfectly linear. The power amplification takes place in the amplifier 13, the is not linear for all values of the signals applied to it. His reinforcement G. f (u) changes as a function from its input voltage. The damping circuit 15, the damping factor of which is -, is an analog to the input signal of the amplifier 13, but through the nonlinear changes in gain influenced signal away. This modulated high frequency signal is generated by the demodulator 27 demodulated, while the input signal of the amplifier 13 is demodulated by the demodulator 26. the The transit time of the amplifier 13 is small (several nanoseconds). There are also the lines which the input signal and the output signal of the amplifier 13, very close to the amplifier itself and, more precisely, to the stage in which the distortion of the signal takes place · These lines have up to the demodulators A length of only a few centimeters (in practice 3 cm to 4 cm). Experience shows that is why only a very slight phase shift occurs.

The output signal of the comparator 16 is sent to the control inputs

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of the two damping circuits 24 and 25 are applied. if the maximum allowable value of each of these damping circuits is about 500 mV, the use of two damping circuits allows the input 11 of the amplification device to apply a signal whose peak value is 1 V.

The correction circuit 12 described above thus contains two parallel main paths between the outputs of the coupler 20 and the inputs of the coupler 21. The first path, which contains the phase shifter 28, carries half of the Input power. The second path, which contains the damping circuits, modulates the signal fed to it as a function from the output signal of the comparator 16. A DC voltage is superimposed on this signal which represents the optimum Working point to choose allowed by the damping factor of the damping circuits is brought to a certain value as long as the value of the output signal of this comparator constant is what a linear gain in dsm amplifier 13 corresponds.

The damping factor changes between a minimum value and this particular value according to the changes of the output signal of the comparator for the non-linearities of the gain of the amplifier. The attenuation characteristic of the Attenuation circuit as a function of the current shows that in the middle section the attenuation is essentially linear (Fig. 4).

The introduced changes in attenuation thus precisely follow the non-linearities of the amplified signal. That on that The modulated signal applied to the input 11 of the amplification device is thus transmitted through the damping circuits according to a opposite to the gain changes of the amplifier

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Law modulates.

The correction circuit 12 is a passive system which does not require an additional power supply. Also is this system is quasi-aperiodic and only requires phase control that is independent of the amplifier used.

The correction achieved in this way is independent of the frequency, since it acts directly on the modulation of the signal will. The length of the connections between the couplers and the comparator 16 and between the output of the comparator * tors 16 and the correction circuit 12 is therefore not critical. The amplification device multiplies the maximum output power, which can be achieved without this correction device under the same linearity conditions, approximately with two.

To improve the correction of these modulated signals it may be useful to have a facility with a dependency of the variable gain frequency to be inserted into the correction circuit.

An example of this is given with reference to FIG. 3. It is assumed that the input signal is a modulated Remaining sideband carrier for a color television signal is. Experience then shows that the output from the comparator Correction signal in the band of the chrominance subcarrier is advantageously increased in amplitude.

3 shows the detailed circuit diagram of the comparator 16 of Fig. 2 to which a circuit for performing the aforesaid amplitude correction is added. The comparator 16 has two inputs (26) and (27), which are the outputs of the demodulators 26 and 27.

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These two inputs are connected to the minus and plus inputs of a differential amplifier 160 on the one hand and via two resistors 161 or * 162 connected to the ground of the circuit. The constant component that is required in order to bring the output signal of the amplifier to an operating point which is compatible with the characteristic curve (FIG. 4) of the attenuation circuits 24 and 25 of FIG Using a circuit set in series between the output of amplifier 160 and the DC supply voltage source -V has a Zener diode 163 and a resistor 164. A series connection of a potentiometer 165 and a resistor 166 is connected to the terminals of the Zener diode 163. A capacitor 167 is connected to the output of the Amplifier 160 connected. The second terminal of the capacitor 167 is connected to the wiper of the potentiometer 165.

The input of the circuit for correcting the amplitude as a function of the frequency is connected to the grinder of the Potentiometer 165 connected.

This input is off via a resistor 172 to the base of an npn transistor 171 and via a series circuit two resistors 174 and 175 connected to the base of an npn transistor 173. The collectors of transistors 171 and 172 are each connected to the DC supply voltage source + V.

The emitters of these two transistors are connected to one another via two series-connected resistors 176 and 177 tied together. The connection point of these two resistors is connected to the DC supply voltage source -V via a resistor 178. This connection point represents the output (17) the amplitude correction circuit. The

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The connection point of the resistors 174 and 175 is with
One terminal of an oscillating circuit, which consists of an induction coil 179 and a capacitor 180. The other terminal of this resonant circuit is with a
Capacitor 181 connected, which on the other hand is connected to the ground of the circuit.

The invention is not restricted to the embodiments described. In particular, one can in the previously
the example under consideration (RF signal modulated by a color television signal) in the correction circuit eliminating the elements shown in FIG. 3 (outside block 16),
on condition that the correction values of the attenuation circuits 24 and 25 are selected as a function of the frequency. In addition, it is possible to use a single attenuation circuit in the correction circuit, thereby reducing the number of couplers to two.
The permissible peak value of the signal at the input 11 is then for a damping circuit, the one permissible
Has a maximum value of 500 mV, limited to 0.7 V.

In order to avoid a comparison with the frequency of the signal to be amplified, especially because of the phase problems when the signal is a modulated signal with a high carrier frequency, the comparisons were made on the demodulated signals. A modification could be the comparison with the intermediate frequency if the device is used in a transmitter which has a stage with a
such frequency has to be carried out with the aid of mixing devices which are inserted in the two transmission paths which connect the two inputs of the comparator to the input of the amplifier and to the output of the attenuation circuit.

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The correction is then also made by simple summation be carried out with intermediate frequency.

Under these conditions the input of the amplification device leads the intermediate frequency and its output carries a higher frequency. The connection of the correction circuit with the input of the amplifier takes place via the mixer of the transmitter, which converts the intermediate frequency into the Transmit frequency executes.

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Claims (4)

Patent claims: 1.JverStärkungseinrichtung with an amplifier, marked by a damping circuit, the input of which is connected to the output of the amplifier, by a first and a second channel, the inputs of which are connected to the input of the amplifier and to the output of the attenuation circuit, respectively, through a comparator with two Inputs that are connected to the output of one channel or to the output of the other channel, and through a correction circuit with a correction input which is connected to the output of the comparator, with a Signal input, which is the input of the amplification device forms, and having an output connected to the input of the amplifier, the output of the amplifier forms the output of the amplification device. 2. Reinforcement device according to claim 1, characterized in that that the first and second channels are cables and that the correction circuit is a summer. 3. Amplification device according to claim 1 for amplifying amplitude-modulated high-frequency signals, characterized in that that the first and the second channel each have a demodulator that the correction circuit is a variable gain circuit and that the correction input is the gain control input the correction circuit is. 4. Reinforcement device according to claim 3 for reinforcement a high-frequency carrier with residual sideband amplitude-modulated by a color television signal, characterized in that that the correction input of the correction circuit with the 509881/0991 Gain control input is connected via a circuit that controls the amplitude of the output signal of the comparator increases in the frequency band of the chrominance subcarrier. 509881/09 91 Blank page