SU1764135A1 - Two-loop system of amplifier automatic control - Google Patents

Abstract

Use: radio engineering, amplifiers with automatic gain control. The essence of the invention: two-looped. 2, the system contains a block with controlled transmission coefficient — a power amplifier, a power detector, 2 comparison elements, a current sensor, an analog-digital converter, a storage unit, a comparison element, a D-flip-flop, an And element, a clock generator, a counter, a decoder, and controlled output transformer. The goal is to equalize the efficiency in the dynamic range over the output power — this is achieved, in particular, by alternating the operation of the power control circuit and the efficiency control circuit of the power amplifier. 2 Il.

Description

The present invention relates to the field of radio engineering and can be used in power amplifiers with automatic gain control in order to increase efficiency,

A significant number of devices are known that provide automatic power control (APM) of amplifiers with the goal of maintaining a given output power when the supply voltage or ambient temperature changes. The basis of these devices is a change in the output power of the amplifier due to a change in the magnitude of the input power or gain of the amplifier.

The closest in technical essence of the present invention is a device in which two control loops are contained. One circuit ensures the maintenance of a given output power of the amplifier, the other ensures the operation of the amplifier under these conditions with the highest efficiency. Each value of the control signal corresponds to a certain value of the output power (in accordance with the slope of the preamplifier) and a certain value of the current consumption (in accordance with the slope of the current source). The principal disadvantage of this construction of automation is the need for a very accurate correlation of both control characteristics — current and power — over the entire range of values of the external control signal. In the event that the current consumption control slope is insufficient with respect to the output power control slope, the specified output power will not be reached at all due to the current consumption limitation; In the case of the reverse situation of redundancy in the current consumption control steepness, there will be an unreasonably high power consumption by the amplifier, i.e. a deterioration in its efficiency.

The purpose of the invention is to increase the efficiency of an amplifier with an AWP under conditions of variable output power .:

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This goal is achieved by the fact that in a two-loop automatic control system a power amplifier comprising a series-connected controlled-gain unit and a power amplifier, a series-connected power detector and a reference element, the other input of which is a reference power control input connected between the output power amplifier and control input of the unit with a controlled transmission coefficient and efficiency control circuit of the power amplifier, including yes A current in the power supply circuit of the power amplifier is additionally inserted in the Efficiency control circuit of a series-connected analog-to-digital converter connected to a current sensor, a storage unit and a matching element, another input of which is connected to the output of an analog-digital converter, a D-flip-flop, whose information input is connected to its inverse output, the clock input to the output A of the comparison element, where A and B are the signals at the outputs of the analog-digital converter and the storage unit, respectively, connected clock generator, a counter and a decoder, and an additional reference element connected in series, one input of which is connected to the output of the reference element and the other is the input of the reference voltage, and the AND element whose other inputs are connected to the forward output of the D-flip-flop and output of the higher bit of the counter, respectively, the output of the element I is connected to the input of the stop of the clock generator, the output of which is connected to the recording input of the memory block, while the input of the generator start is The coding pulses, the D-flip-flop and counter reset inputs are the start-up input of the two-loop system, and the output of the decoder is connected to the control input of the transformation ratio of the controlled output transformer.

A comparison with the prototype shows that the novelty of the proposed device lies in the presence of a controlled output transformer and an efficiency control circuit containing an analog-digital converter, a storage unit, a comparison element, a D-flip-flop, a clock generator, a counter, a decoder, an additional comparison element.

Comparison with other technical solutions shows that the essential difference of the proposed device lies in the possibility of automatically ensuring the maximum efficiency of the amplifier at different values of the output power.

FIG. Figure 1 shows a two-loop automatic control system for a power amplifier; in fig. 2 is a scheme for adjusting the efficiency of a power amplifier. Two-loop automatic system

0 control for power amplifier 1 contains a controlled attenuator 2, a controlled transformer 3, a power detector 4, a comparison circuit 5, an amplifier efficiency control circuit 6, a measuring

5 resistance 7 connected in such a way that controlled attenuator 2, amplifier 1 and controlled transformer 3 form a series between the master oscillator and a constant load, the input of the power detector 4 is connected to a constant load, and the output is connected to the first input of the circuit 5 comparison, the second input of the comparison circuit 5 is connected to the power control circuit, and

5, the output is connected to the control input of the controlled attenuator 2 and one of the inputs of the efficiency control circuit 6, the other inputs of the circuit 6 are connected to the start circuit and both terminals of the measuring resistor 7, the outputs are connected to the control inputs of the controlled transformer 3, the measuring resistance 7 is connected in series to the power supply circuit.

5 The amplifier efficiency control circuit 6 contains an analog-to-digital converter (ADC) 8, five D-flip-flops 9-13, a digital 14 and an analog 15 comparison circuit, a matching circuit 16, a clock generator

0 17, the counter 18, the decoder 19, connected in such a way that the inputs of the ADC 8 are connected to the terminals of the measuring resistance 7, the outputs are connected to the D inputs of the flip-flops 9-12 and the inputs of the digital circuit 14 compared to the outputs of the flip-flops 9-12 connected to the inputs digital circuit 14 of the comparison, the output of the digital circuit 14 of the comparison is connected to the C-input of the trigger 13, the inverse output of the trigger 13 is connected to the D-input of the same

0 flip-flop, trigger output 13 is connected to one of the inputs of the matching circuit 16, the second input of the matching circuit 16 is connected to the output of the analogue comparison circuit 15, the third input is connected to the discharge transfer output

5 of the counter 18, the output of the coincidence circuit 16 is connected to the inhibition input of the clock generator 17, the output of the clock generator 17 is connected to the C inputs of the flip-flops 9-12 and the C input of the counter 18, the outputs of the counter 18 are connected to the inputs of the decoder 19. the outputs of the decoder 19 are connected with the control inputs of the controlled transformer 3, the first input of the analog comparison circuit 15 is connected to the output of the comparison circuit 5, the second input is connected to the voltage source, the trigger input of the clock generator 17 is connected to the starting circuit, the R input of the trigger 13 and R-in - house counter 18

Attenuator 2, power detector 4, comparison circuit 5 form the known loop structure of the power amplifier workstation.

Controlled transformer 3 is designed to change the load value of amplifier 1 by changing the transformation ratio under the action of control signals, for example, by switching the transformer windings p1n-d | dodami.

The efficiency control scheme B is used to generate signals for controlling the magnitude of the transformation ratio, providing the highest possible efficiency, according to the following algorithm

- the operation of the circuit starts on a trigger signal from an external device,

- in the presence of a start signal, the efficiency control scheme B ensures a monotonous change in the transformation ratio until a) with a change in the transformation ratio, the current consumption of the amplifier decreases, b) the limit of the range of change of the controlled transformer is reached, c) the limit of the range of the controlled is not reached Attenuator If one of the above conditions fails, the efficiency of the efficiency control circuit stops. An example of the implementation of this algorithm on 564 series microcircuits is shown in FIG. 2

The operation of the device is as follows.

The efficiency control circuit 6 receives a trigger signal from an external circuit. By this signal, the trigger 13 is set to a single output position, the counter 18 and the decoder 19 are set to the extreme position, providing the transformation ratio of the controlled transformer 3, which is necessary to obtain the maximum power in the load, the clock generator 17 is started. The power control circuits are fed to the input of the comparison circuit 5, which is proportional to the required power 8 to the load. With the set transformation ratio, which allows to get the maximum power in the load, the loop of the workstations amplifier will always set in the load

given power. For normal operation of the device, it is necessary that the time constant of the AWP loop be less than the frequency of the clock generator 17. Under the influence of the clock generator 17, the counter 18 and the decoder 19 change their state from the extreme position. The control signals from the output of the decoder 19 switch the windings of the controlled

0 of transformer 3, thereby changing the transformation ratio of a constant load to the output of the amplifier. Obviously, the initial load value intended to obtain the maximum power is not optimal from the point of view of obtaining the maximum efficiency at a given power. Therefore, a change in the load (at least in the first step) will lead to a decrease in the current consumption of the amplifier while maintaining a given power in the load using an AWP loop, i.e., it will increase the efficiency

The operation of the clock generator 17 will be

5, as long as a change in load leads to a decrease in current consumption. The control over the current consumption is controlled by an analog-to-digital converter (ADC) 8, flip-flops 9-13, and a comparison circuit 14. It is assumed that the ADC contains internally necessary for the generator, whose frequency is much higher than the frequency of the clock generator

5 17. The signal from the clock generator 17 memorizes the current value of the current consumption on the flip-flops 9-12 and compares it in the comparison circuit 14 with the current value that is set after

0 of the next change in transformation ratio. Since the operating time of the AWP loop is much less than the period of the frequency of the clock generator 17, the current consumption is compared with the same power in the load. If the current value of the current consumption is less than the memorized, then the output of the comparison circuit 14 is O. As soon as the current value exceeds the stored value, the output of the comparison circuit 14 is 1, the positive edge will change the output state of the 16 matching circuit and the clock generator 17 will stop Such an ending is

5 normal and indicative of that. that at a given power at the output of amplifier 1 the minimum current consumption is reached, that is, the maximum efficiency is reached,

To ensure absolute stability of the device outside the normal operating range, a clock generator 17 is provided to stop when the range of variation of the controlled attenuator or controlled transformer is reached. Stopping upon reaching the limit of the range of variation of the controlled attenuator is carried out using the comparison circuit 15, to one input of which a signal is output from the output of the comparison circuit 5, to another input - a reference voltage corresponding to the control boundary of the attenuator 2. Upon reaching this limit The signal at the output of the comparison circuit 15 and through the coincidence circuit 16 will stop the clock generator 17. Stop when the limit of the range of change of the controlled transformer 3 is reached is in the presence of a signal transfer at the output of the counter 18 This signal through the coincidence circuit 16 also stops the clock generator 17. After stopping the clock generator 17 according to any of the three criteria, further operation of the device is possible after the next start pulse from the external circuit.

Claims (1)

The given example of a specific implementation of a two-loop automatic control system for a power amplifier proves the possibility of increasing efficiency by minimizing the current consumption of the amplifier using a controlled output transformer and an efficiency control circuit containing an analog-to-digital converter, a storage unit, comparison elements, a clock pulse generator, a counter decoder. Claims of the Invention A two-loop automatic control system for a power amplifier comprising a series-connected control unit and a power amplifier, a power detector and a element connected in series comparison, the other input of which is the reference input of the signal of a controlled set power, connected between the output of the power amplifier and the control input of the unit with a controllable transmission coefficient and the efficiency control circuit of the power amplifier, which includes a current sensor in the power supply circuit of the power amplifier, characterized in that , in order to equalize the efficiency in the dynamic range of the output power, the power amplifier is made with a controlled output transformer, and serially connected analogs are introduced into the efficiency control circuit a go-to-digital converter connected to a current sensor, a storage unit and a comparison element, another input of which is connected to the output of the analog-digital converter, a D-flip-flop, whose information input is connected to its inverse output, a clock one to the output AB of a comparison element, where A and B are the signals at the outputs of the analog-digital converter and the storage unit, respectively, serially connected clock generator, counter and decoder, and serially connected additional element, one input of which is connected to the output of the reference element, and the other is the input of the reference voltage, and the element AND, the other inputs of which are connected to the forward output of the D-trigger and the output of the higher bit of the counter, respectively, the output of the element AND is connected to the input of the stop clock generator, the output of which is connected to the recording input of the storage unit, wherein the trigger input of the clock, the reset inputs of the D-flip-flop and the counter are input of the two-loop system, and the output of the decoder is connected to to control the transformation ratio of the controlled output transformer.  "MFA / ZHGO t by co ponutfle ul f cm t / t) ffCofiocmk O