RU130764U1 - RADIO TRANSMISSION POWER AMPLIFIER - Google Patents

Abstract

A power amplifier of a radio transmitting device comprising a radio signal amplifier with signal level sensors and an information display device, characterized in that it includes a microcontroller unit, a bias voltage control device, a filter unit with a traveling wave and power coefficient meter, an adjustable switching power supply with current sensors, voltage and temperature, voltage and current control unit of an adjustable switching power supply, while the radio signal amplifier contains an amplification cascade, a buildup cascade of the final amplification cascades, final amplification cascades and measuring instruments for the traveling wave coefficient and power, and each amplification stage uses broadband transformers on coordinated multi-wire lines, and for each generator element of the amplification stage there is a separate adjustable bias voltage source, in addition , signal level sensors include temperature sensors of the generator elements, while the outputs of the signal level sensors, current sensors, n voltage and temperature of the regulated switching power supply and the KBV and power meters are connected to the corresponding inputs of the microcontroller unit, the outputs of the microcontroller unit are connected to the input of the bias voltage control device and the input of the voltage and current control unit of the regulated switching power supply, the outputs of which, in turn, are connected to the inputs of the amplification stages and the input of an adjustable switching power supply, in addition, the output of the microcontroller unit is connected to the input of the device

Description

The inventive utility model relates to the field of electrical engineering and can be used in broadband automated radio transmitting power amplification modules.

A known power amplifier comprising a preamplifier, two amplifier modules, an adjustable phase shifter, an adjustable bias voltage source, a power addition bridge, a ballast resistor, further comprising a current sensor and a unit for analyzing current changes in the ballast resistor and generating control signals for the phase shifter and voltage source bias, while the current sensor is connected between the housing terminal of the ballast resistor and the housing, and its output is connected to the input of the analysis unit changes t OKA in the ballast resistor and the formation of control signals of the phase shifter and the bias voltage source, one output control circuit of which is connected to the input of the control circuit of the adjustable phase shifter, and the other is connected to the control input of the controlled bias voltage source (RF patent No. 71197, 2008).

The disadvantages of this amplifier include:

1. The lack of control of the load currents of the generator elements of the end stages, which, when using an adjustable bias voltage source, working according to the data obtained from the output current sensor of a high-frequency (HF) signal on the ballast resistor and the error signal from the phase shifter, can lead to the output of the generator elements from the working mode (undervoltage, overvoltage), the consequence of which is a decrease in the coefficient of performance (COP) and the reliability of the amplifier.

2. Lack of control and adjustment of the operating mode of the generator elements of the preliminary amplification stage, which, in turn, when adjusting the generator elements of the terminal amplification stages of the current in the ballast resistor, can lead to failure to comply with the requirements for attenuation of harmonic and discrete components in the output signal, as well as not meeting the requirements for non-linear distortion in the telephone modes of the amplifier.

Also known is a power amplifier comprising a radio signal amplifier, an operating mode reading device, an operating mode adjustment device and a storage device, further comprising N signal level sensors at N amplifier points predetermined for monitoring and an information display device, the outputs of signal level sensors connected to the N inputs of the storage device, the input of the operating mode reader is connected to the amplifier point controlled for adjustment by the radio clock from, and its output is connected to the input of the storage device corresponding to it, the input of the operating mode adjustment device is connected to the output of the storage device, and its output is connected to an adjustable amplifier element, the other output of the storage device is connected to the input of the information display device (RF patent No. 95924, 2010 g.). This amplifier is taken as the closest analogue.

The disadvantage of this amplifier is the use of one adjustable element on N generator elements, the change of the operation parameters of which is carried out by the resulting signal from N sensors, which does not allow to achieve high performance, reliability, nonlinear distortion, suppression of higher harmonic and discrete components in the output RF signal in a wide band of operating frequencies.

The technical result, which is achieved by the claimed utility model, is to provide high reliability indicators, efficiency. attenuation of higher harmonic and discrete components of the output RF signal, reduction of nonlinear distortions in the telephone operating modes of the amplifier, as well as in the expansion of the range of operating frequencies of the power amplifier.

The specified technical result is achieved in that the power amplifier of the radio transmitting device, comprising a radio signal amplifier with signal level sensors and an information display device, includes a microcontroller unit, a bias voltage control device, a filter unit with a traveling wave coefficient (KBV) meter and an adjustable pulse power a power source (RIIP) with current, voltage and temperature sensors, a voltage and current control unit of the RIIP, while the radio signal amplifier contains the gain amplification cascade, the amplification cascade of the terminal amplification cascades, the amplification terminal cascades, and KBV and power meters, broadband transformers on coordinated multi-wire lines are used in each amplification cascade, and for each generator element of the amplification cascade there is a separate adjustable bias voltage source, in addition to level sensors signals include temperature sensors of the generator elements, while the outputs of the signal level sensors, sensors of currents, voltages and temperatures RIIP and KBV and power meters are connected to the corresponding inputs of the microcontroller unit, the outputs of the microcontroller unit are connected to the input of the bias voltage control device and the input of the RIIP voltage and current control unit, the outputs of which, in turn, are connected to the inputs of the amplification stages and the input of the RIIP Togo. the output of the microcontroller unit is connected to the input of the information display device, and the output of the radio signal amplifier is connected to the filter unit.

The utility model is illustrated by diagrams, which depict:

- figure 1 is a structural diagram of a power amplifier of a radio transmitting device;

- figure 2 is a structural diagram of a radio signal amplifier.

According to Figure 1, the power amplifier of the radio transmitting device comprises a radio signal amplifier 1, signal level sensors 2, a bias voltage control device 3, a microcontroller unit 4, a filter unit 5, an adjustable switching power supply (RIIP) 6, a voltage and current control unit RIIP 7, information display device 8, current, voltage and temperature sensors 9, KBV and power meters 10.

According to Fig. 1, 2, the radio signal amplifier 1 includes a preliminary amplification stage 11, a cascade of buildup of the final amplification stages 12, two end amplification stages 13, and KBV and power meters 10. To ensure the possibility of operating in a wide frequency range, the high-frequency powerful generator elements 14, for example, paired field-effect transistors 2P978G or 2P979V. and as resistance transformers in the amplification stages 11, 12 and 13, broadband transformers are used on coordinated multi-wire lines 15. To ensure the operation of the generator elements 14 in the optimal mode, an adjustable bias voltage source 16 is installed in each of the amplification stages 11, 12 and 13, while in the end stages, the bias voltage is individually regulated for each generator element 14.

The signal level sensors 2 include RF voltage sensors at the input of amplification stages 11, 12, and 13 and temperature sensors at the generator elements 14.

The bias voltage control device 3 is a digital-to-analog converter for generating control signals to adjustable bias voltage sources installed in the amplification stages 11, 12, and 13.

The microcontroller unit 4 is a control microcomputer based on controllers, for example AT90CAN128-16MU, and operates under the multitasking operating system MMO.S. It analyzes signals from sensors 2, 9 and KBV and power 10 meters and generates control commands to the device control voltage bias 3 and the control unit voltage and current 7, and also provides the issuance of information about the parameters of the power amplifier to the information display device 8.

Filter block 5 is designed to suppress the higher harmonic and discrete components of the high-frequency voltage of the working frequency of the radio signal amplifier 1 and constructively consists of two blocks: the first block is designed to operate in the frequency range 1.5-30.0 MHz and contains 7 harmonic filters, the second block is designed for operation in the frequency range 28.0-80.0 MHz and contains 3 harmonic filters. Each harmonic filter consists of a high and low pass filter. In addition, the filter unit 5 contains a meter KBV and power 10.

Adjustable switching power supply (RIIP) 6 is designed to generate DC voltages for power supply of the power amplifier and includes two power modules with an output voltage of up to 50V and a current of up to 50A and one power module with an output voltage of up to 50V and a current of up to 30A. For each power module installed sensors of current, voltage and temperature 9.

The RIIP 7 voltage and current control unit is a digital-to-analog converter for generating control signals to the RIIP 6 power modules.

The information display device 8 is made on the basis of a liquid crystal panel and is intended to display the operating parameters of the power amplifier.

The outputs of the signal level sensors 2, current, voltage and temperature sensors 9, and KBV and power 10 meters are connected to the corresponding inputs of the microcontroller unit 4. The outputs of the microcontroller unit 4 are connected to the inputs of the bias voltage control device 3 and the RIIP voltage and current control unit 7. Device outputs control voltage bias 3 connected to the inputs of the cascades of amplification 11, 12 and 13, and the outputs of the voltage and current control unit RIIP 7 are connected to the inputs of RIIP 6. In addition, the output of the microcontroller unit 4 s one with the input information display device 8, and the output RF signal of the amplifier 1 is connected to a filter unit 5.

Thus, a deep feedback is formed in the power amplifier, ensuring the maintenance of optimal operating modes of all elements of the power amplifier, depending on the load parameters, a given output power level, established radiation classes, and environmental parameters.

The power amplifier of the radio transmitting device operates as follows.

When the power amplifier is turned on, amplification stages 11, 12 and 13 in the radio signal amplifier 1 set the initial bias voltage values, and in RIIP 6 the initial voltage values of the amplification stages 11, 12, and 13 so that the output RF power level corresponds to approximately 20% of rated. For a time of the order of 3.0 ms, the microcontroller unit 4 collects information from sensors 2, 9 and KBM and power 10 meters, and, depending on the load KBW level and the output power level set by the operator, generates control commands to the bias voltage control device 3 and the control unit voltage and current RIIP 7 for setting optimal operating modes of the generator elements 14 of the radio signal amplifier 1.

Subsequently, the microcontroller unit 4 interrogates the sensors 2, 9 and the KBV and power meters 10 and, depending on the obtained values of the output power, the temperature of the generator elements 14, the load current of the amplification stages 11, 12 and 13, generates control commands to the bias voltage control device 3 and the control unit voltage and current RIIP 7 to maintain optimal operating conditions of the generator elements 14.

All data taken from the sensors, at the request of the operator, can be displayed on the information display device 8 to check the operability of all nodes of the power amplifier.

Thus, due to the branched control and data processing system, the microcontroller unit provides automatic control of the operation of the radio transmitting device as a whole. The realized possibility of separate control of the bias voltage and the supply voltage of the generator elements of the radio signal amplifier allows to ensure high efficiency of the device up to 45%, and, as a result, to improve reliability indicators. Optimization of the operating modes of the generator elements allows to reduce the level of higher harmonic and discrete components in the output RF signal, as well as to reduce the level of nonlinear distortion when working in the telephone operating modes of the amplifier. The use in amplification stages of powerful high-frequency generator elements and resistance transformers, built on the basis of broadband transformers on coordinated multi-wire lines, allows you to expand the operating frequency range of the power amplifier to 80 MHz.

Claims (1)

A power amplifier of a radio transmitting device comprising a radio signal amplifier with signal level sensors and an information display device, characterized in that it includes a microcontroller unit, a bias voltage control device, a filter unit with a traveling wave and power coefficient meter, an adjustable switching power supply with current sensors, voltage and temperature, voltage and current control unit of an adjustable switching power supply, while the radio signal amplifier contains an amplification cascade, a buildup cascade of the final amplification cascades, final amplification cascades and measuring instruments for the traveling wave coefficient and power, and each amplification stage uses broadband transformers on coordinated multi-wire lines, and for each generator element of the amplification stage there is a separate adjustable bias voltage source, in addition , signal level sensors include temperature sensors of the generator elements, while the outputs of the signal level sensors, current sensors, n voltage and temperature of the regulated switching power supply and the KBV and power meters are connected to the corresponding inputs of the microcontroller unit, the outputs of the microcontroller unit are connected to the input of the bias voltage control device and the input of the voltage and current control unit of the regulated switching power supply, the outputs of which, in turn, are connected to the inputs of the amplification stages and the input of an adjustable switching power supply, in addition, the output of the microcontroller unit is connected to the input of the device display information, and the output of the radio signal amplifier is connected to the filter unit.

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