RU2157585C1 - Broad-band high-frequency push-pull power amplifier - Google Patents

Abstract

FIELD: push-pull power amplifiers. SUBSTANCE: amplifier that has two power amplifiers 1, balancing transformer 3, connecting cable 6, and change- over subband harmonic filters 8 uses low-frequency filter whose cutoff frequency is higher than operating frequency of power amplifier 1. First capacitor 2 of low-frequency filter is installed at input of balancing transformer 3. Series inductance coil 4 and capacitor 5 of low-frequency filter connected in parallel with connecting cable input are inserted in non- balanced circuit between balancing transformer 3 and connecting cable 6. EFFECT: improved efficiency and linearity. 1 dwg

Description

 The invention relates to radio engineering and can be used in high-frequency broadband push-pull power amplifiers that are part of radio transmitting devices.

To transmit high-frequency signals, broadband push-pull power amplifiers (with suppression of even harmonics) are used, the output signal of which is transmitted through switchable harmonic filters, which provide signal transmission with an operating frequency and suppression of harmonic components [L1, L2]. To ensure a linear amplitude characteristic and increase the efficiency of push-pull high-frequency broadband power amplifiers, which usually operate in a nonlinear mode (class B or AB), it is necessary to form the active load resistance at the first harmonic (f ₀ ) and low impedance reactance for odd harmonic components (3f ₀ , 5f ₀ ) of the transmitted signal [L1, L2]. This problem has various solutions.

Known push-pull power amplifiers [L1, p. 115], in which the output circuits contain L-shaped forming circuits (C _FORM , L _FORM ) installed at the outputs of the amplifiers of the push-pull cascade. The presence of two forming circuits in a push-pull amplifier does not allow for the same load resistances for each transistor (due to the deviation of the capacitance and inductance from the nominal value), complicates the design of the L-shaped forming circuits in low-resistance circuits and leads to instability of the amplifiers when working in the field high working frequencies.

 A push-pull power amplifier, selected as a prototype [L2, p. 106], contains a capacitor between the collectors of the transistors of the output circuit, which, together with the dissipation inductance of the transformer, forms a resonance at a frequency higher than the maximum operating frequency by 10%. The frequency of this resonance should change due to a change in the magnetic permeability of the transformer magnetic circuit under destabilizing influences (temperature, moisture, etc.), which will lead to a change in the load resistance for the transmitted signal and for its harmonic components. In addition, the dissipation inductance of a transformer depends on its design, which causes a wide variation in the capacitance of the capacitor between the collectors of transistors, and the load reactance for harmonic components depends on this, which ultimately does not allow to realize the maximum value of the efficiency of the power amplifier.

 The aim of the present invention is to increase the efficiency and linearity of the amplitude characteristic of a high-frequency broadband push-pull amplifier loaded on a switchable harmonic filter. This goal is achieved by the fact that in a high-frequency broadband power amplifier containing a balancing transformer, a connecting cable and sub-band switched harmonic filters, a low-pass filter (LPF) is used with a cutoff frequency higher than the upper working frequency of the power amplifier, and the first LPF capacitor is installed parallel to the output electrodes push-pull cascade of the power amplifier, at the input of the balancing transformer, and the serial inductance and parallel to the input are connected of the power cable, the low-pass filter capacitor is connected in an unbalanced circuit between the balancing transformer and the connecting cable.

 For the transmitted signal, the installation of an LPF with a cutoff frequency exceeding the upper operating frequency does not have a significant effect, since the wave impedances of the cables and the characteristic impedances of the LPF and the harmonic filter are consistent with the load resistance of the power amplifier, and the standing wave path coefficient can be close to 1. For harmonic components of the signal transmitted through a switchable harmonic filter of the upper sub-frequency range, an LPF capacitor installed at the output of a push-pull helmet Yes power amplifier, has a shunt effect.

 For the harmonic components of the signal transmitted through the switchable harmonic filter of the lower frequency subbands, the main shunt effect is exerted by the equivalent input capacitance of the harmonic filter.

 For the harmonic components of the signal transmitted through a switchable harmonic filter of the mid-frequency ranges, the shunt effect is formed due to the input capacitor of the low-pass filter and transformed into capacitive reactance through the balancing transformer of the reactance of the series-connected inductors and capacitors of the second capacitor low-pass filter, as well as the input capacitive reactance transformed through the connecting cable switchable harmonic filter.

The above explanations are confirmed by the following formulas for the equivalent harmonic filter capacitance C _f , counted through the connecting cable to the low-pass filter, - C ' _f and the normalized conductivity of the matching link for the harmonic components of the transmitted signal - Y.

где f - частота гармоники передаваемого сигнала;
l₁ - длина соединительного кабеля;
ε - диэлектрическая проницаемость внутренней изоляции кабеля;
R - волновое сопротивление кабеля;
с - скорость света в пространстве.

where f is the harmonic frequency of the transmitted signal;
l ₁ - the length of the connecting cable;
ε is the dielectric constant of the inner insulation of the cable;
R is the wave impedance of the cable;
c is the speed of light in space.

где f₁ - частота среза ФНЧ;
α₁, α₂ - нормированные значения элементов ФНЧ;
l₂ - длина кабеля симметрирующего трансформатора;

Сопоставительный анализ схемы с прототипом показывает, что заявляемое устройство отличается по структуре и соединениям, следовательно, оно соответствует критерию "новизна". Трансформирующие свойства длинных линий (кабелей) широко известны, однако использование их в сочетании с элементами ФНЧ в высокочастотных широкополосных согласующих устройствах с целью обеспечения передачи сигнала с рабочей частотой и шунтирования высших гармонических составляющих позволяет сформировать оптимальную нагрузку для двухтактного усилителя мощности, вследствие чего повышаются линейность амплитудной характеристики и КПД усилителя мощности, из чего следует вывод о соответствии технического решения критерию "существенные отличия".

where f ₁ is the cutoff frequency of the low-pass filter;
α ₁ , α ₂ - normalized values of the elements of the low-pass filter;
l ₂ - cable length of the balancing transformer;

A comparative analysis of the circuit with the prototype shows that the inventive device differs in structure and connections, therefore, it meets the criterion of "novelty." The transforming properties of long lines (cables) are widely known, however, their use in combination with low-pass filter elements in high-frequency broadband matching devices in order to ensure the transmission of a signal with an operating frequency and shunting of higher harmonic components allows you to create the optimal load for a push-pull power amplifier, thereby increasing the linearity of the amplitude characteristics and efficiency of the power amplifier, from which it follows that the technical solution meets the criterion of "significant e differences. "

 The drawing shows a structural diagram of a high-frequency broadband push-pull power amplifier, consisting of two amplifiers 1, a first low-pass filter capacitor 2, a balanced transformer 3, an low-pass filter inductance 4, a second low-pass filter capacitor 5, a connecting cable 6, two high-frequency switches 7 and harmonic filters 8.

 The device operates as follows. The out-of-phase signal from the output of amplifiers 1 is fed to the low-pass filter capacitor 2 and the input of the balancing transformer 3, the output of which is connected to other low-pass filter elements - inductance 4 and capacitor 5. Since the cut-off frequency of the low-pass filter is higher than the upper operating frequency, the wave impedance and the characteristic resistance of the low-pass filter are matched, then the signal with the operating frequency is transmitted to the matched load without attenuation. Next, the signal through the connecting cable 6 with a wave impedance equal to the load, is transmitted through the switches 7 and the harmonic filter 8 to the matched payload. The signal with the working frequency from the output of the push-pull amplifier 1 is transmitted to the output through the connecting, matching and filtering circuits without attenuation, since the reflection losses, determined by the total coefficient of the standing wave of the path, can be minimized by choosing the values of the elements.

 The odd harmonic components of the transmitted signal through the harmonics filter of the upper frequency subband are bridged by the low-pass filter capacitor 2. Suppression of even harmonics of the transmitted signal is carried out by a typical circuit of a push-pull amplifier.

 The odd harmonic components of the transmitted signal through the harmonics filter of the middle sub-range of frequencies are bridged by the total capacitance of the low-pass filter capacitor 2 and the balancing transformer 3 inductors 5 connected in series 5 and the low-pass filter capacitor 5 taking into account the reactivity transformed by the connecting cable 6, equivalent to the input capacitance of the harmonic filter 8.

 The odd harmonic components of the signal transmitted through the harmonics filter of the 8 lower frequency subbands are bridged by the equivalent input capacitance of the harmonic filter 8. The cable lengths of the balancing transformer 3 and the connecting cable 6 must be selected so that the equivalent load capacitance for the odd harmonics of the signal transmitted through the harmonics filter 8 of each sub-band, had a shunting effect.

 The odd harmonic components of the transmitted signal through the harmonics filter 8 of the lower frequency subbands are bridged by the equivalent input capacitance of the harmonics filter 8.

 Due to the shunt effect of the equivalent load capacitance for odd harmonics, the voltage shape at the output electrodes of the push-pull amplifier is sinusoidal in nature, and each amplifier 1 operates in under-stress mode, and the operating point does not fall into the critical mode line region even at the maximum allowable power output, which determines the linearity of the amplitude amplifier specifications. Shunt capacitive load reactivity for the odd harmonic components of the transmitted signal does not increase the current pulse of the transistor. The current consumption of the transistor is proportional only to the current of the first harmonic, the power of which is released in the payload, which increases the efficiency of the amplifier.

 The above formulas allow you to choose the optimal values of the low-pass filter elements, harmonic filters, the length of the connecting cable and the cable length of the balancing transformer. Positive experimental results are confirmed by calculations. The efficiency of the considered amplifier is not lower than 50% in the entire operating frequency range with the degree of suppression of intermodulation products greater than or equal to minus 33 dB, which is higher than that of the prototype.

Sources of information
1. Design of radio transmitting devices. Edited by V.V. Shahgildyan. M .: Radio and communication, 1993, p. 115.

 2. RED. E. Reference manual on high-frequency circuitry. - M .: Mir, 1990, p. 106.

Claims (1)

 A high-frequency broadband power amplifier containing a push-pull amplifier stage, a balancing transformer, a connection cable and switchable sub-band harmonic filters, and characterized in that the signal of the amplifier stage is transmitted to the connection cable and switchable sub-band harmonic filters through a low-pass filter (LPF) with a cutoff frequency, exceeding the upper operating frequency of the power amplifier, and the first low-pass filter capacitor is installed parallel to the output electrodes of the power amplifier at the input of the balancing transformer, and the series inductance and the low-pass capacitor parallel to the input of the connecting cable are connected in an asymmetric circuit between the balancing transformer and the connecting cable.