CN210745087U - Efficient high-linearity power amplifier for Internet of vehicles - Google Patents

Abstract

The utility model discloses a high-efficient high linearity power amplifier towards car networking, shift the phase network including the distribution of input single-ended to differential power, first from three to pile up the amplifier network, the second from three to three piles up the amplifier network, the third from three to three piles up the amplifier network, the fourth from three to three piles up the amplifier network and output differential changes single-ended power synthesis and shift the phase network, the utility model discloses the core framework adopts the self-biased three that heterojunction bipolar transistor constitutes to pile up the amplifier network at the high power of radio frequency microwave section, high gain characteristic, utilizes differential amplifier to roll back the good parasitic parameter rejection nature in microwave frequency range simultaneously, and the power that the structure is good with Doherty amplifier rolls back efficiency characteristic and combines together for whole power amplifier has obtained good high gain, high efficiency and the high power output ability of rolling back.

Description

Efficient high-linearity power amplifier for Internet of vehicles

Technical Field

The utility model relates to a heterojunction bipolar transistor radio frequency power amplifier and integrated circuit field, especially to the high-efficient high linearity power amplifier chip circuit towards the car networking based on the transmission module of car networking communication (C-V2X) application of cellular technology.

Background

With the rapid development of 5G wireless communication systems and radio frequency circuits, the car networking communication based on the 5.9GHz frequency band cellular technology also has unprecedented application space, and the radio frequency front-end receiving and transmitting circuit of the car networking communication system also develops towards the directions of high performance, high integration and low power consumption. Therefore, the radio frequency power amplifier of the transmitter is urgently required by the internet of vehicles communication market to have high linear output power and efficiency, reduce heat dissipation and improve circuit stability, and the power amplifier chip is the key expected to meet the market requirement. However, when the integrated circuit process design is adopted to realize the power amplifier chip circuit in the car networking communication market, the performance and the cost of the power amplifier chip circuit are limited to a certain extent, and the performance and the cost are mainly reflected as follows:

(1) the power amplifier efficiency is limited under high back-off power, and the power consumption is higher: when the traditional AB type power amplifier realizes the amplification of a high peak-to-average ratio signal, the efficiency is lower under high back-off power, so the power consumption is larger.

(2) Power gain is limited, and insertion loss degradation is large: the 5.9GHz frequency band is usually realized by adopting a semiconductor process with lower cost and lower characteristic frequency, so that the single-tube gain of the power amplifier is limited, the parasitic parameters of a transistor become larger along with the increase of the frequency band, the parasitic loss of a circuit is greatly deteriorated, and the performance of the circuit is influenced;

(3) limitations with lumped parameter circuit design: when a circuit matched with the traditional lumped parameter RLC is designed in the 5.9GHz frequency band, devices with larger chip areas such as an inductor and a capacitor still need to be adopted, and the limitation is brought to the circuit design because the substrate loss is increased and the inductance Q value is lower.

The common circuit structures with high linear output power and efficiency amplifiers are many, the most typical is a Doherty single-ended power amplifier, but the difficulty is high when the traditional Doherty single-ended power amplifier needs to meet the power amplifier index requirements of the communication market of the internet of vehicles at the same time, mainly because:

(1) when the traditional Doherty single-ended power amplifier realizes the circuit design of a 5.9GHz frequency band, the backspacing efficiency index is poor due to the influence of parasitic parameters;

(2) when the traditional Doherty single-ended power amplifier realizes the circuit design of a 5.9GHz frequency band, an AB class driving amplifier is often adopted to drive the Doherty amplifier, so that when the Doherty amplifier works with the back-off efficiency and is subjected to the gain compensation effect of the AB class amplifier, the good load traction effect under the high back-off of a main circuit and an auxiliary circuit of the Doherty amplifier cannot be met at the same time, the back-off efficiency is reduced, and the linearity index is deteriorated.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a high-efficient high linearity power amplifier towards the car networking is provided, has combined the difference and has piled up the advantage of amplifier technique, doublestage Doherty drive technique, has at radio frequency microwave frequency channel high power, high gain and advantage such as with low costs. Meanwhile, a heterojunction bipolar transistor with a self-bias structure is adopted, so that a complex power supply circuit of a depletion transistor is avoided.

The utility model provides an above-mentioned technical problem's technical scheme as follows: a high-efficiency high-linearity power amplifier oriented to the Internet of vehicles is characterized by comprising an input single-end-to-differential power distribution phase-shifting network, a first self-biased three-stacked amplifying network, a second self-biased three-stacked amplifying network, a third self-biased three-stacked amplifying network, a fourth self-biased three-stacked amplifying network and an output differential-to-single-end power synthesis phase-shifting network;

the input end of the input single-end to differential power distribution phase shift network is the input end of the whole power amplifier, the first, second, third and fourth output ends of the input single-end to differential power distribution phase shift network are respectively connected with the input ends of the first, third, second and fourth self-biased three-stacked amplifying networks, and the phase difference between the input end of the input single-end to differential power distribution phase shift network and the signal phase difference between the input end of the input single-end to differential power distribution phase shift network and the first, second, third and fourth output ends is respectively 0 degree, 90 degrees, 180 degrees and 270 degrees;

the output ends of the first, second, third and fourth self-biased three-stack amplifying networks are respectively connected with the first, third, second and fourth input ends of the output differential-to-single-ended power synthesis phase-shifting network, the output end of the output differential-to-single-ended power synthesis phase-shifting network is the output end of the whole power amplifier, and the signal phases of the output end of the output differential-to-single-ended power synthesis phase-shifting network and the first, second, third and fourth input ends are respectively different by 270 degrees, 180 degrees, 90 degrees and 0 degree.

Furthermore, the input end of the input single-end-to-differential power distribution phase-shifting network is connected with an inductor L₁Inductance L₁The other end of the transformer is connected with a coupling transformer T₁Dotted terminal of primary coil and grounding capacitor C₁Transformer T₁The non-homonymous end of the primary coil of (1) is grounded; transformer T₁The first, second and third homonymous terminals of the secondary coil are connected with the first, second and third output terminals of the input single-ended-to-differential power distribution phase-shifting network, and the transformer T₁The non-homonymous end of the stage coil is connected with the fourth output end of the input single-ended-to-differential power distribution phase-shifting network.

The beneficial effects of the further scheme are as follows: the utility model discloses an input single-ended changes differential power distribution phase shift network except can realizing the power distribution of input radio frequency signal, can also carry out impedance match and phase adjustment to radio frequency input signal, realizes single-ended signal to differential signal's conversion simultaneously, guarantees differential signal's phase difference. The phase difference between the input end of the input single-ended-to-differential power distribution phase shift network and the signal phase difference between the input end of the.

Furthermore, the input ends of the first self-biased three-stack amplifying network, the second self-biased three-stack amplifying network, the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network are sequentially connected with an inductor L in series_qjInductorL_pjAnd a DC blocking capacitor C_pjDc blocking capacitor C_pjIs connected with a heterojunction bipolar transistor Q_pjBase electrode of (1), inductor L_qjAnd an inductance L_pjThe connecting node is also connected with a grounding capacitor C in parallel_qjHetero-junction bipolar transistor Q_pjCollector of the heterojunction bipolar transistor Q_sjEmitter of (2), heterojunction bipolar transistor Q_sjCollector of the heterojunction bipolar transistor Q_ujEmitter of (2), heterojunction bipolar transistor Q_ujCollector electrode of (2) is connected with an inductor L_ujInductance L_ujThe other end of the capacitor is connected with a grounding capacitor C_vjAnd the output ends of the first self-biased three-stack amplifying network, the second self-biased three-stack amplifying network, the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network; heterojunction bipolar transistor Q_pjThe base electrode of the resistor is also connected with a resistor R_pjResistance R_pjIs connected with a heterojunction bipolar transistor Q_cjEmitter of (2), heterojunction bipolar transistor Q_cjCollector connecting resistance R_bj，R_bjIs connected with a heterojunction bipolar transistor Q_ujCollector of (2), heterojunction bipolar transistor Q_cjThe base electrode of the capacitor is simultaneously connected with a grounded capacitor C_ajResistance R_ajHeterojunction bipolar transistor Q_ajCollector and base of (1), heterojunction bipolar transistor Q_ajEmitter electrode of (3) is grounded, and resistor R_ajIs connected with a heterojunction bipolar transistor Q_ujA collector electrode of (a); heterojunction bipolar transistor Q_sjBase electrode connecting resistance R_sjAnd a ground capacitor C_sjResistance R_sjThe other end of the resistor is connected with a grounding resistor R_tjAnd heterojunction bipolar transistor Q_gjEmitter of (2), heterojunction bipolar transistor Q_gjCollector and base simultaneous connection resistor R_cjResistance R_cjIs connected with a heterojunction bipolar transistor Q_ujA collector electrode of (a); heterojunction bipolar transistor Q_ujBase electrode connecting resistance R_ujAnd a ground capacitor C_ujResistance R_ujThe other end of the resistor is connected with a grounding resistor R_vjAnd heterojunction bipolar transistor Q_mjEmitter of (2), heterojunction bipolar transistor Q_mjCollector and base simultaneous connection resistor R_djResistance R_djIs connected with a heterojunction bipolar transistor Q_ujWherein j is 1, 2, 3, 4. Heterojunction bipolar transistor Q_u1And heterojunction bipolar transistor Q_u2Through a capacitor C between the emitters₂Connected, heterojunction bipolar transistor Q_u3And heterojunction bipolar transistor Q_u4Through a capacitor C between the emitters₃Connecting; the first self-biased three-stack amplifying network and the second self-biased three-stack amplifying network work in a deep AB amplifying state, and the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network work in a shallow C amplifying state.

The beneficial effects of the further scheme are as follows: the utility model discloses the first three of self-bias piles up amplifier network, the second is self-bias three and piles up amplifier network, the third is self-bias three and pile up amplifier network, the fourth is self-bias three and piles up amplifier network's project organization adoption be that the heterojunction bipolar transistor amplifier's structure is piled up to the three, can show lift amplifier power capacity and power gain, improves amplifier output impedance and takes load capacity. Meanwhile, the first self-biased three-stack amplifying network is combined with the second self-biased three-stack amplifying network, and the third self-biased three-stack amplifying network is combined with the fourth self-biased three-stack amplifying network to form two pairs of differential amplifier structures, so that the deterioration of high-frequency parasitic parameters of transistors on circuit indexes can be inhibited.

Furthermore, the first and second input ends of the output differential-to-single-ended power synthesis phase-shifting network are connected with the transformer T₂The third and fourth input ends of the power synthesis phase-shifting network for converting output differential into single end are connected with a transformer T₂Non-dotted and dotted terminals of the second secondary winding, transformer T₂An inductor L is arranged between the middle taps of the first secondary coil and the second secondary coil₃Interconnection, transformer T₂The middle tap of the first secondary coil is also connected with an inductor L₂，L₂The other end of the capacitor is connected with a bypass grounding capacitor C₄Collector bias voltage V_c1Transformer T₂Primary coil's dotted terminal connection inductance L₄And is connected withGround capacitor C₅Inductance L₄The other end of the differential transformer is connected with the output end of the output differential-to-single-end power synthesis phase-shifting network, and the transformer T₂The non-dotted terminal of the primary coil of (a) is grounded.

The beneficial effects of the further scheme are as follows: the utility model discloses an output difference changes single-ended power synthesis phase shift network except can realizing four ways difference radio frequency signal's power synthesis, can also convert four ways difference signal into single-ended signal, and the insertion loss of introducing is less, has ensured simultaneously the output and the efficiency of amplifier.

Drawings

Fig. 1 is a schematic block diagram of a power amplifier of the present invention;

fig. 2 is a circuit diagram of the power amplifier of the present invention.

Detailed Description

Exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings. It is to be understood that the embodiments shown and described in the drawings are merely exemplary and are intended to illustrate the principles and spirit of the invention, not to limit the scope of the invention.

The embodiment of the utility model provides a high-efficient high linearity power amplifier towards car networking, pile up amplifier network, second from inclined to one side three and pile up amplifier network, third from inclined to one side three and pile up amplifier network, fourth from inclined to one side three and pile up amplifier network and output difference changes the synthesis of single-ended power and shift the network including the single-ended difference power distribution of input phase shift network, first from inclined to one side three.

As shown in fig. 1, the input end of the input single-ended to differential power distribution phase shift network is the input end of the whole power amplifier, the first, second, third, and fourth output ends thereof are respectively connected to the input ends of the first, third, second, and fourth self-biased three-stacked amplification networks, and the phase difference between the input end of the input single-ended to differential power distribution phase shift network and the first, second, third, and fourth output ends is 0 degree, 90 degrees, 180 degrees, and 270 degrees, respectively;

the output ends of the first, second, third and fourth self-biased three-stack amplifying networks are respectively connected with the first, third, second and fourth input ends of the output differential-to-single-ended power synthesis phase-shifting network, the output end of the output differential-to-single-ended power synthesis phase-shifting network is the output end of the whole power amplifier, and the signal phases of the output end of the output differential-to-single-ended power synthesis phase-shifting network and the first, second, third and fourth input ends are respectively different by 270 degrees, 180 degrees, 90 degrees and 0 degree.

As shown in FIG. 2, the input end of the input single-ended to differential power distribution phase-shifting network is connected with an inductor L₁Inductance L₁The other end of the transformer is connected with a coupling transformer T₁Dotted terminal of primary coil and grounding capacitor C₁Transformer T₁The non-homonymous end of the primary coil of (1) is grounded; transformer T₁The first, second and third homonymous terminals of the secondary coil are connected with the first, second and third output terminals of the input single-ended-to-differential power distribution phase-shifting network, and the transformer T₁The non-homonymous end of the stage coil is connected with the fourth output end of the input single-ended-to-differential power distribution phase-shifting network; .

The input ends of the first self-biased three-stack amplifying network, the second self-biased three-stack amplifying network, the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network are sequentially connected with an inductor L in series_qjInductor L_pjAnd a DC blocking capacitor C_pjDc blocking capacitor C_pjIs connected with a heterojunction bipolar transistor Q_pjBase electrode of (1), inductor L_qjAnd an inductance L_pjThe connecting node is also connected with a grounding capacitor C in parallel_qjHetero-junction bipolar transistor Q_pjCollector of the heterojunction bipolar transistor Q_sjEmitter of (2), heterojunction bipolar transistor Q_sjCollector of the heterojunction bipolar transistor Q_ujEmitter of (2), heterojunction bipolar transistor Q_ujCollector electrode of (2) is connected with an inductor L_ujInductance L_ujThe other end of the capacitor is connected with a grounding capacitor C_vjAnd the output ends of the first self-biased three-stack amplifying network, the second self-biased three-stack amplifying network, the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network; heterojunction bipolar transistor Q_pjThe base electrode of the resistor is also connected with a resistor R_pjResistance R_pjTo another one ofEnd-connected heterojunction bipolar transistor Q_cjEmitter of (2), heterojunction bipolar transistor Q_cjCollector connecting resistance R_bj，R_bjIs connected with a heterojunction bipolar transistor Q_ujCollector of (2), heterojunction bipolar transistor Q_cjThe base electrode of the capacitor is simultaneously connected with a grounded capacitor C_ajResistance R_ajHeterojunction bipolar transistor Q_ajCollector and base of (1), heterojunction bipolar transistor Q_ajEmitter electrode of (3) is grounded, and resistor R_ajIs connected with a heterojunction bipolar transistor Q_ujA collector electrode of (a); heterojunction bipolar transistor Q_sjBase electrode connecting resistance R_sjAnd a ground capacitor C_sjResistance R_sjThe other end of the resistor is connected with a grounding resistor R_tjAnd heterojunction bipolar transistor Q_gjEmitter of (2), heterojunction bipolar transistor Q_gjCollector and base simultaneous connection resistor R_cjResistance R_cjIs connected with a heterojunction bipolar transistor Q_ujA collector electrode of (a); heterojunction bipolar transistor Q_ujBase electrode connecting resistance R_ujAnd a ground capacitor C_ujResistance R_ujThe other end of the resistor is connected with a grounding resistor R_vjAnd heterojunction bipolar transistor Q_mjEmitter of (2), heterojunction bipolar transistor Q_mjCollector and base simultaneous connection resistor R_djResistance R_djIs connected with a heterojunction bipolar transistor Q_ujWherein j is 1, 2, 3, 4. Heterojunction bipolar transistor Q_u1And heterojunction bipolar transistor Q_u2Through a capacitor C between the emitters₂Connected, heterojunction bipolar transistor Q_u3And heterojunction bipolar transistor Q_u4Through a capacitor C between the emitters₃Connecting; the first self-biased three-stack amplification network and the second self-biased three-stack amplification network work in a deep AB amplification state, and the third self-biased three-stack amplification network and the fourth self-biased three-stack amplification network work in a shallow C amplification state.

The first and second input ends of the output differential-to-single-ended power synthesis phase-shifting network are connected with a transformer T₂The non-homonymous terminal and homonymous terminal of the first secondary coil output differenceThe third and fourth input ends of the power-dividing single-end power synthesis phase-shifting network are connected with a transformer T₂Non-dotted and dotted terminals of the second secondary winding, transformer T₂An inductor L is arranged between the middle taps of the first secondary coil and the second secondary coil₃Interconnection, transformer T₂The middle tap of the first secondary coil is also connected with an inductor L₂，L₂The other end of the capacitor is connected with a bypass grounding capacitor C₄Collector bias voltage V_c1Transformer T₂Primary coil's dotted terminal connection inductance L₄And a ground capacitor C₅Inductance L₄The other end of the differential transformer is connected with the output end of the output differential-to-single-end power synthesis phase-shifting network, and the transformer T₂The non-dotted terminal of the primary coil of (a) is grounded.

The following introduces the specific working principle and process of the present invention with reference to fig. 2:

radio frequency input signal through input terminal RF_inThe input single-end-to-differential power distribution phase-shifting network is used for impedance transformation matching, and then the input single-end-to-differential power distribution phase-shifting network simultaneously enters the input ends of the first, second, third and fourth self-biased three-stack amplifying networks in the form of differential signals with equal power.

1) When the power of the differential signal is lower than the saturated input power point of the first self-biased three-stack amplification network and the third self-biased three-stack amplification network, only the first self-biased three-stack amplification network and the third self-biased three-stack amplification network work at the moment, an output signal exists, the second self-biased three-stack amplification network and the fourth self-biased three-stack amplification network do not work, no output signal exists, the output ends of the first self-biased three-stack amplification network and the third self-biased three-stack amplification network enter an output differential-to-single-ended power synthesis phase-shifting network after outputting a radio frequency signal, the differential_outOutputting;

2) when the power of the differential signal is higher than the saturated input power point of the first self-biased three-stack amplification network and the third self-biased three-stack amplification network, the first self-biased three-stack amplification network to the fourth self-biased three-stack amplification network work, the output ends of the first self-biased three-stack amplification network to the fourth self-biased three-stack amplification network output four paths of radio frequency signals and respectively enter the output differential to single-ended power synthesis phase-shifting network, the four paths of differential signals are subjected to power synthesis and then converted into single-ended signals, and then the single-ended signals are output_outOutput of。

Based on above-mentioned circuit analysis, the utility model provides a towards high-efficient high linearity power amplifier of car networking and difference of amplifier structure based on integrated circuit technology in the past lie in that the core framework adopts from the bias three to pile up enlarged network and transformer, has realized being equivalent to the structure of Doherty power amplifier mode of operation:

the self-biased three-stack amplifying network is different from the traditional single transistor in structure, and the details are not repeated herein;

the self-biased three-stack amplifying network is different from a Cascode differential amplifier in that: the cascade base compensation capacitor of the common base tube of the Cascode transistor is a capacitor with a large capacitance value and is used for realizing alternating current grounding of the base, the base of the differential self-biased three-stack amplification network is a matching capacitor with a small capacitance value and realizes synchronous swing of base voltage, meanwhile, the Cascode amplifier is formed by connecting two tubes in series and interconnecting the self-biased three-stack amplification network is formed by connecting three tubes in series and interconnecting the self-biased three-stack amplification network, so that the circuit breakdown voltage can be remarkably improved, and the impedance matching of the transistors among stacks can be improved;

the amplifier with the Doherty structure is realized by utilizing the self-biased three-stacked amplifying network, and compared with the traditional single-ended amplifier structure, the suppression characteristic of the circuit on parasitic parameters can be obviously improved, and the index of a high-frequency circuit is improved.

In the whole radio frequency power amplifier aiming at the communication of the Internet of vehicles, the size of a transistor and the sizes of other resistors and capacitors are determined after the gain, the back-off efficiency, the output power and other indexes of the whole circuit are comprehensively considered, and through the layout design and the reasonable layout in the later period, the required indexes can be better realized, and the high-power output capacity, the high-back-off efficiency, the high-power gain and the good input-output matching characteristic are realized.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (4)

1. A high-efficiency high-linearity power amplifier oriented to the Internet of vehicles is characterized by comprising an input single-end-to-differential power distribution phase-shifting network, a first self-biased three-stacked amplifying network, a second self-biased three-stacked amplifying network, a third self-biased three-stacked amplifying network, a fourth self-biased three-stacked amplifying network and an output differential single-end-to-differential power synthesis phase-shifting network;

the input end of the input single-ended to differential power distribution phase shift network is the input end of the whole power amplifier, the first, second, third and fourth output ends of the input single-ended to differential power distribution phase shift network are respectively connected with the input ends of the first, third, second and fourth self-biased three-stacked amplifying networks, and the phase difference between the input end of the input single-ended to differential power distribution phase shift network and the signal phase difference between the input end of the input single-ended to differential power distribution phase shift network and the first, second, third and fourth output ends is 0 degree, 90 degrees, 180 degrees and 270 degrees respectively;

the output ends of the first, second, third and fourth self-biased three-stacked amplifying networks are respectively connected with the first, third, second and fourth input ends of the output differential-to-single-ended power synthesis phase-shifting network, the output end of the output differential-to-single-ended power synthesis phase-shifting network is the output end of the whole power amplifier, and the phase difference between the output end of the output differential-to-single-ended power synthesis phase-shifting network and the signal phase difference between the output end of the output differential-to-single-ended power synthesis phase-shifting network and the first, second, third and fourth input ends is 270 degrees, 180 degrees, 90 degrees and 0 degrees respectively.

2. The efficient high-linearity power amplifier oriented to the Internet of vehicles according to claim 1, wherein an inductor L is connected to an input end of the input single-ended-to-differential power distribution phase-shifting network₁Inductance L₁The other end of the transformer is connected with a coupling transformer T₁Dotted terminal of primary coil and grounding capacitor C₁Transformer T₁The non-homonymous end of the primary coil of (1) is grounded; transformer T₁The first, second and third homonymous terminals of the secondary coil are connected with the first, second and third output terminals of the input single-ended-to-differential power distribution phase-shifting network, and the transformer T₁The non-homonymous end of the stage coil is connected with the fourth output end of the input single-ended-to-differential power distribution phase-shifting network.

3. The efficient high-linearity power amplifier for the internet of vehicles according to claim 1, wherein the input ends of the first self-biased three-stack amplifying network, the second self-biased three-stack amplifying network, the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network are sequentially connected with an inductor L in series_qjInductor L_pjAnd a DC blocking capacitor C_pjDc blocking capacitor C_pjIs connected with a heterojunction bipolar transistor Q_pjBase electrode of (1), inductor L_qjAnd an inductance L_pjThe connecting node is also connected with a grounding capacitor C in parallel_qjHetero-junction bipolar transistor Q_pjCollector of the heterojunction bipolar transistor Q_sjEmitter of (2), heterojunction bipolar transistor Q_sjCollector of the heterojunction bipolar transistor Q_ujEmitter of (2), heterojunction bipolar transistor Q_ujCollector electrode of (2) is connected with an inductor L_ujInductance L_ujThe other end of the capacitor is connected with a grounding capacitor C_vjAnd the output ends of the first self-biased three-stack amplifying network, the second self-biased three-stack amplifying network, the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network; heterojunction bipolar transistor Q_pjThe base electrode of the resistor is also connected with a resistor R_pjResistance R_pjIs connected with a heterojunction bipolar transistor Q_cjEmitter of (2), heterojunction bipolar transistor Q_cjCollector connecting resistance R_bj，R_bjIs connected with a heterojunction bipolar transistor Q_ujCollector of (2), heterojunction bipolar transistor Q_cjThe base electrode of the capacitor is simultaneously connected with a grounded capacitor C_ajResistance R_ajHeterojunction bipolar transistor Q_ajCollector and base of (1), heterojunction bipolar transistor Q_ajEmitter electrode of (3) is grounded, and resistor R_ajIs connected with a heterojunction bipolar transistor Q_ujA collector electrode of (a); heterojunction bipolar transistor Q_sjBase electrode connecting resistance R_sjAnd a ground capacitor C_sjResistance R_sjThe other end of the resistor is connected with a grounding resistor R_tjAnd heterojunction bipolar transistor Q_gjEmitter of (2), heterojunction bipolar transistor Q_gjCollector and base simultaneous connection resistor R_cjResistance R_cjIs connected with a heterojunction bipolar transistor Q_ujA collector electrode of (a); heterojunction bipolar transistor Q_ujBase electrode connecting resistance R_ujAnd a ground capacitor C_ujResistance R_ujThe other end of the resistor is connected with a grounding resistor R_vjAnd heterojunction bipolar transistor Q_mjEmitter of (2), heterojunction bipolar transistor Q_mjCollector and base simultaneous connection resistor R_djResistance R_djIs connected with a heterojunction bipolar transistor Q_ujWherein j is 1, 2, 3, 4; heterojunction bipolar transistor Q_u1And heterojunction bipolar transistor Q_u2Through a capacitor C between the emitters₂Connected, heterojunction bipolar transistor Q_u3And heterojunction bipolar transistor Q_u4Through a capacitor C between the emitters₃Connecting; the first self-biased three-stack amplifying network and the second self-biased three-stack amplifying network work in a deep AB amplifying state, and the third self-biased three-stack amplifying network and the fourth self-biased three-stack amplifying network work in a shallow C amplifying state.

4. The efficient high-linearity power amplifier oriented to the internet of vehicles according to claim 1, wherein the first and second input ends of the output differential-to-single-ended power synthesis phase-shifting network are connected with a transformer T₂The third and fourth input ends of the output differential-to-single-ended power synthesis phase-shifting network are connected with a transformer T₂Non-dotted and dotted terminals of the second secondary winding, transformer T₂An inductor L is arranged between the middle taps of the first secondary coil and the second secondary coil₃Interconnection, transformer T₂The middle tap of the first secondary coil is also connected with an inductor L₂，L₂The other end of the capacitor is connected with a bypass grounding capacitor C₄Collector bias voltage V_c1Transformer T₂Primary coil's dotted terminal connection inductance L₄And a ground capacitor C₅Inductance L₄The other end of the output differential-to-single-ended power synthesis circuit is connected with the output differential-to-single-ended power synthesis circuitOutput terminal of phase-shifting network, transformer T₂The non-dotted terminal of the primary coil of (a) is grounded.

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