CN215452892U - Broadband efficient GaN internal matching power tube - Google Patents
Broadband efficient GaN internal matching power tube Download PDFInfo
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- CN215452892U CN215452892U CN202120112907.2U CN202120112907U CN215452892U CN 215452892 U CN215452892 U CN 215452892U CN 202120112907 U CN202120112907 U CN 202120112907U CN 215452892 U CN215452892 U CN 215452892U
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Abstract
The utility model relates to a novel broadband high-efficiency GaN internal matching power tube, wherein the input and the output of the novel broadband high-efficiency GaN internal matching power tube both adopt a band-pass matching network in a multi-stage impedance transformation form, and matching elements are manufactured on a ceramic substrate; a parallel resonant network is formed by connecting an inductor, a capacitor and a resistor series circuit to the ground in parallel at a position close to the grid end of the tube core of the GaN HEMT and a Cgs series resistor Rin of the GaN HEMT. The network forms parallel resonance in a fundamental wave frequency band through optimization, so that the input impedance can realize efficiency matching in a wider frequency band; meanwhile, the network introduces certain loss, reduces low-frequency gain, effectively improves the stability of the amplifier, improves standing waves and expands the bandwidth. The series resistor Rin is introduced, so that the input impedance can be improved, and the improvement of the impedance is beneficial to realizing broadband impedance matching on the high-power GaN HEMT device. The utility model effectively reduces the difficulty of realizing the broadband matching of the GaN HEMT device, and leads the use of the broadband high-efficiency GaN power tube to be wider.
Description
Technical Field
The utility model discloses a broadband high-efficiency GaN internal matching power tube, and belongs to the technical field of microwave power amplifiers.
Background
With the increasing requirements of the wireless systems such as radar and communication on the multifunction, fast response, anti-interference, high reliability and mobility of the front-end module, the miniaturized, high-efficiency and broadband microwave power amplifier becomes the current research trend. Neither the first generation semiconductors represented by Ge, Si, nor the second generation semiconductors represented by GaAs have been able to fully satisfy the requirements of the system for power amplifiers. The third generation semiconductor material represented by GaN has the characteristics of high forbidden bandwidth, high electron mobility, high electron saturation rate, high breakdown voltage, high thermal conductivity, good chemical stability, strong radiation resistance and the like. The high electron mobility transistor (GaN HEMT) power device has the advantages of high operating frequency, high power density, high breakdown voltage, high efficiency and the like, and gradually becomes an ideal device for the application of the microwave power device and the microwave monolithic integrated circuit at present.
The international semiconductor technology roadmap (ITRS-2009) released in 2009 is further to clarify that GaN HEMTs will replace GaAs in power application fields below the Ka band between 2013 and 2017. Currently, many companies such as Cree, Qorvo, and Macom in the united states and Fujitsu in japan have GaN HEMT power tube products, and the products focus on base station application in the L, S band and also extend to the Ku band and other bands below the Ku band. At present, except that companies such as Macom and the like focus on developing a GaN HEMT technology based on a Si substrate, other companies adopt a semi-insulating SiC substrate. Compared with Si and GaAs microwave power devices, the GaN HEMT has very obvious performance advantages. Typical top level of products such as CREE in the United states reaches 1000W in the L band, 500W in the S band, 200-300W in the C, X band, and the main maximum working voltage is 50-65V. According to laboratory-level high-voltage products reported by Integra corporation, a single tube working in a P wave band can realize 1.1KW output under 145V working voltage.
In recent years, wireless systems have higher integration and more complex functions, but the power consumption and the volume of the systems are reduced, which puts new demands on efficient miniaturization of components. The microwave power amplifier is an important component of a system transmitting channel, the power consumption of the microwave power amplifier usually occupies most of the power consumption of components, and the high-efficiency output of a single power device can effectively reduce the total power consumption of the system; the power amplifier volume, especially the final power amplifier volume usually occupies a larger volume, and the power amplifier circuit area is effectively reduced by adopting a ceramic substrate with high dielectric constant in the form of internal matching power amplifier, so that the system volume can be reduced.
Disclosure of Invention
The utility model provides a broadband high-efficiency GaN inner matching power tube, aiming at overcoming the defects of the prior art and providing a novel broadband high-efficiency GaN inner matching power tube which can realize the high-efficiency output of a single power device in a wider working frequency, effectively reduces the size of an amplifier by using an inner matching power device and meets the requirement of a microwave system on realizing the miniaturization of the system.
The technical solution of the utility model is as follows: the utility model provides a novel broadband high-power GaN internal matching power tube, which is synthesized by a twin-cell GaN HEMT tube core to realize output, wherein the larger the grid width of the tube core is, the lower the input and output impedance of a GaN HEMT device is, and the more difficult the impedance matching is. The input and output matching network in the utility model adopts distributed element matching, and the matching element is manufactured on an alumina ceramic substrate; the input matching network adopts a resonant network matching mode, and an inductor L is adopted near the grid end of the GaN HEMT tube core1Resistance R1C with GaN HEMTgsCapacitor, series resistor RinForming a parallel resonant network by optimizing L1、R1、RinValue of (2) to achieve parallel tuning in the fundamental frequency bandAnd the input impedance approaches to the optimal efficiency point in a wider frequency band, the stability of the device is improved, the input impedance of the GaN HEMT is improved, the impedance improvement is beneficial to realizing broadband impedance matching of the large-grid-width GaN HEMT device, and a microwave power device with higher performance is realized.
The input matching network comprises a grid feed part and adopts a distributed parameter circuit for matching, including L1Parallel inductance, Lin1First stage inductance, Lin2Second-stage inductor, Rin series resistor and CinCapacitance, R1Resistance and C1Capacitor, composition Rin-L1-Lin1-Cin-Lin2T-type matching network, L1The other end of the parallel inductor is connected with R in series1Resistance and C1Capacitance, C1The capacitor is grounded; wherein L is1Parallel inductance, Lin1First stage inductance, Lin2The second stage inductor is made of low-dielectric-constant ceramic with dielectric constant less than 20, CinThe capacitor is made of high dielectric constant ceramics with dielectric constant more than 70.
The output matching network comprises a leakage feed part, and is matched by adopting a distributed parameter circuit, including L2Parallel inductance, Lout1First stage inductance, Lout2Second stage inductance, CoutCapacitor, C2Capacitor, composition L2-Lout1-Cout-Lout2T-type matching network, L2The other end of the parallel inductor is connected in series with C2Capacitance, C2The capacitor is grounded; wherein L is2Parallel inductance, Lout1First stage inductance, Lout2The second stage inductor is made of low-dielectric-constant ceramic with dielectric constant less than 20, CoutThe capacitor is made of high dielectric constant ceramics with dielectric constant more than 70.
The low dielectric constant ceramic is alumina ceramic.
The matching networks are all microstrip structures and are distributed elements.
Said L1The parallel inductor is equivalent by microstrip line, and the gate end passes through L1The shunt inductor feeds power; r of gate terminal1Resistance, RinThe resistor is a lumped resistor; leakage terminal L2The parallel inductor is equivalent by microstrip line, and the drain terminal passes through L2And the parallel inductor feeds power.
The input matching network, the GaN HEMT tube core and the output matching network are manufactured on the SiC substrate.
Said C is1Capacitor, C2The capacitor is a decoupling capacitor of a leakage bias circuit, prevents direct current from supplying power to the ground, and adopts a lumped element MIM capacitor; r1Resistance, RinThe resistor is a thin film resistor.
The utility model has the beneficial effects that:
the input and output matching networks are matched by adopting distributed elements, the matching elements are manufactured on the alumina ceramic substrate, the matching networks all adopt a parallel resonance matching mode, a parallel resonance network is formed near the grid end of the tube core of the GaN HEMT through an inductor L1, a resistor R1, the Cgs capacitor of the GaN HEMT and a series resistor Rin, and a parallel resonance network is formed near the drain end of the tube core of the GaN HEMT through a microstrip inductor L2 and the Cds capacitor of the GaN HEMT. The internal matching network is adopted to directly match the GaN HEMT device to the output near 50 ohms, the area of the radio frequency amplifier is greatly reduced, and the use is more convenient.
Therefore, the grid end and the drain end of the novel broadband high-efficiency GaN power tube are matched by adopting the distributed resonant network, and the broadband high-efficiency output of a single power device can be realized. The broadband high-efficiency GaN internal matching power tube can effectively reduce the system size and the system power consumption on the premise that the system requires the same output power, and the requirement of system miniaturization and low power consumption is met.
Drawings
FIG. 1 is a schematic diagram of the internal structure of a novel broadband high-efficiency GaN internal matching power tube according to the utility model;
FIG. 2 is an enlarged structural view of the inside of a novel broadband high-efficiency GaN internal matching power tube of the utility model;
FIG. 3 is a schematic diagram of a novel broadband high-efficiency GaN internal matching power tube circuit of the present invention;
fig. 4 shows the output characteristic test result of the novel broadband efficient internal matching power tube of the present invention.
In the figure, L is inductance, R is resistance, and C is capacitance.
Detailed Description
A novel broadband high-efficiency GaN internal matching power tube realizes high-efficiency output of a single power device in the working frequency of a wide range, the size of an amplifier is effectively reduced by the internal matching power device, and the requirement of a microwave system for realizing system miniaturization is met. Firstly, in order to achieve high-efficiency broadband output, the GaN HEMT device with the advantages of high breakdown electric field, high thermal conductivity and the like is selected, the power device can work under the condition of higher voltage (more than or equal to 28V), and the power device has higher power density, higher heat dissipation capacity and higher drain impedance, and provides guarantee for realizing high-efficiency broadband output.
Secondly, a novel matching network is selected, so that the power tube can realize broadband matching. The input inner matching network adopts distributed element matching, the matching element is manufactured on the ceramic substrate, the broadband resonant network is introduced, and the distributed inductance L is arranged near the grid end of the GaN HEMT tube core1Resistance R1C with GaN HEMTgsCapacitor, series resistor RinForming a parallel resonant network by optimizing L1、R1、RinThe value of (3) enables parallel resonance to be formed in a fundamental wave frequency band, input matching is enabled to be close to efficiency matching in a wider frequency band, meanwhile, the stability of the device is improved, the input impedance of the GaN HEMT is improved, and the impedance improvement is beneficial to realizing broadband impedance matching on the GaN HEMT device with large grid width; the output matching network also adopts a similar matching form and distributes an inductor L near the drain end of the GaN HEMT tube core2C with GaN HEMTdsThe capacitors form a parallel resonant network by optimizing L2The value of (3) enables parallel resonance to be formed in the fundamental wave frequency band, improves the output impedance of the GaN HEMT and is convenient for realizing broadband matching. Here C1、C2Decoupling the capacitor for the leakage bias circuit prevents dc supply to ground.
In addition, the input matching circuit adopts a multi-stage impedance transformation structure to realize broadband matching, and the input impedance matching network adopts Rin-Lin1-Cin-Lin2A T-shaped matching network is arranged in the T-shaped matching network,the matching network has a low Q value in the Smith chart, and effectively expands the matching bandwidth. Input matching network inductance Lin1、Lin2Using alumina ceramic equivalent, capacitor C of relatively low dielectric constantinThe ceramic equivalent with relatively high dielectric constant is adopted, so that the size of the matching circuit can be effectively reduced, and the miniaturization is convenient to realize.
The technical scheme of the utility model is further explained by combining the attached drawings
The utility model relates to a novel broadband high-efficiency GaN internal matching power tube, the internal structure diagram of which is shown in figure 1, and figure 2 is a structure diagram for amplifying the vicinity of a tube core of the GaN internal matching power tube. The input matching network adopts a distributed resonant matching network for matching, the matching element is manufactured on an alumina ceramic substrate, and the distributed inductance L is arranged near the grid end of the tube core of the two-cell GaN HEMT1Resistance R1C with GaN HEMTgsCapacitor, input resistor RinForming a resonant network by optimizing L1、R1、RinThe value of (3) enables parallel resonance to be formed in the fundamental wave frequency band, so that the circuit bandwidth can be improved, the input standing wave is improved, the circuit stability is improved, the grid end output impedance of the GaN HEMT is improved, and the impedance improvement is beneficial to realizing broadband impedance matching of the GaN HEMT device with large grid width. Similarly, the output matching network also adopts a distributed resonant matching network for matching, and the leakage end of the tube core of the two-cell GaN HEMT is close to the leakage end of the tube core of the two-cell GaN HEMT through a distributed inductor L2C with GaN HEMTdsThe capacitors form a parallel resonant network by optimizing L2The value of (3) enables parallel resonance to be formed in the fundamental wave frequency band, and the output impedance of the GaN HEMT drain terminal is improved. Fig. 3 is an electrical schematic diagram of an inner matching power tube.
In order to realize broadband high-power output, a twin-cell GaN HEMT tube core is adopted in the example, the grid width of each cell of GaN tube core is 50mm, and the output power density of the chip reaches 6W/mm under the 50V drain electrode working voltage. Therefore, the output impedance of the GaN HEMT tube core is very small, only a few tenths of ohms, the difficulty of directly matching to 50 ohms is very large, and the circuit is extremely unstable, so that the distributed inductance L is distributed near the grid ends of the two-cell GaN HEMT tube core1Resistance R1And of GaN HEMTCgsCapacitor, series resistor RinA resonant network is formed, the circuit bandwidth is effectively improved, the circuit stability is improved, the circuit standing wave is improved, the grid end impedance of the GaN HEMT is improved, and the low impedance can be matched to the high impedance.
As shown in FIG. 4, which is a graph of the output power and the added efficiency characteristic of the device of the present invention under the condition that the drain voltage VD is equal to 50V, it can be seen from the graph that the output power is greater than 600W (58 dBm) and the added efficiency is greater than 60% in the frequency band range of 1.0GHz to 1.5 GHz.
In conclusion, the novel broadband high-efficiency GaN internal matching power tube is designed, the input network and the output network of the novel broadband high-efficiency GaN internal matching power tube are matched by adopting distributed elements, the matching elements are manufactured on the alumina ceramic substrate, the input matching network adopts a novel resonant network, the grid end improves the output impedance of the grid end by introducing the LRC resonant network, meanwhile, the stability of the tube core is further improved, the bandwidth is expanded, and the stable output in the broadband of a single power device is realized.
The above description is only of the preferred embodiments of the present invention, and it should be noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the utility model and these are intended to be within the scope of the utility model.
Example 1
Wherein L is1Using distributed parameter inductor with single-side inductance of about 0.465nH and single-side resistor R1Resistance value of 0.75 omega, C1The capacitor is a ceramic capacitor with the capacitance value of 1000pF and has a decoupling function. CgsFor the gate-source capacitance of the tube core, the capacitance value corresponding to the impedance at the optimal efficiency is about 1.2pF/mm, and the capacitance value of the single tube core is 66 pF. The calculation of the corresponding resonant frequency can be simplified as shown in formula 1:
The resonant frequency is 1.28 GHz.
The quality factor is calculated as shown in formula 2:
Its quality factor is 5, which corresponds to a relative bandwidth of about 1/Q, i.e. 20%. A reduction in the quality factor may effectively increase the bandwidth, but a too low quality factor may reduce the gain, depending on the bandwidth.
Claims (9)
1. A broadband high-efficiency GaN internal matching power tube is characterized by comprising an input matching network, a GaN HEMT tube core and an output matching network, wherein the GaN HEMT tube core is provided with two cells, the two GaN HEMT tube cores are arranged in parallel, the input matching network and the output matching network adopt a resonant network matching mode and adopt distributed element matching, the grid end or the drain end of each GaN HEMT tube core is bypassed by distributed inductors and resistors, and the inductors and the resistors as well as capacitors and resistors in the GaN HEMT tube core form a parallel resonance network, so that parallel resonance is formed in a fundamental wave frequency band, input impedance is close to the optimal efficiency point in a broadband, and meanwhile, the input impedance of the GaN HEMT is improved.
2. The wideband high efficiency GaN internal matching power transistor as claimed in claim 1, wherein the input matching network includes a gate feed portion, and is matched using a distributed parameter circuit, including L1Parallel inductance, Lin1First stage inductance, Lin2Second-stage inductor, Rin series resistor and CinCapacitance, R1Resistance and C1Capacitor, composition Rin-L1-Lin1-Cin-Lin2T-type matching network, L1The other end of the parallel inductor is connected with R in series1Resistance and C1Capacitance, C1The capacitor is grounded; wherein L is1Parallel inductance, Lin1First stage inductance, Lin2The second stage inductor is made of low-dielectric-constant ceramic with dielectric constant less than 20, CinThe capacitor has a high dielectric constant greater than 70And (5) manufacturing ceramic.
3. The power transistor as claimed in claim 1, wherein the output matching network includes a leaky feeder part, and is matched by a distributed parameter circuit including L2Parallel inductance, Lout1First stage inductance, Lout2Second stage inductance, CoutCapacitor, C2Capacitor, composition L2-Lout1-Cout-Lout2T-type matching network, L2The other end of the parallel inductor is connected in series with C2Capacitance, C2The capacitor is grounded; wherein L is2Parallel inductance, Lout1First stage inductance, Lout2The second stage inductor is made of low-dielectric-constant ceramic with dielectric constant less than 20, CoutThe capacitor is made of high dielectric constant ceramics with dielectric constant more than 70.
4. The wide-band high-efficiency GaN inner-matched power tube as claimed in claim 2 or 3, wherein the low-dielectric-constant ceramic is an alumina ceramic.
5. The GaN inner matching power tube with high efficiency and wide band as claimed in claim 2 or 3, wherein the matching networks are distributed elements with microstrip structures.
6. The GaN internal matching power transistor of claim 2 or 3, wherein L is1The parallel inductor is equivalent by microstrip line, and the gate end passes through L1The shunt inductor feeds power; r of gate terminal1Resistance, RinThe resistor is a lumped resistor; leakage terminal L2The parallel inductor is equivalent by microstrip line, and the drain terminal passes through L2And the parallel inductor feeds power.
7. The wide-band high-efficiency GaN inner matching power tube as claimed in claim 1, wherein the input matching network, the GaN HEMT tube core and the output matching network are fabricated on a SiC substrate.
8. The GaN internal matching power transistor of claim 2 or 3, wherein C is1Capacitor, C2The capacitor is a decoupling capacitor of a leakage bias circuit, prevents direct current from supplying power to the ground, and adopts a lumped element MIM capacitor; r1Resistance, RinThe resistor is a thin film resistor.
9. The GaN internal matching power transistor of claim 2 or 3, wherein L is1The parallel inductor uses distributed parameter inductor, and its single-side inductance value is about 0.465nH, R1Resistance of the resistor is 0.75 omega, C1The capacitor is a ceramic capacitor, has a capacitance value of 1000pF and has a decoupling function; cgsFor the gate-source capacitance of the tube core, the capacitance value corresponding to the impedance at the optimal efficiency is about 1.2pF/mm, and the capacitance value of the single tube core is 66 pF.
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CN110729281A (en) * | 2019-11-11 | 2020-01-24 | 中国电子科技集团公司第五十五研究所 | Broadband high-power GaN pre-matching power tube |
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CN110729281A (en) * | 2019-11-11 | 2020-01-24 | 中国电子科技集团公司第五十五研究所 | Broadband high-power GaN pre-matching power tube |
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