EECS-730 High-Power Inverted Doherty Power Amplifier for Broadband Application Jehyeon Gu* Mincheol Seo Hwiseob Lee Jinhee Kwon Junghyun Ham Hyungchul Kim and Youngoo Yang Sungkyunkwan University 300 Cheoncheon-dong Suwon Gyeonggi-do 440-476 Korea yang09@skku.edu Abstract This paper presents a high-power inverted Doherty power amplifier for broader operational bandwidth. After analyzing two operation modes according to the load modulation of the Doherty power amplifier the inverted Doherty structure was selected. In the design the load impedances for optimum broadband characteristics at both the back-off and peak power levels. The Doherty power amplifier was designed to have simultaneously optimized back-off efficiency and load impedances at peak power level. The designed inverted Doherty power amplifier based on LDMOSFET s shows high efficiency of more than 40 % at the point backed-off by 6 db from the 1 db compression point of 50 dbm and at the band from 2.04 to 2.24 GHz. Keyword: Doherty power amplifier inverted Doherty power amplifier broadband Doherty power amplifier high-power amplifier. 1. Introduction Modern wireless communication systems such as WiMAX W-CDMA and LTE have modulated signals that have high peak-to-average power ratio (PAPR). Therefore power amplifiers (PA) operate at backed-off region from the peak power in order to comply with the arity specifications which causes efficiency degradation. The Doherty power amplifiers (DPA s) takes advantage in back-off efficiency of load modulation using a quarter-wave [1]. The DPA s have been widely used due to their simple circuits and superior performances. However DPA s have limited bandwidth for high-efficiency operation mainly because of the load impedance modulation using the quarter-wave. Various studies have been carried out to broaden the bandwidth of DPA s. In [2] the matching s follow optimum impedances at each frequency point by using a realfrequency technique. In [3] based on an analysis for the load modulation new-type of the output combiner was proposed for broadband characteristics. The ratio of impedance transformation reduced to 1:2.85 from 1:4 so that the frequency effect on the impedance transformation can also be reduced in [4]. After resonating the parasitic capacitance in the device out the matching can be designed only using a resistive load in [5]. In [6] the optimum impedance at back-off according the frequency become less sensitive using a newly shaped output combiner. However high-power broadband DPA s are very difficult to design because of low load impedance of the transistor. In this paper we designed high-power broadband inverted Doherty power amplifier (IDPA) with an output power of more than 100 W. Optimum load impedances over the frequency band were extracted. The optimum reference impedance was found for the various load conditions. The IDPA was designed with considering the optimum load impedances at the 20
both back-off power and peak power. No quarter-wave in the carrier PA due to the IDPA structure the output combiner becomes more insensitive over frequency. The design procedure and simulation results of the IDPA using high-power LDMOSFET s will be presented. 2. Broadband IDPA For the conventional Doherty power amplifiers (CDPA s) there is a quarter-wave transformer whose characteristic impedance of R 0 at the carrier PA to transform R 0 to R /2. 0 Generally between the load and the junction that combines current from the carrier and peaking PA s there is another quarter-wave. Two quarter-wave s limit the bandwidth of the CDPA. Especially at back-off power level triple impedance transformation happens due to the two quarter-wave s and the load matching of the carrier PA. This can cause significant performance degradation at back-off power level according to the frequency variation. For broadband characteristics it is required to reduce the performance degradation at back-off power level. R a c R a R 90 T R 0 Offset 2R 90 a Peaking PA 2R a p Fig. 1: Output combining circuit of the IDPA. Figure 1 presents the output combining circuit of the IDPA. For the IDPA structure there is no quarter-wave after the carrier PA for load modulation. At back-off power level when the peaking PA is off impedance transformation occurs only twice due to the quarter-wave of R T and the load matching of the carrier PA. Thus output combiner of the IDPA shows less sensitive characteristics over frequency variation compared to the CDPA. Z opt L R R 90 T 50 Peaking off Peaking PA 21
Z opt H Maching R R 90 T RLH 90 50 Peaking on Maching Z opt H Fig. 2: Two operation modes of the IDPA: back-off power level peak power level. Figure 2 shows schematic diagrams of the IDPA load s for two operation modes. Z L and Z H are optimum impedances at back-off and peak power levels respectively. For the back-off power level as shown in Figure 2 peaking PA is off and the load impedance after a quarter-wave of R T is R. The carrier and peaking PA s drive the same current at the peak power level as the peaking PA is full turned on as shown in Figure 2. Therefore the carrier and peaking PA s see the same impedance of R LH (= 2R ) at the peak power level. Back-off power Peak power Z opt L Z opt H R R 2R LH Z1 1 Offset ( RLL ) Z2 2 Fig. 3: of the carrier PA. For broadband operation it is important for the transistors to have load impedance near the optimum for the overall operating frequency band. Figure 3 shows the matching and impedances of the carrier PA. Since the carrier PA operates with two modes it required to have two different optimum load conditions of Z L and Z H for the back-off and peak power levels respectively. In addition R which is selected by the characteristic impedance of the quarter-wave after the combining junction affects the bandwidth of the matching as well. For good and broad back-off performance the matching is optimized for Z L. At the peak power level the load impedance is transformed from 2R to around Z H by the matching and offset which has a characteristic impedance of R. 22
2 5 2 5-2j Z L 15 ohm 25 ohm 35 ohm 45 ohm -2j Z H 30 ohm 50 ohm 70 ohm 90 ohm Fig. 4: Optimum impedances and load impedances of the matching for various R at the band from 2.04 to 2.24 GHz: at the back-off power level at the peak power level. Figure 4 represents the optimum impedances and simulated load impedances of the matching for various R : at the back-off power level and at the peak power level. The optimum impedances were extracted using load-pull simulation over the frequency band of 2.04 to 2.24 GHz with a step of 50 MHz. When RLL 25 the simulated load impedances are closest to the optimum impedances. Peak power Z opt H Output RLH 90 Back-off power 1.0j short Open 0.5j 2.0j 0.2j 5.0j 0.2 0.5 1.0 2.0 5.0-0.2j -5.0j -0.5j -2.0j -1.0j Fig. 5: Peaking PA design: schematic and impedances output reflection coefficient after the matching and offset at the band from 2.04 to 2.24 GHz. 23
Figure 5 shows the schematic and impedances of the peaking PA. It has a quarter-wave after the matching and offset. The output reflection coefficient after the matching and a proper matching is near to the short point on the Smith chart as shown in Figure 5. Therefore it requires a quarter-wave to transform the output reflection coefficient to the open point so that the IDPA configuration is accomplished. V gg c V dd Input Wilkinson Divider Atten. Delay compensation Input Output MRF6P21190H Offset 35.35 90 50 90 50 Input Output V gg p Fig. 6: Schematic diagram of the designed broadband IDPA. V dd Figure 6 is a schematic diagram of the designed broadband IDPA. The circuit was designed using Agilent s Advanced Design System (ADS). Freescale s 190-Watt push-pull LDMOSFET (MRF6P21190H) was used. For the gain balance between the carrier PA and peaking PA an 1dB attenuator is employed at the input of the carrier PA. A delay compensation is inserted in the input stage of the carrier PA. 3. Results 24
Fig. 7: Simulated gin and PAE of the designed IDPA using a 1-tone input with a frequency of 2.14 GHz. Fig. 8: Simulated results over the frequency band from 2.04 to 2.24 GHz: gain and P1dB PAEs at the peak and 6dB back-off points. Figure 7 shows simulation results for the designed IDPA using a 1-tone signal with a frequency of 1 GHz. The IDPA has a P1dB of 52.77 dbm and a PAE of 51.53% at the 6dB back-off point from P1dB. Figure 8 presents simulated gains and P1dB s of the CDPA and the IDPA over the frequency band from 2.04 to 2.24 GHz. Figure 8 shows the PAEs at the peak power and 6dB back-off power levels at the operating frequency band. The designed IDPA has P1dB of more than 50 dbm and back-off PAE of more than 40%. The designed IDPA clearly has broader bandwidth and better performances than that of the CDPA. Table 1 summarizes the performances of the previously published works regarding broadband DPA. 25
Table 1: Comparison to the previous results for the broadband DPA Ref. Output power 5-6 db back-off efficiency Freq. range Device (dbm) (GHz) [2] 41 40 %* 2.2 2.96 GaN [3] 49 50 %* 0.7 1 GaN [4] 42 41 %** 1.7 2.6 GaN [5] 42 40 %* 1.7 2.1 LDMOS [6] 42 48 %* 1.95 2.25 GaN [8] 37 31 %** 1.5 2.14 GaN This work 50 40 %** 2.04 2.24 LDMOS * Drain efficiency ** Power added efficiency 4. Conclusions In this paper based on the analysis for the two operating modes of DPA a broadband IDPA is proposed. The IDPA structure allows the output combiner to be less sensitive to the frequency changes because there is no quarter-wave after the carrier PA. The optimum load impedances were extracted using a load-pull simulation for both the back-off and peak power levels over the operating frequency band. The matching was designed to simultaneously provide load impedances close to the optimum impedances at the back-off and peak power levels. The IDPA was designed using a 190-Watt push-pull LDMOSFET. At the 200MHz band from 2.04 to 2.24 GHz it has P1dB of more than 50 dbm and efficiency at 6 db back-off of more than 40%. 5. References [1] W. H. Doherty A new high efficiency power amplifier for modulated waves in Proc. IRE vol. 24 pp. 1163 1182 Sep. 1936. [2] G. Sun and R. Jansen Broadband Doherty power amplifier via real frequency technique IEEE Trans. Microw. Theory Tech. vol. 60 no. 1 pp. 99 111 Jan. 2012. [3] D. Y.-T. Wu and S. Boumaiza A modified Doherty configuration for broadband amplification using symmetrical devices IEEE Trans. Microw. Theory Techn. vol. 60 no. 10 pp. 3201 3213 Oct. 2012. [4] K. Bathich A. Z. Markos and G. Boeck Frequency response analysis and bandwidth extension of the Doherty amplifier IEEE Trans. Microw. Theory Tech. vol. 59 no. 4 pp. 934 944 Apr. 2011. [5] J. Qureshi N. Li W. Neo F. van Rijs I. Blednov and L. de Vreede A wideband 20W LMOS Doherty power amplifier in IEEE MTT-S Int. Microw. Symp. Dig. pp. 1504 1507 May 2010. [6] R. Giofré P. Colantonio F. Giannini and L. Piazzon New output combiner for Doherty amplifiers IEEE Microw. Wireless Compon. Lett. vol. 23 no. 1 pp. 31 33 Jan. 2013. [7] S. Kwon M. Kim S. Jung J. Jeong K. Lim J. Van H. Cho H. Kim W. Nah and Y. Yang Inverted-load for high-power Doherty amplifier IEEE Microwave Mag pp. 93 98 Feb. 2009. [8] K. Bathich A. Z. Markos and G. Boeck A wideband GaN Doherty amplifier with 35% fractional bandwidth in Proc. 40th Eur. Microw. Conf. Paris France pp. 1006 1009 Sep. 2010. 26