ZTE Communications ›› 2020, Vol. 18 ›› Issue (3): 49-56.DOI: 10.12142/ZTECOM.202003008
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LIU Xin1, CHEN Wenhua1(), WANG Dehan1, NING Dongfang2
Received:
2019-12-12
Online:
2020-09-25
Published:
2020-11-03
About author:
LIU Xin received the B.S. degree in electronic information science and technology from Xidian University, China in 2017. She is currently pursuing the Ph.D. degree at Department of Electronic Engineering, Tsinghua University, China. Her current research interests include the behavioral modeling and digital predistortion for RF power amplifiers.|CHEN Wenhua (Supported by:
LIU Xin, CHEN Wenhua, WANG Dehan, NING Dongfang. Robust Digital Predistortion for LTE/5G Power Amplifiers Utilizing Negative Feedback Iteration[J]. ZTE Communications, 2020, 18(3): 49-56.
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URL: https://zte.magtechjournal.com/EN/10.12142/ZTECOM.202003008
Scenario | Without DPD | Proposed DPD | DL DPD | IDL DPD |
---|---|---|---|---|
ACPR/dBc (±100 MHz) | -33.31/-34.42 | -45.26/-45.25 | -44.06/-44.37 | -41.48/-42.41 |
Table 1 Measured performance in single band scenario
Scenario | Without DPD | Proposed DPD | DL DPD | IDL DPD |
---|---|---|---|---|
ACPR/dBc (±100 MHz) | -33.31/-34.42 | -45.26/-45.25 | -44.06/-44.37 | -41.48/-42.41 |
Scenario | Lower Band | Upper Band | ||
---|---|---|---|---|
Without DPD | Proposed DPD | Without DPD | Proposed DPD | |
ACPR/dBc (±10 MHz) | -28.28/-28.81 | -51.71/-51.45 | -30.26/-29.43 | -54.04/-53.33 |
Table 2 Measured performance in dual-band scenario
Scenario | Lower Band | Upper Band | ||
---|---|---|---|---|
Without DPD | Proposed DPD | Without DPD | Proposed DPD | |
ACPR/dBc (±10 MHz) | -28.28/-28.81 | -51.71/-51.45 | -30.26/-29.43 | -54.04/-53.33 |
1 |
DING L, ZHOU G T, MORGAN D R, et al. A robust digital baseband predistorter constructed using memory polynomials [J]. IEEE transactions on communications, 2004, 52(1): 159–165. DOI:10.1109/tcomm.2003.822188
DOI |
2 |
KIM J, KONSTANTINOU K. Digital predistortion of wideband signals based on power amplifier model with memory [J]. Electronics Letters, 2001, 37(23): 1417. DOI:10.1049/el:20010940
DOI |
3 |
ZHU A D, PEDRO J C, BRAZIL T J. Dynamic deviation reduction⁃based Volterra behavioral modeling of RF power amplifiers [J]. IEEE transactions on microwave theory and techniques, 2006, 54(12): 4323–4332. DOI:10.1109/tmtt.2006.883243
DOI |
4 |
HAMMI O, GHANNOUCHI F M, VASSILAKIS B. A compact envelope⁃memory polynomial for RF transmitters modeling with application to baseband and RF⁃digital predistortion [J]. IEEE Microwave and wireless components letters, 2008, 18(5): 359–361. DOI:10.1109/lmwc.2008.922132
DOI |
5 |
MORGAN D R, MA Z, KIM J, et al. A generalized memory polynomial model for digital predistortion of RF power amplifiers [J]. IEEE transactions on signal processing, 2006, 54(10): 3852–3860. DOI:10.1109/tsp.2006.879264
DOI |
6 |
GHANNOUCHI F M, HAMMI O. Behavioral modeling and predistortion [J]. IEEE microwave magazine, 2009, 10(7): 52–64. DOI:10.1109/mmm.2009.934516
DOI |
7 |
ZHOU D Y, DEBRUNNER V E. Novel Adaptive nonlinear predistorters based on the direct learning algorithm [J]. IEEE transactions on signal processing, 2007, 55(1): 120–133. DOI:10.1109/tsp.2006.882058
DOI |
8 |
PAASO H, MAMMELA A. Comparison of direct learning and indirect learning predistortion architectures [C]//IEEE International Symposium on Wireless Communication Systems. Reykjavik, Iceland: IEEE, 2008: 309–313. DOI:10.1109/iswcs.2008.4726067
DOI |
9 |
AMIN S, ZENTENO E, LANDIN P N, et al. Noise impact on the identification of digital predistorter parameters in the indirect learning architecture [C]//Swedish Communication Technologies Workshop. Lund, Sweden: IEEE, 2012: 36–39. DOI:10.1109/swe-ctw.2012.6376285
DOI |
10 |
DING L, MUJICA F, YANG Z G. Digital predistortion using direct learning with reduced bandwidth feedback [C]//IEEE MTT⁃S International Microwave Symposium Digest. Seattle, USA: IEEE, 2013: 1–3. DOI:10.1109/mwsym.2013.6697388
DOI |
11 |
LIU X, CHEN W H, CHEN L, et al. A robust and broadband digital predistortion utilizing negative feedback iteration [C]//IEEE MTT⁃S International Wireless Symposium (IWS). Chengdu, China: IEEE, 2018: 1–4. DOI:10.1109/ieee-iws.2018.8400950
DOI |
12 |
WU X F, SHI J H, CHEN H H. On the numerical stability of RF power amplifier’s digital predistortion [C]//15th Asia⁃Pacific Conference on Communications. Shanghai, China: IEEE, 2009: 430–433. DOI:10.1109/apcc.2009.5375601
DOI |
13 |
BASSAM S A, HELAOUI M, GHANNOUCHI F M. 2⁃D digital predistortion architecture for concurrent dual⁃band transmitters [J]. IEEE transactions on microwave theory and techniques, 2011, 59(10): 2547–2553. DOI:10.1109/tmtt.2011.2163802
DOI |
14 |
LIU Y J, CHEN W H, ZHOU J, et al. Digital predistortion for concurrent dual⁃band transmitters using 2D modified memory polynomials [J]. IEEE transactions on microwave theory and techniques, 2013, 61(1): 281–290. DOI:10.1109/tmtt.2012.2228216
DOI |
15 |
CHEN W H, BASSAM S A, LI X, et al. Design and linearization of concurrent dual⁃band doherty power amplifier with frequency⁃dependent power ranges [J]. IEEE transactions on microwave theory and techniques, 2011, 59(10): 2537–2546. DOI:10.1109/tmtt.2011.2164089
DOI |
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