Masaaki Tanio scite author profile

This paper proposes an efficient neural-network-based digital predistortion (DPD), named as envelope time-delay neural network (ETDNN) DPD. The method complies with the physical characteristics of radio-frequency (RF) power amplifiers (PAs) and uses a more compact DPD model than the conventional neural-network-based DPD. Additionally, a structured pruning technique is presented and used to reduce the computational complexity. It is shown that the resulting ETDNN obtained after applying pruning becomes so sparse that its complexity is comparable to that of conventional DPDs such as memory polynomial(MP) and generalized memory polynomial (GMP), while the degradation in performance due to the pruning is negligible. In an experiment on a 3.5-GHz GaN Doherty power amplifier (PA), our method with the proposed pruning had only one-thirtieth the computational complexity of the conventional neural-network-based DPD for the same adjacent channel leakage ratio (ACLR). Moreover, compared with memory-polynomial-based digital predistortion, our method with the proposed pruning achieved a 7-dB improvement in ACLR, despite it having lower computational complexity. INDEX TERMS digital predistortion, generalized memory polynomial, memory polynomial, neural network, pruning technique Recently, a number of neural network-based DPDs have been presented [4], [5], [8], [9]. Their accurate modeling capability of neural networks enables them to outperform Volterra-based DPDs but at the expense of computational complexity.

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Reconstruction of driving forces through recurrence plots

Tanio

Hirata

Suzuki

2009

Physics Letters A

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28 GHz Downlink Multi-User MIMO Experimental Verification Using 360 Element Digital AAS for 5G Massive MIMO

Tawa

Kuwabara

Maruta

et al. 2018

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An FPGA-based all-digital transmitter with 9.6-GHz 2nd order time-interleaved delta-sigma modulation for 500-MHz bandwidth

Tanio

Hori

Tawa

et al. 2017

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An FPGA-based all-digital transmitter with 28-GHz time-interleaved delta-sigma modulation

Tanio

Hori

Tawa

et al. 2016

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Masaaki Tanio

Efficient Digital Predistortion Using Sparse Neural Network

Reconstruction of driving forces through recurrence plots

28 GHz Downlink Multi-User MIMO Experimental Verification Using 360 Element Digital AAS for 5G Massive MIMO

An FPGA-based all-digital transmitter with 9.6-GHz 2nd order time-interleaved delta-sigma modulation for 500-MHz bandwidth

An FPGA-based all-digital transmitter with 28-GHz time-interleaved delta-sigma modulation

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