Digital Self-Interference Cancellation for Asynchronous In-Band Full-Duplex Underwater Acoustic Communication

Qiao, Gang; Gan, Shuwei; Liu, Songzuo; Ma, Lu; Sun, Zhilin

doi:10.3390/s18061700

Cited by 46 publications

(48 citation statements)

References 24 publications

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“…To maximise the capacity of the acoustic links, we consider full-duplex (FD) communications, when a transceiver simultaneously transmits and receives data in the same frequency band [3]- [5]. The main challenge of achieving FD communication is the strong self-interference (SI) introduced by the near-end transmission [6]- [11]. Due to the high transmission power of the near-end data, we expect to deal with a high level of SI, which can be 100 dB higher than the noise floor in some communication scenarios.…”

Section: Introductionmentioning

confidence: 99%

“…This design achieves around 30 dB of digital SI cancellation with a multipath SI channel model. The recent work [11] proposes a sparse adaptive algorithm for estimation of the SI channel and PA nonlinearity, but the cancellation performance is limited. One approach to dealing with the PA nonlinearity without developing a high complexity digital SI canceller is to use the PA output as a reference signal [20].…”

Section: Introductionmentioning

confidence: 99%

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Digital Self-Interference Cancellation for Full-Duplex Underwater Acoustic Systems

Shen

Henson

Zakharov

et al. 2020

IEEE Trans. Circuits Syst. II

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Underwater acoustic (UWA) communication suffers from the limited available bandwidth for data transmission. Fullduplex (FD) communication has demonstrated the ability of achieving high spectral efficiency in terrestrial radio communications. There is a significant potential in adopting the benefits of FD in UWA systems. The major obstacle in FD communications is the severe self-interference (SI) introduced by the near-end transmitted signal. For FD UWA communications, the low signal frequency allows high-resolution ADCs to be used. With higher performance ADCs, it might be possible to achieve higher digital SI cancellation performance than that in FD radio systems. In this paper, we present experimental results of digital SI cancellation in FD UWA system, based on the use of the low-complexity recursive least-squares (RLS) adaptive filter with dichotomous coordinate descent iterations. The experimental results demonstrate that up to 46 dB of SI is cancelled when we use the transmitted digital data as the regressor in the adaptive filter. To improve the SI cancellation performance without introducing high-complexity operation, we use the digitalized power amplifier (PA) output as the regressor to deal with the non-linear distortions caused by the PA in the transmitted chain. With this technique, as high a level as 69 dB of digital SI cancellation is achieved.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Digital Self-Interference Cancellation for Full-Duplex Underwater Acoustic Systems

Shen

Henson

Zakharov

et al. 2020

IEEE Trans. Circuits Syst. II

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“…The main mathematical principle of RF cancellation in a CCFD system is the composition of vectors [31]. The following notation is utilized in developing a mathematical model for the problem of SI cancellation in the RF domain addressed in this paper: s(t) is the near-end transmitting signal, s i (t) is the same phase component as s(t), s q (t) is the orthogonal component obtained by s i (t) through a 90 degree phase shifter, r 1 (t) is the estimated SI signal, r(t) is the near-end receiving signal, and e(t) is the error signal.…”

Section: Mathematical Modelmentioning

confidence: 99%

A Novel Self-Interference Cancellation Method Using an Optimized LMS Algorithm in CCFD Systems for a 5G Communication Network

Sun

Zhao

2019

Applied Sciences

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The Co-frequency Co-time Full Duplex (CCFD) is a key concept in 5G wireless communication networks. The biggest challenge for CCFD wireless communication is the strong self-interference (SI) from near-end transceivers. Aiming at cancelling the SI of near-end transceivers in CCFD systems in the radio frequency (RF) domain, a novel time-varying Least Mean Square (LMS) adaptive filtering algorithm which is based on step-size parameters gradually decrease with time varying called the DTV-LMS algorithm is proposed in this paper. The proposed DTV-LMS algorithm in this paper establishes the non-linear relationship between step factor and the evolved arct-angent function, and using the relationship between the time parameter and error signal correlation value to coordinately control the step factor to be updated. This algorithm maintains a low computational complexity. Simultaneously, the DTV-LMS algorithm can also attain the ideal characteristics, including the interference cancellation ratio (ICR), convergence speed, and channel tracking, so that the SI signal in the RF domain of a full duplex system can be effectively cancelled. The analysis and simulation results show that the ICR in the RF domain of the proposed algorithm is higher than that in the compared algorithms and have a faster convergence speed. At the same time, the channel tracking capability has also been significantly enhanced in CCFD systems.

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“…For FD UWA systems, due to the lower frequencies of acoustic signals, high resolution ADCs are available. Thus, digital cancellation can be considered as the main practical approach for SI cancellation in FD UWA systems [8], [9].…”

Section: Introductionmentioning

confidence: 99%

“…A general approach to deal with the PA non-linearity is to estimate the non-linear distortion, e.g. using the Hammerstein model and its extensions, and then compensate it in the received signal [5], [8], [11]. To accurately model the non-linearity, high order basis functions are required.…”

Section: Introductionmentioning

confidence: 99%

Adaptive Filtering for Full-Duplex UWA Systems with Time-Varying Self-Interference Channel

Shen¹,

Zakharov²,

Henson³

et al. 2020

Preprint

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<div>Abstract:</div><div><br></div><div>To enable full-duplex (FD) in underwater acoustic (UWA) systems, a high level of self-interference (SI) cancellation (SIC) is required. For digital SIC, adaptive filters are used. In time-invariant channels, the SI can be effectively cancelled by classical recursive least-square (RLS) adaptive filters, such as the sliding-window RLS (SRLS) or exponential-window RLS, but their SIC performance degrades in time-varying channels, e.g., in channels with a moving sea surface. Their performance can be improved by delaying the filter inputs. This delay, however, makes the mean squared error (MSE) unsuitable for measuring the SIC performance. In this paper, we propose a new evaluation metric, the SIC factor (SICF), which gives better indication of the SIC performance compared to MSE. The SICF can be used in experiments and in real FD systems. A new SRLS adaptive filter based on parabolic approximation of the channel variation in time, named SRLS-P, is also proposed. The SIC performance of the SRLS-P adaptive filter and classical RLS algorithms (with and without the delay) is evaluated by simulation and in lake experiments. The results show that the SRLS-P adaptive filter significantly improves the SIC performance, compared to the classical RLS adaptive filters.</div>

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Digital Self-Interference Cancellation for Asynchronous In-Band Full-Duplex Underwater Acoustic Communication

Cited by 46 publications

References 24 publications

Digital Self-Interference Cancellation for Full-Duplex Underwater Acoustic Systems

Digital Self-Interference Cancellation for Full-Duplex Underwater Acoustic Systems

A Novel Self-Interference Cancellation Method Using an Optimized LMS Algorithm in CCFD Systems for a 5G Communication Network

Adaptive Filtering for Full-Duplex UWA Systems with Time-Varying Self-Interference Channel

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