Abstract
To enable full-duplex (FD) in underwater acoustic (UWA) systems, a high level of self-interference cancellation (SIC) is required. This can be achieved by using a combination of SIC methods, including digital SIC. 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 article, 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 to evaluate the performance of digital SIC techniques without the need of implementing a full FD system. 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 can significantly improve the SIC performance, compared to the classical RLS adaptive filters.
Highlights
In recent years, full-duplex (FD) operation of terrestrial radio systems, such as communication systems, has demonstrated an ability to increase the system throughput [1]–[5]
We consider much lower far-end signal level compared to that used for the SRLSd algorithm to generate the bit error rate (BER) curves, as the SI cancellation (SIC) performance is significantly improved with the sliding-window RLS (SRLS)-P algorithm
We will show that the SIC performance can be significantly improved by the SRLS-P adaptive filter which accurately models the channel variation caused by the time-varying surface reflection
Summary
Full-duplex (FD) operation of terrestrial radio systems, such as communication systems, has demonstrated an ability to increase the system throughput [1]–[5]. Shen et al.: Adaptive Filtering for FD UWA Systems With Time-Varying SIC the non-linear model and a large number of parameters to be estimated Another approach is to use the PA output as the reference signal for SIC [9], [13], [14]. The performance of the adaptive filter is sensitive to the delay between the regressor (PA output) and the desired (hydrophone) signal We propose and investigate the SIC factor (SICF) for measuring the cancellation performance and a new adaptive algorithm for FD UWA systems with time-varying SI channels. We denote the expectation as E{·}, the transpose of x as xT , and the Hermitian transpose of h as hH
Sign-in/Register to view highlights & summary Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
