Abstract
The communication channel in underwater acoustic sensor networks (UASNs) is time-varying due to the dynamic environmental factors, such as ocean current, wind speed, and temperature profile. Generally, these phenomena occur with a certain regularity, resulting in a similar variation pattern inherited in the communication channels. Based on these observations, the energy efficiency of data transmission can be improved by controlling the modulation method, coding rate, and transmission power according to the channel dynamics. Given the limited computational capacity and energy in underwater nodes, we propose a double-scale adaptive transmission mechanism for the UASNs, where the transmission configuration will be determined by the predicted channel states adaptively. In particular, the historical channel state series will first be decomposed into large-scale and small-scale series and then be predicted by a novel k-nearest neighbor search algorithm with sliding window. Next, an energy-efficient transmission algorithm is designed to solve the problem of long-term modulation and coding optimization. In particular, a quantitative model is constructed to describe the relationship between data transmission and the buffer threshold used in this mechanism, which can then analyze the influence of buffer threshold under different channel states or data arrival rates theoretically. Finally, numerical simulations are conducted to verify the proposed schemes, and results show that they can achieve good performance in terms of channel prediction and energy consumption with moderate buffer length.
Highlights
In recent years, the development of underwater acoustic sensor networks (UASNs) has boosted a wide range of emerging applications, such as ocean observation, ecosystem monitoring, disaster warning, etc. [1,2,3]
A double-scale adaptive transmission mechanism has been proposed for UASNs with time-varying channels
The historical channel state series has been decomposed into large-scale and small-scale series, which can be predicted by a novel k-nearest neighbor search algorithm with sliding window and auto-regressive algorithm, respectively
Summary
The development of underwater acoustic sensor networks (UASNs) has boosted a wide range of emerging applications, such as ocean observation, ecosystem monitoring, disaster warning, etc. [1,2,3]. Based on the above observation, we propose to take advantage of the historical channel state series and analyze the fluctuation characteristics for channel state prediction, so that an optimized configuration scheme can be derived and the energy efficiency of data transmission would be enhanced . To improve the overall performance of underwater sensor networks, the transmission rate and energy cost should be jointly optimized based on the predicted channel states. To improve the energy efficiency and reliability of data transmission, we propose a double-scale adaptive transmission mechanism for UASNs. the historical channel state series is used for channel state prediction, and the transmission mode is determined adaptively.
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