Abstract
Time reversal processes have been used to improve communication performance in the severe underwater communication environment characterized by significant multipath channels by reducing inter-symbol interference and increasing signal-to-noise ratio. In general, the performance of the time reversal is strongly related to the behavior of the q -function, which is estimated by a sum of the autocorrelation of the channel impulse response for each channel in the receiver array. The q -function depends on the complexity of the communication channel, the number of channel elements and their spacing. A q -function with a high side-lobe level and a main-lobe width wider than the symbol duration creates a residual ISI (inter-symbol interference), which makes communication difficult even after time reversal is applied. In this paper, we propose a new parameter, E q , to describe the performance of time reversal communication. E q is an estimate of how much of the q -function lies within one symbol duration. The values of E q were estimated using communication data acquired at two different sites: one in which the sound speed ratio of sediment to water was less than unity and one where the ratio was higher than unity. Finally, the parameter E q was compared to the bit error rate and the output signal-to-noise ratio obtained after the time reversal operation. The results show that these parameters are strongly correlated to the parameter E q .
Highlights
Underwater acoustic communication presents a challenging problem arising from the environmental properties of underwater acoustic waveguides
Passive time reversal can be used in underwater acoustic communications that are severely affected by multipaths because it reduces the ISI and increases the signal-to-noise ratio (SNR)
The time reversal performance totally depends on the behavior of the q-function, which is the sum of the autocorrelation of the channel impulse response (CIR) for each channel
Summary
Underwater acoustic communication presents a challenging problem arising from the environmental properties of underwater acoustic waveguides. Acoustic waves propagating through shallow-water channels experience multiple interactions with the sea surface and ocean bottom This causes a significant, time-varying delay spread called ISI (inter-symbol interference) [1]. If the residual ISI is not negligible even after the time reversal process, additional equalization processes, such as an adaptive decision feedback equalizer, are needed to eliminate the residual ISI Such properties of the q-function affecting communication performance were investigated by Yang [18]. We propose a new parameter, Eq , which describes the performance of passive time reversal communication using the q-function. The parameter Eq can be used to quickly assess the symbol rate of a coherent underwater communication system using the time reversal technique, and it can be used to determine the optimal number of receiver elements required to meet the BER requirement.
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