Increasing the vertical resolution of conventional sub‐bottom profilers by parametric equalization

Vertical resolution, i.e. the ability to resolve two close reflectors, is a crucial aspect of pulses used in geo‐acoustic exploration of sea sub‐bottoms. This paper deals with the problem of exploring the shallowest unconsolidated layers of the seafloor with conventional piezo‐electric sonar pulses. Such transducers do not have a sufficiently broad transmission response to enable them to radiate short high‐resolution pulses. Therefore, some kind of equalization process must be applied to broaden the transmission response. Here, inverse filtering is used to calculate the transducer driving waveform so that the subsequent acoustic pulse has a zero‐phase cosine‐magnitude nature. Within a specified bandwidth, this pulse has minimum length, i.e. maximum resolution. The method has been applied to compress the acoustic pulses radiated by two piezo‐electric transducers. In conventional performance, these transducers radiate narrowband pulses which contain several cycles at the natural resonance frequency. Under equalized driving, both transducers emit broadband pulses, with resolving power greatly increased, at the cost of some amplitude loss. That is, the pulses radiated by both transducers have been shortened from 1 ms (low‐frequency transducer) and 0.274 ms (high‐frequency transducer) in conventional performance to 0.13 ms and 0.038 ms in equalized mode, with amplitude losses of 33% and 56%, respectively. The great improvement in the resolution of this technique is demonstrated by comparing the synthetic echograms that should be obtained when exploring a wedge model using zero‐phase cosine‐magnitude pulses with conventional ping pulses.