The Tritech AquaTrak™ CVL provides greater precision and accuracy than a 1200kHz with the range exceeding a 300kHz DVL.
Underwater navigation is essential for a diverse range of Unmanned Underwater Vehicle (UUV) military and commercial applications. Although GPS and other radio signals have been widely used for surface vessel navigation, these technologies are ineffective for underwater navigation because electromagnetic signals are blocked by seawater. Inertial sensing is a suitable and widely used technology for underwater navigation. However, position error tends to drift in the absence of input from aiding sensors. The most successful combination for underwater navigation has therefore been to combine inertial technology with velocity measurement using acoustic sensors that measure speed from echoes reflected off the seafloor.
The Doppler Velocity Log (DVL) has traditionally been the standard choice for integration into UUV navigation systems. Until now Correlation Velocity Logs (CVL) have not affected this domination of the marketplace because of the high level of signal processing required for correlating pairs of signals in CVLs. However, recent advances in low power electronics and advanced
acoustic correlation signal processing techniques now enable CVLs to offer a superior price and performance value proposition over existing DVLs.
CVLs offer many advantages over DVLs, since they can achieve high accuracy at low velocities even during hover manoeuvres. DVLs use narrow beam widths, while CVL transmitters have wid
e beam widths. This gives CVLs the potential to use lower frequencies thus permitting operation in deeper water; increased accuracy; reduced power requirements for the same depth and smaller form factors.
CVL typical vertical beam DVL typical tilted beam
Tritech AquaTrak™ Correlation Velocity Log provides both long range navigation and high resolution accuracy. The highly flexible and modular design allows the unit to be used in a standalone configuration or as part of an Integrated Navigation System.
A CVL measures a two-dimensional displacement vector between two receiver channels for successive pulses, so that the corresponding velocity measurement is generated by the
displacement divided by the time interval between pulses, with no need for a speed of sound measurement.
AquaTrak’s piezocomposite transducers operate at 150 kHz enabling altitudes of 300m above the seabed. This operating frequency was selected as an ideal compromise between a deeper propagation of the acoustic pulses (due to the reduction in attenuation with decreasing frequency) while avoiding background noise at lower frequencies. The acoustic power requirements have also been minimized for UUV integration and operation — particularly for autonomous underwater vehicles.
To ensure that the incoming signals used within the correlation calculation result from bottom reflection rather than volume reverberation or background noise, AquaTrak uses advanced Synthetic Aperture Sonar acoustic correlation signal processing techniques. It first determines the height of the instrument above the seabed and uses time of flight calculations to neglect signals detected before this depth threshold.
The unit can therefore operate as an altimeter to verify other onboard instrumentation. The transmitted power is then automatically adjusted to take into account the attenuation of the returns from the seabed caused by transmission and absorption losses by the seafloor. The complex form of the correlation coefficient between two complex acoustic signals is then used by AquaTrak to generate velocity measurements.
The breakthrough in AquaTrak™ CVL was understanding how to use the SAS transducer arrays as a CVL in order to estimate with sufficiently high accuracy the three-dimensional velocity vector, giving the displacement between successive pings. The side-by-side comparison (shown below) of the forward ground speed given by a 300 kHz SAS used as a CVL and a conventional 600kHz DVL shows the much greater accuracy achieved by the CVL, which provides the evidence of the high potential of CVL technology.
Along-track velocity of a 600kHz DVL (in grey) compared to that of a ‘through the SAS sensor’ CVL operated at 300kHz, performing correlations in multiple (other colors) 2m range windows varying from 40m to 160m. The ground truth is provided by the quality of the SAS imagery which is focused for the CVL and defocused for the DVL.
Find out more information at Tritech.co.uk