This study investigates the accuracy of the wave products retrieved by a 12-MHz
high-frequency (HF) phased-array radar, and establishes their potential to characterise
wave-current interactions. The two stations composing the system were
deployed in 2011 to overlook the Wave Hub, a test site for marine renewable energy
devices located on the south-western coast of the United Kingdom. The system
was conceived and configured to reduce the inaccuracies introduced by short time
averaging and minimal overlap between stations, both associated with the most
traditional HF radar deployments, whose primary activity is current measurement.
Wave spectra were retrieved by two independent inversion algorithms, which were
evaluated both independently and relative to each other. This process helped
determining the errors associated to the algorithm used, and differentiated them
from those inherent to the radar technology itself.
The first method investigated was a semi-empirical algorithm distributed with
Wellen Radars (WERA), which was calibrated using in situ measurements collected
within the radar footprint. Evaluated through comparison against measurements
acquired by three in situ devices, the results revealed estimates of significant
wave height with biases below 9 cm, Pearson correlations higher than 0.9,
and RMS errors that range from 29 to 44 cm. The relative error of wave energy
period comparisons was within 10% for periods between 8 and 13 s, while both
under- and overestimations were observed above and below that range, respectively.
The validation demonstrated that when locally calibrated, the algorithm
performs better than in its original form in all metrics considered. Observed discrepancies
were mainly attributable to single-site estimations, antenna sidelobes,
and the effect of the second-harmonic peaks of the Doppler spectrum.
As opposed to the semi-empirical inversion, the second method evaluated in this
work provides estimates of the full directional spectrum. Compared against the
in situ measurements, the radar spectra were more spread over frequencies and
directions, and had a lower energy content at the peak of the spectrum. In terms
of parameter estimation, this was generally translated in a slight underestimation
of wave periods, but accurate estimates of significant wave heights. Pearson correlations
between these parameters and the in situ measurements for the bulk of
the spectrum were higher than 0.9, and both types of measurements resulted in
similar standard deviations. The inversion algorithm showed a high skill estimating
mean wave directions, which revealed linear correlations higher than 0.8, when
compared to the in situ devices. Overall, the inversion algorithm has shown to be
capable of providing accurate estimates of directional spectra and the parameters
derived from them, and at present the main drawback of the method is the data
return, which due to the high data quality requirements of the algorithm, did not
exceed 55% over the 8-month period studied here.
In the second part of this work, the validated measurements were examined to
determine their ability to reproduce the effects of wave-current interactions. The
fine structure of the surface current was first evaluated, and revealed a circulation
dominated by tides. The residual flow was seen to respond to the wind, as well
as to the stratification present in the area during the spring and summer months.
These data were then used to assess their contribution to wave refraction over
the radar domain. The results show modulations in the wave phase parameters,
which resulted from both the temporal and spatial derivatives of the surface current
velocities.
The evaluation of HF radar wave measurements provided in this work has shown
that, properly configured, this technology can produce accurate estimates of several
statistical descriptors of the wave field. Together with the highly accurate
surface currents also measured by this device, the spatial wave data obtained has
proved to have great potential for studying wave-current interactions; a skill that
can be of support to coastal wave modelling.
Date of Award | 2017 |
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Original language | English |
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Awarding Institution | |
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Supervisor | Daniel Conley (Other Supervisor) |
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- HF radar
- Wave Hub
- Waves
- Surface Current
- Wave-current
Evaluation, Analysis, and Application of HF Radar Wave and Current Measurements
Lopez, G. (Author). 2017
Student thesis: PhD