SAMANBERING AV ALDUFORSØGNUM FRÁ ECMWF VIÐ ALDUMÁTINGAR GJØRDAR Á FØROYALEIÐINI 141 more energetic peak frequencies, and a slightly narrower peak, one such example is given in the upper plot in Figure 7. Discussion Before going into the detailed discussions of the fit of the modelled wave parameters at the different locations, a closer look into the effect of the cut-off frcqucncy flu rh on the measurements is needed. Using all the measured wave spectra at WVD-4 (17196 measurements spanning from 10/2-1999 to 13/2-2004) as a reference database, it was investigated what the effect of different values for f were on the wave parame- ters H g and Tm02. The inspection showed that fhj h=0.50 Hz, corresponding to fhigh at WV-2, introduced a positive bias (artificial overshoot) of 0.43 s in Tm02 and a negative bias in Hm0 of -0.01 m. \ífhjg=Q25 s, corre- sponding to fhh at K7, the artificial posi- tive bias in T would be 1.43 s and the bias in H 0 would be -0.09 m. The parame- ters from the WVD-4 site are, as men- tioned earlier, compensated for the effect of (. , whereas the measurements at WV-2 •'lugh and K7 are not. When compensating for Ihc effect frorn f. , on T ,,,-measurements at WV-2 and K7 it becomes apparent that the true 7^-bias is in the region of 1 s at all sites for most of the events. It is there- fore clear that the EW4 rnodel seems to consistently over-predict the Tm02 wave pe- riod. Due to inherent random properties in wind and wave fields, there is a lower limit to the scatter index of wave parameters. For the wave height this lower limit of the scatter index, lies on average in the region of 10-20% (Kornen et al., 1994). As re- ported by Cardone et al. (2000), a gener- ally accepted high skill level for continu- ous hindcasts of Hm0 is represented by a scatter index of less than 0.25 associated with bias of less than 0.25 m and a correla- lion of 0.90 or greater. Looking at Table 4, and comparing it to otlier operational models (Bidlot et al., 2002; Nielsen, 2002, 2003a, 2003b, Jans- sen et al., 2005), it is clear that the EW4 model prediction is good for all locations and events. When this is said, it is quite clear that the modelled wave height performance is seasonally dependent, having larger nega- tive bias and smaller skill index in the win- ter events. This seasonal performance vari- ation in H „ of the EW4 mođel is also doc- umented in Bidlot et al. (2002). Due to the skill of the present wave models, poor inodel performance says rnore about the driving wind fíelds than the model itself (Komen et al., 1994). This claim seems in the present case to be supported by the general under prediction of the wind fields observcd at K7 in the winter events (Figure 2). Another trend which is visible in all events is the under prediction of the wave height, in the peak of the storms. This problem is well known from different ap- plications, and the rnajor source for error can usually be traced back to deficiencies in the forcing wind field (Cardone et al., 1996). The rnodel prediction of Hm0 and T are not affected by the same order of consis- tent bias as it is seen in T and the bias of m02

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