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Article

SAR-Based Wind Resource Statistics in the Baltic Sea

Wind Energy Division, Risø DTU, Frederiksborgvej 399, 4000 Roskilde, Denmark
*
Author to whom correspondence should be addressed.
Remote Sens. 2011, 3(1), 117-144; https://doi.org/10.3390/rs3010117
Submission received: 16 November 2010 / Revised: 22 December 2010 / Accepted: 31 December 2010 / Published: 11 January 2011

Abstract

:
Ocean winds in the Baltic Sea are expected to power many wind farms in the coming years. This study examines satellite Synthetic Aperture Radar (SAR) images from Envisat ASAR for mapping wind resources with high spatial resolution. Around 900 collocated pairs of wind speed from SAR wind maps and from 10 meteorological masts, established specifically for wind energy in the study area, are compared. The statistical results comparing in situ wind speed and SAR-based wind speed show a root mean square error of 1.17 m s−1, bias of −0.25 m s−1, standard deviation of 1.88 m s−1 and correlation coefficient of R2 0.783. Wind directions from a global atmospheric model, interpolated in time and space, are used as input to the geophysical model function CMOD-5 for SAR wind retrieval. Wind directions compared to mast observations show a root mean square error of 6.29° with a bias of 7.75°, standard deviation of 20.11° and R2 of 0.950. The scale and shape parameters, A and k, respectively, from the Weibull probability density function are compared at only one available mast and the results deviate ~2% for A but ~16% for k. Maps of A and k, and wind power density based on more than 1000 satellite images show wind power density values to range from 300 to 800 W m−2 for the 14 existing and 42 planned wind farms.

1. Introduction

Satellite Synthetic Aperture Radar (SAR) can be used for ocean wind mapping at high spatial resolution. The study aims to verify the applicability of the SAR-based method for wind resource mapping in part of the Baltic Sea. Firstly, SAR-based wind maps are compared to observations from 10 meteorological in situ masts using around 900 collocations. Thereafter, an offshore wind resource map is calculated using SAR-based wind maps. Finally, wind resource statistics observed at one site are compared to the SAR-based results, and the wind resource results from existing and planned offshore wind farms are examined.
Several studies demonstrate that C-band SAR (~5.3 GHz) can be used to extract wind speed and wind direction over the ocean at high spatial resolution ~1 km × 1 km [1,2,3,4,5,6]. In the present study, data from the Advanced SAR (ASAR), on-board the Envisat satellite launched in 2002 by the European Space Agency (ESA), are investigated. The ASAR provide several modes, one of them the wide swath mode (WSM) with 400 km swath. The specific advantage of the Envisat ASAR WSM is the excellent coverage in the study area, the southwestern part of the Baltic Sea including parts of the Danish, Swedish, German and Polish waters covering the area from 10° to 19°E longitude and 54° to 58°N latitude. Kattegat Strait is included. See Figure 1.
Figure 1. Map of the study area with indication of the 17 meteorological masts. Those indicated with ◊ are used in the comparison study.
Figure 1. Map of the study area with indication of the 17 meteorological masts. Those indicated with ◊ are used in the comparison study.
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Offshore wind power began at Vindeby in 1992 with 11 wind turbines located in the Baltic Sea in Denmark. The installed capacity of this first wind farm is ~5 MW. Today the study area in the Baltic Sea is home to 14 wind farms with a total capacity of 622 MW distributed as 486 MW in Denmark, 133 MW in Sweden and 3 MW in Germany. There are plans to increase to a total of 12 GW offshore wind farm capacity in the Baltic Sea within the study area. The plans include new capacities in Denmark 1,854 MW, Sweden 5,218 MW, Germany 3,540 MW and Poland 900 MW, see Appendix A for details. In the Baltic Sea outside the study area there are offshore wind farm plans in Estonia, Latvia, Lithuania, Russia (Kaliningrad), Finland and Sweden. Thus there is interest in offshore wind statistics in the Baltic Sea. Predictions on wind resources for the new wind farm sites are interesting.
Satellite SAR used in wind resource estimation has a brief history having started at the turn of the Millennium [7]. Satellite SAR wind maps from the North Sea have been compared to meteorological mast data [8,9,10]. Satellite-based SAR wind mapping in the Baltic Sea encompasses the wind farm wake study near the Nysted wind farm [11], case studies comparing satellite SAR and mesoscale model results [1,12,13,14], and the production of preliminary mean wind speed maps without comparison to in situ data or model results [15,16].
Observing offshore winds with meteorological masts is costly, but at least 17 masts have been installed within the study area of the southern Baltic Sea, and the Skagerrak and Kattegat Straits. The novelty of the present study is the inclusion of ten different meteorological masts—all installed for the specific purpose of wind resource assessment—enabling a comprehensive comparison within the study area. It is anticipated that the quality of the meteorological observations will be of higher precision and accuracy than buoy wind data. The comparison is done case by case, on wind speed using a footprint averaging technique in the SAR-based wind maps and a time-average from the mast data.
The article describes satellite SAR wind mapping, the meteorological data from the masts, and the comparison results on wind speed, wind direction and wind resource statistics. Furthermore, the wind resource map based on more than 1,000 wind maps and wind resource statistics for present and future offshore wind farms in the study area of the Baltic Sea are presented and the results are discussed.

2. Satellite SAR Wind Mapping

In the Wind Energy Division at Risø DTU satellite, SAR wind mapping is performed using the Johns Hopkins University, Applied Physics Laboratory (JHU/APL) software APL/NOAA SAR Wind Retrieval System (ANSWRS). The Envisat ASAR WSM images are downloaded in near-real-time from ESA and the following automated procedure is applied: The pixels are calibrated to obtain the Normalized Radar Cross-Section (NRCS) value, then pixels are averaged to around 500 m, and finally the geophysical model function CMOD-5 [17] is used to retrieve wind speed using the wind direction a priori from the US Navy Operational Global Atmospheric Prediction System (NOGAPS). The spatial averaging of SAR pixels suppresses noise effects from longer ocean waves and from speckle, an inherent property of imaging radars. The 6-hourly model wind vectors are available at a 1 degree latitude and longitude grid and the wind vectors from the lowest model level around 10 m above the surface are used. To match the satellite data, the wind vectors are interpolated in time and space [18,19].
The wind maps resolve details on atmospheric mesoscale wind phenomena. Figure 2 shows the wind speed map from 1 January 2010 observed at 20.48 UTC. All time stamps in the article are in UTC. In Skagerrak Strait strong winds are channeled between Norway and Denmark from the northeast. Wind streaks are present and wind speeds are between 15 and 20 m s−1. In the South Baltic Sea the winds are weaker, around 7 to 12 m s−1 with lee effects southwest of the Danish islands and along the Swedish coast.
Figure 2. Wind speed map of the South Baltic Sea and interior Danish Seas observed from Envisat ASAR wide swath mode on 1 January 2010 at 20.48 UTC with the NOGAPS wind direction vectors shown in white. Risø DTU/JHU APL.
Figure 2. Wind speed map of the South Baltic Sea and interior Danish Seas observed from Envisat ASAR wide swath mode on 1 January 2010 at 20.48 UTC with the NOGAPS wind direction vectors shown in white. Risø DTU/JHU APL.
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The microwave radiation backscattered from the ocean surface is non-linearly proportional to the size and orientation of capillary and short-gravity waves produced near-instantaneously by the local surface winds. Thus using information on the radar incidence, azimuth angle, and relative wind direction, the wind speed is retrieved for a neutrally stratified marine atmosphere at 10 m a.s.l. from the empirical CMOD functions. A more detailed description of SAR-based wind retrieval is given in [15]. In near-coastal regions non-neutral static stratification often prevails, and a correction to the neutral wind profile would be ideal. However, for this task accurate sea and air temperatures are necessary, and this information is generally not available.
Physical obstacles located in the ocean such as ships, oil rigs, and wind turbines act as reflectors and the backscattered microwave radiation is significantly increased. The CMOD function will, in such cases, provide a positively biased wind speed observation. In contrast, oil spill and thick algae blooms at the ocean surface can reduce the backscattered signal as the generation of capillary waves is hindered. The result is a negatively biased wind speed. Convective rain cells also influence SAR data. Often a pattern is seen with increased winds around the rain cell, and with reduced wind inside the rain cell, possibly due to the rain drop’s interference (splashing effect) with the capillary waves and/or lower winds. Sea bottom structures, ocean and tidal currents [20], and long internal ocean waves can also influence SAR and override the basic wind speed signal. For the study area one or more of the above situations may occur. However, despite all these possible shortcomings, ocean winds are generally mapped reasonably well from C-band SAR [6]. Sea ice was present in parts of the study area from late January to late February 2010 as it was an unusually cold winter. Information from the Swedish Meteorological and Hydrological Institute (SMHI) Ice Service and visual inspection of the wind maps were used to discard some scenes.
At Risø DTU 1009 Envisat ASAR WSM scenes covering the study area are processed to wind maps. Table 1 lists the number of scenes per year and per month. There are 523 morning passes observed between 08.52 and 10.01 UTC and 486 evening passes observed between 20.05 and 21.06 UTC.
Table 1. Envisat ASAR data used in the study per year and per month.
Table 1. Envisat ASAR data used in the study per year and per month.
Year20032004200520062007200820092010
Number of scenes8301011530224624850
Month123456789101112
Number of scenes10269119637664837997817799

Footprint Averaging and Wind Resource Statistics

The comparison of SAR-based winds to meteorological wind observations is done using footprint averaging in the wind maps. The footprint theory [21] as described in [22] is used. The footprint is located upwind of each meteorological mast in each collocated wind map. The wind direction is used locally to estimate the direction of the footprint. The size of the footprint is a function of the height, which in this case is 10 m above sea level. The pixels within the 95% limit of the footprint are split into very tiny areas and each area is weighted with the footprint density function and averaged. In this way a physically-based selection of spatial wind information is used according to atmospheric theory to compare winds at a certain position (x,y,z,t) in time. For a roughness at sea around 0.0002 m the footprint stretches around 860 m upwind with the maximum influence at half this distance. The statistical analysis of SAR wind maps is performed with the Satellite-Wind Atlas Analysis and Application Program (S-WAsP) tool developed by Risø DTU [23].
The Weibull probability distribution function is commonly used to describe wind speed data as in the European Wind Atlas [24]. The available wind power density, E, (that is proportional to the wind speed cubed), may be calculated from the two Weibull parameters, the scale parameter A and the shape parameter k, using the gamma function Γ, and the air density ρ (~1.245 g/m3 at 10 °C) as
E = 1 2 ρ A 3 Γ ( 1 + 3 k ) .
Studies from the North Sea have shown SAR wind maps to be a possible source of information for the estimation of A and k [8,10]. Recent results from the North Sea show deviations between SAR-based wind resource statistics compared to the meteorological data below 5% for the mean wind speed and A and below 7% for E and k, when a sufficient number of samples are available [10]. If only 100 to 200 samples can be purchased the new wind class method is recommended. It is necessary to have many more available images in the data archive in order to populate the wind classes. The wind class method is based on a selection of SAR wind maps for the analysis combined with weighting of the SAR-based results using long-term mesoscale model statistics as input to quantify the weighting coefficients. The wind class method is primarily relevant when few samples are available whereas if more than 400 samples are available the random sampling method appears to be the best option. The random sampling method is based on equal weight to all available samples. This is used here. Weibull fitting of the SAR-based wind maps is done with the maximum likelihood estimator suitable for sparse data sets [25].

3. Meteorological Data

The locations of the 17 meteorological masts are indicated in Figure 1. Table 2 lists the geographical coordinates of the met-masts and the data owners. The data periods with the first and last observation from each of the ten masts used in the comparison study and the observational heights are listed. Data from the other seven masts are not available or do not overlap in time with the satellite images, however, basic information on these masts is also included in Table 2.
Brief descriptions of the meteorological data and data analysis for each of the ten meteorological masts are given in Section 3.1, Section 3.2, Section 3.3, Section 3.4 and Section 3.5. It is the wind speed at 10 m above sea level that is extracted from satellite SAR, thus it has been chosen to extrapolate the met-mast wind speed to this height—if not directly observed at 10 m. In order for the statistics from the masts to match well with the footprint averaging technique, an hourly average centered at the satellite recording time is used. At shorter averaging time scales, e.g., 10 minutes, greater scatter is found, probably because the finer scales are not resolved in SAR. All masts have data stored every 10 minutes and several masts have two-sided measurements (to avoid mast shadow effects).
Table 2. Longitude (long.) and latitude (lat.) for 17 met-masts in the study area: In situ data from the top ten masts are used in the comparison study with indication of the data periods used and the observational heights for wind speed (zu in m) (some two-sided) and direction (zdir in m) used. The distance (D in km) to nearest land is given for all masts.
Table 2. Longitude (long.) and latitude (lat.) for 17 met-masts in the study area: In situ data from the top ten masts are used in the comparison study with indication of the data periods used and the observational heights for wind speed (zu in m) (some two-sided) and direction (zdir in m) used. The distance (D in km) to nearest land is given for all masts.
Met mastLong. Lat.OwnerPeriodCountryDzuzdir
FINO-213.154167, 55.006944BMU*20071209 20090921DE38.232 to 102 at 8 heights32
Lillgrund-112.760000, 55.500000Vattenfall20031010 20050902SE8.725 (N/S)23
Lillgrund-212.765400, 55.499783Vattenfall20060531 20071228SE8.71318
Læsø11.123250, 57.08422Techwise20030301 20031010DK13.915 (SW/NE)28
Nysted-111.663461, 54.53527DONG Energy20040620 20080610DK7.11010
Nysted-211.654026, 54.55354DONG Energy20040617 20080404DK7.31010
Nysted-311.790082, 54.53981DONG Energy20040620 20080607DK9.21010
Nysted-411.835698, 54.53494DONG Energy20040620 20080607DK6.91010
Nysted-511.745960, 54.54075DONG Energy20030301 20050524DK11.8844
Omø Stålgrunde11.130000, 55.050000DONG Energy20030301 20050524DK10.41048
Arkona Becken SÖ14.12, 54.78Arkona-Windpark2007–DE37.1No data used
Gedser Rev12.086800, 54.503250Risø DTU1997–2003DK9.5
Midgrund12.657122, 55.702861Risø DTU1997–1999DK2.3
Sky200011.410367, 54.285115GEOmbH2003–DE14.7
Stora Middelgrund12.104708, 56.561347Universal WindOffshore2008–2009SE29.7
Vindeby SMS11.130053, 54.954461Risø DTU1993–2001DK0.3
Vindeby SMW11.127326, 54.968162Risø DTU1993–1998DK1.7
*BMU: Federal Ministry for the Environment, Nature Conservation and Nuclear Safety in Germany.
Six of the meteorological masts are located near offshore wind farms and observe wind farm wake effects for certain wind directions, i.e., reduced wind speeds. In the context of comparing wake-influenced meteorological data and wake-influenced satellite SAR, it is expected that the satellite wind maps record similarly reduced wind speeds. Only when satellite backscatter is enhanced, due to returns from the turbine towers and blades, an apparent too high wind speed is expected. The footprint has a length of around 860 m. Wind speed data are omitted from the verification study (but presented in a separate table) when wind turbines are positioned closer to the mast than this distance.

3.1. FINO-2 Data

The FINO-2 meteorological mast is the second of the three German ‘Forschungs-plattformen in Nord- und Ostsee’ (research platforms in the North and Baltic Seas). It is located midway between Germany and Sweden, around 38.2 km and 38.6 km, respectively. Information is available at http://212.201.38.20/fino2/. The wind speed at 32, 42, 52, 62, 72, 82, 92, 102 m is extrapolated to 10 m using the logarithmic wind profile and the Charnock roughness model with the constant set at 0.0144 following [26] and assuming neutral stability. There is no wind farm nearby.

3.2. Lillgrund-1/-2 Data

The Lillgrund-1 data were collected prior to construction of the Lillgrund wind farm that consists of 48 turbines of 2.3 MW. Wind speed observations at 25 m height at two booms in directions north and south are used. The highest wind speed from the two booms is selected to avoid mast shadow effects. The wind speed is extrapolated to 10 m as for FINO-2.
The Lillgrund-2 mast is in fact the Lillgrund-1 mast moved to a nearby location and re-instrumented. The Lillgrund wind farm is constructed less than 500 m east of the Lillgrund-2 meteorological mast. This results in a wind farm wake sector from 300° to 360° and 0° to 120°, and a free stream wind sector from 120° to 300°. Only the free stream sector is useful for wind speed verification analysis. The wind speed is observed at 13 m and extrapolated to 10 m as for FINO-2.

3.3. Læsø Data

The Læsø data were recorded in the early years of the Envisat mission. Only a few SAR observations are collocated with mast data in our dataset. The wind speed is observed at 15 m at two booms pointing southwest and northeast. The highest wind speed is selected to avoid mast shadow effects, and the data are extrapolated to 10 m as for FINO-2. There is no wind farm nearby.

3.4. Nysted-1/-2/-3/-4/-5 Data

The five meteorological masts at Nysted are located near the Nysted offshore wind farm. For the layout of the wind farm and masts see [27] and http://www.dongenergy.com/Nysted. Only meteorological observations after construction of the wind farm are used in the study. The Nysted wind farm started to operate on the 1 December 2003. Two of the masts, Nysted-1/-2, are located west of the wind farm both at distances of less than 500 m from the nearest row of wind turbines. The two other masts, Nysted-3/-4, are located east of the wind farm at distances of around 1 km and 4 km, respectively, from the nearest row of wind turbines. The fifth mast, Nysted-5, is located within the wind farm itself. The position of the masts and the wind turbines, results in the following wake and free stream sectors: Nysted-1/-2 both have wake sectors from 0° to 180° and free stream sectors from 180° to 360°. Nysted-3 and -4 are located far enough from the wind farm to have free stream sector for all 360°. This only implies that the upwind footprint of the satellite SAR is shorter than the distance to the nearest wind turbines and the turbines do not contribute high backscatter. Nysted-5 is located inside the wind farm and has a 360° wake influenced sector.
At Nysted-1/-2/-3/-4, wind speeds are measured with cup anemometers at heights above mean sea level of 10 m and up to 69 m and wind directions are measured at 10 m and 65 m. At Nysted-5, wind speeds are measured at 8 m and 44 m and direction at 44 m; here the wind speed at 10 m is extrapolated from that at 8 m, by using the Charnock formulation for the surface roughness length. Due to the short distance—here 2 m—the stability effect is neglected.
The study of [13] shows that over the water area where the Nysted wind farm is, the stability parameter, the Richardson number Ri, is larger than zero for about 61% of the time and about 26% of the time it is strongly stable with Ri > 0.25, suggesting mainly stable conditions. These features are in agreement with the studies of [28] and [29], where it was also shown that throughout most of the year, the atmosphere over the Baltic Sea is stable. This stable condition indicates a source of uncertainty in the SAR wind retrievals where neutral stability is assumed.

3.5. Omø Stålgrunde Data

The Omå Stålgrunde mast observes wind speeds at 10 m. There is no wind farm nearby.

3.6. Wind Direction from All Masts

Wind directions in the wind maps are from the NOGAPS model. The wind direction is reported both for free stream and wake influence sectors. Wind direction is poorly defined for very low wind speeds. Wind direction comparison results are reported only for cases of wind speed larger than 3 m s−1 observed in the SAR wind maps. Wind direction in NOGAPS is from the lowest model layer, around 10 m above surface. For the masts the wind directions are observed at the following heights: FINO-2 at 32 m, Lillgrund-1 at 23 m, Lillgrund-2 at 18 m, Læsø at 28 m, Nysted-1/-2/-3/-4 at 10 m, Nysted-5 at 44 m, and Omø Stålgrunde at 48 m. The wind directions from the mast data have not been adjusted to 10 m as veering is expected to be small.

3.7. Wind Energy Resource Statistics

Wind resource results from the commercial masts cannot be published. Thus only FINO-2 data are available for wind resource comparison in the Baltic Sea study area. Wind speeds are observed at 32, 42, 52, 62, 72, 82, 92, and 102 m. The Wind Atlas Analysis and Application Program (WAsP) [30] has been used to fit the Weibull A and k parameters. To what extent the wind resource at 10 m was estimated similarly from data at all heights was investigated and the result showed variations indicating flow distortion, in particular, at the lower heights. The final result for comparing SAR-based and in situ wind resource statistics was estimated from meteorological data at 102 m.

4. Results

4.1. Wind Direction

The comparison results on wind direction are presented first, because these are used to initiate the local wind speed retrieval. The wind directions in the wind maps are the NOGAPS wind directions interpolated in time and space to match locally in each satellite image. Figure 3 shows wind direction from all masts versus NOGAPS. In Figure 3 a few observations near 0° and 360° are removed (e.g., in case met-data shows 355° and NOGAPS shows 10°). The data are removed to provide a suitable basis for linear regression within 0–360°. Linear regression results, for each mast for its free stream sector and wake-influenced sector, are listed in Table 3. The statistical results from the free stream sectors and wake-influenced sectors are similar. Therefore the overall result includes all observations, and the overall statistics are given in the last column of Table 3. Figure 4 shows the residual plot.
Figure 3. Wind directions from meteorological stations versus NOGAPS, N = 927.
Figure 3. Wind directions from meteorological stations versus NOGAPS, N = 927.
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Figure 4. Residual plot for the linear regression on wind direction from masts versus NOGAPS.
Figure 4. Residual plot for the linear regression on wind direction from masts versus NOGAPS.
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Table 3. Linear regression results for wind direction between masts versus NOGAPS in free stream sectors and wake-influenced sectors; and ALL includes both free stream and wake-influenced sectors; N is number of samples (−); R2 is the correlation coefficient(−); SD is standard error (°); RMS is root mean square error (°); bias is the offset of the linear regression (°) and the slope (−).
Table 3. Linear regression results for wind direction between masts versus NOGAPS in free stream sectors and wake-influenced sectors; and ALL includes both free stream and wake-influenced sectors; N is number of samples (−); R2 is the correlation coefficient(−); SD is standard error (°); RMS is root mean square error (°); bias is the offset of the linear regression (°) and the slope (−).
FINO2Lill.1Lill.2Nys.1Nys.2Nys.3Nys.4Nys.5OmøALL
FreeFreeFreeWakeFreeWakeFreeWakeFreeFreeWakeFreeALL
N16523774287476346155563535927
R20.9520.9650.8810.9710.8590.7640.8050.8810.9700.9700.9720.9710.950
SD18.9516.6416.6322.6715.9419.6517.5113.8515.7315.7015.0716.1620.11
RMS5.794.377.865.448.1612.6810.386.563.853.843.563.886.29
Bias−8.44−11.5947.1620.0848.5422.7132.4612.896.8317.975.243.027.75
Slope1.011.050.871.010.860.830.900.931.011.000.970.980.99

4.2. Wind Speed

The comparison results on wind speed are calculated for each meteorological mast taking into account free stream and wind farm wake sectors. The wind directions are taken from NOGAPS to discriminate which directional sector any given pair of wind speeds from a meteorological mast and a SAR wind speed map belongs to. There are more data pairs included in the wind speed analysis than in the wind direction analysis above. Comparison of wind speeds are done also for wind speeds less than 3 m s−1 (in contrast to the wind directional comparison analysis) but for winds less than 2 m s−1, the software excludes the SAR-wind data. SAR wind maps contain observations below 2 m s−1, yet the quality of wind speed at this low end is questionable. The linear regression statistics for wind speeds are shown in Table 4(a,b), for free stream sectors and wake sectors, respectively.
The overall correlation coefficient is higher for the free stream sectors (R2 = 0.783) than for the wake sectors (R2 = 0.676). In the free stream sectors, the bias is (slightly) negative for all masts except Omø Stålgrunde, whereas it is positive for the wake sectors of Lillgrund-2 and Nysted-1/-2 but surprisingly not for Nysted-5. Positive bias indicates strong microwave returns in the footprint from the wind turbines in the wake sectors.
The turbine affected data are not included in the plot between mast wind speed and SAR-based wind speed shown in Figure 5 and winds less than 2 m s−1 in the SAR-wind maps are excluded. The residual plot in Figure 6 shows this omission. Other than that non-linear features do not show and the assumption of a linear fit holds.
Table 4(a) shows that regression using N = 875 samples of collocated wind speed observed at masts and SAR-based wind speed results in R2 = 0.783, SD = 1.88 m s−1 and RMS = 1.17 m s−1. The linear regression slope is 0.96 (with SD = 0.017) and bias −0.25 m s−1 (with SD = 0.152 m s−1).
Figure 5. Wind speeds from ten meteorological stations versus SAR-based winds, excluding the wake sectors for Lillgrund-2 and Nysted-1/-2/-5, N = 875.
Figure 5. Wind speeds from ten meteorological stations versus SAR-based winds, excluding the wake sectors for Lillgrund-2 and Nysted-1/-2/-5, N = 875.
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Figure 6. Residual plot for the linear regression on wind speed from masts versus SAR wind maps.
Figure 6. Residual plot for the linear regression on wind speed from masts versus SAR wind maps.
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Table 4. (a) Linear regression results for wind speed between mast data versus SAR-wind maps in free stream sectors; (b) wake sectors. N is number of samples (−); R2 is the correlation coefficient (−); SD is standard error (m s−1); RMS is root mean square error (m s−1); bias is the offset of the linear regression (m s−1) and the slope (−).
Table 4. (a) Linear regression results for wind speed between mast data versus SAR-wind maps in free stream sectors; (b) wake sectors. N is number of samples (−); R2 is the correlation coefficient (−); SD is standard error (m s−1); RMS is root mean square error (m s−1); bias is the offset of the linear regression (m s−1) and the slope (−).
(a)FINO-2Lill.1Lill.2LæsøNys.1Nys.2Nys.3Nys.4OmøALL
N1803286510511017813742875
R20.7650.7960.7890.9730.8010.7540.8040.8380.6860.783
SD2.041.901.711.001.882.091.661.622.121.88
RMS1.311.151.050.231.131.370.990.891.551.17
Bias−0.21−1.34−0.61−2.32−0.06−0.10−0.22−0.450.22−0.25
Slope1.031.081.061.160.930.920.920.950.920.96
(b)Lill.2Nys.1Nys.2Nys.4ALL
N51655741214
R20.7190.6690.6860.7400.676
SD1.891.591.582.041.85
RMS1.311.191.151.371.36
Bias0.520.940.98-0.780.57
Slope1.060.800.821.030.91

4.3. Wind Resource Statistics

The wind energy resource statistics in the Baltic Sea study area are calculated based on 1009 Envisat ASAR wind maps using the method in [8] with equal weights to all. The data represent seasons and twice-daily conditions (cf. Table 1).
The resulting SAR-based maps at 1 km by 1 km resolution are presented in Figure 7(a–d). The first panel in Figure 7 shows the number of samples and the following three panels show SAR-based results on Weibull A and k, and wind power density, E. The map of overlapping samples shows the characteristic pattern of satellite passes inclined from ascending and descending tracks. There are more samples in the northwest part of the study area and less in the southern region. The maximum number of samples is 538 and the minimum number around 350. Weibull A ranges from 6 m s−1 along the eastern Swedish coast to 9.5 m s−1 in the Skagerrak Strait, and Weibull k ranges from 1.4 near coastlines up to 2.1 in the southwestern part of the study area. In Figure 7(b,c) too high values are found at the Nysted (Rødsand 1) wind farm due to backscatter from the 72 turbines. Wind power density values range from 249 W m−2 to 934 W m−2. The highest wind power density value is found in the Skagerrak Strait, not in the Baltic Sea.
Figure 7. Wind resource statistics based on 1009 Envisat ASAR wide swath mode satellite wind maps covering part of the Baltic Sea and interior Danish Seas. Panels top: (a) number of samples (−); (b) Weibull A (m s−1); (c) Weibull k (−); and (d) wind power density (W m−2) including indication of wind farms. The wind farm numbers refer to Appendix 1.
Figure 7. Wind resource statistics based on 1009 Envisat ASAR wide swath mode satellite wind maps covering part of the Baltic Sea and interior Danish Seas. Panels top: (a) number of samples (−); (b) Weibull A (m s−1); (c) Weibull k (−); and (d) wind power density (W m−2) including indication of wind farms. The wind farm numbers refer to Appendix 1.
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Comparison of the SAR-based wind resource statistics is done for FINO-2. Firstly though, the FINO-2 data observed at eight levels during three years from 1 August 2007 to 31 July 2010 are shown in Figure 8 including the logarithmic profiles for all. Observations at the lower heights appear to be flow distorted (reduced) and none of the other data fall onto one profile. The 102 m data appear not to be reduced and are used to estimate the wind resource at 10 m using data from 9 December 2007 to present. The SAR wind maps are from 2003 to 2010.
The wind speed distribution at FINO-2 and the SAR-based data are shown in a histogram in Figure 9 and wind resource results are listed in Table 5. The SAR-based result appears to estimate mean wind speed and Weibull A well, but over-predicts the wind power density by 29%.
Figure 8. FINO-2 mean wind speed at eight levels observed from 1 August, 2007 to 31 July 2010 using 89,394 concurrent samples and logarithmic profiles extrapolated to 10 m from each of the eight observation heights.
Figure 8. FINO-2 mean wind speed at eight levels observed from 1 August, 2007 to 31 July 2010 using 89,394 concurrent samples and logarithmic profiles extrapolated to 10 m from each of the eight observation heights.
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Figure 9. Histogram of wind speed observed at FINO-2 extrapolated from 102 m to 10 m from 1 July 2007 to 19 October 2010 total of 146,910 samples (in grey) with Weibull fit using WAsP, and wind speed observed from Envisat ASAR from 2003 to 2010, total of 409 samples (in black) with Weibull fit using WAsP.
Figure 9. Histogram of wind speed observed at FINO-2 extrapolated from 102 m to 10 m from 1 July 2007 to 19 October 2010 total of 146,910 samples (in grey) with Weibull fit using WAsP, and wind speed observed from Envisat ASAR from 2003 to 2010, total of 409 samples (in black) with Weibull fit using WAsP.
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Table 5. Wind resource statistics at FINO-2 using all meteorological observations at 102 m extrapolated to 10 m using WasP. For SAR wind maps using WAsP and using maximum likelihood (M.L.) and the differences SAR normalized with mast data (in percentage).
Table 5. Wind resource statistics at FINO-2 using all meteorological observations at 102 m extrapolated to 10 m using WasP. For SAR wind maps using WAsP and using maximum likelihood (M.L.) and the differences SAR normalized with mast data (in percentage).
FINO-2Mast
(WAsP)
SAR
(WAsP)
SAR
(M.L.)
Difference (%)
(WAsP-WAsP)
Difference (%)
(WAsP-M.L.)
Mean wind speed (m s−1)8.128.178.160.50.6
Weibull A (m s−1)9.008.729.212.33.1
Weibull k (−)2.311.941.93−16.9−16.0
Power density (W m−2)5215596707.328.6
N (-)146,910409409--
The SAR-based mean wind speed, A, k and E at the position of the 17 meteorological masts are listed in Table 6. The mean wind speed tends to increase with distance from the nearest coastline as graphed in Figure 10. It should be noted that the effect of nearby wind turbines is neglected. For certain sites and wind directions too high wind speed values may occur due to backscatter from the turbines, but may also include wind farm wake areas with reduced wind speed. For Midgrund the distance to the nearest wind turbines is ~600 m, islands or ships may explain this too high value. Thus the results for the sites with nearby wind turbines are clearly not valid for free stream wind resource assessment.
Table 6. SAR-based wind resource statistics listed with increasing mean wind speed (U), and including wind power density (E), Weibull A and k, number of samples (N) and the distance to the nearest coast. The satellite wind maps are from Envisat ASAR from March 2003 to April 2010. Sampling uncertainties are shown in brackets. *nearby wind farm.
Table 6. SAR-based wind resource statistics listed with increasing mean wind speed (U), and including wind power density (E), Weibull A and k, number of samples (N) and the distance to the nearest coast. The satellite wind maps are from Envisat ASAR from March 2003 to April 2010. Sampling uncertainties are shown in brackets. *nearby wind farm.
Met-stationU (m s−1)E (W m−2)A (m s−1)k (−)N (−)Dist. (km)
Vindeby SMS*6.67 (±0.16)346(±24)7.53 (±0.18)2.04 (±0.07)4630.3
Vindeby SMW*6.74 (±0.20)459(±40)7.53 (±0.23)1.63 (±0.05)4681.7
Omø Stålgrunde6.90 (±0.16)364 (±24)7.79 (±0.18)2.16 (±0.08)46410.4
Sky20007.01 (±0.18)401 (±29)7.92 (±0.20)2.05 (±0.08)41714.7
Lillgrund-2*7.18 (±0.20)477(±39)8.09 (±0.23)1.85 (±0.07)4188.7
Lillgrund-1*7.22 (±0.20)483(±39)8.14 (±0.23)1.86 (±0.07)4158.7
Gedser Rev7.22 (±0.20)498(±42)8.12 (±0.23)1.81 (±0.07)4239.5
Nysted-3*7.29 (±0.18)446(±32)8.23 (±0.20)2.07 (±0.08)4399.2
Nysted-4*7.30 (±0.18)451(±32)8.24 (±0.20)2.05 (±0.07)4416.9
Nysted-1*7.37 (±0.18)453(±31)8.32 (±0.20)2.11 (±0.08)4387.1
Nysted-2*7.45(±0.17)460(±31)8.41 (±0.20)2.14 (±0.08)4397.3
Nysted-5*7.70 (±0.18)500(±33)8.69 (±0.20)2.18 (±0.08)43811.8
Læsø7.70 (±0.19)593(±42)8.67 (±0.21)1.84 (±0.06)54013.9
Midgrund*7.90 (±0.25)777(±75)8.80 (±0.29)1.58 (±0.05)4242.3
Stora Middelgr.7.99 (±0.19)618 (±42)9.01 (±0.21)1.96 (±0.07)52529.7
FINO-28.16 (±0.22)670(±53)9.21 (±0.25)1.93 (±0.07)40938.2
Arkona-Becken-S.8.17 (±0.23)714(±60)9.19 (±0.26)1.83 (±0.07)40737.1
Figure 10. SAR-based mean wind speed (top) and wind power density (bottom) at the location of 17 meteorological masts, near or far from wind farms.
Figure 10. SAR-based mean wind speed (top) and wind power density (bottom) at the location of 17 meteorological masts, near or far from wind farms.
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Finally, the wind resource statistics based on satellite SAR wind maps are calculated for existing and planned offshore wind farms in the study area. The existing wind farms include nine in Denmark, four in Sweden and one in Germany. The three largest are Rødsand 2 with 90 turbines and a total of 207 MW installed capacity since August 2010; Rødsand 1 with 72 turbines and a total of 166 MW installed capacity since 2003; and Lillgrund with 48 turbines and a total of 110 MW installed capacity since 2007.
There are plans of adding 42 new wind farms in the study area in coming years. A list of existing and planned wind farms is provided in Appendix A. The information on the wind farms is taken mainly from http://www.4coffshore.com/windfarms. The wind resource statistics for existing and planned wind farms are calculated based on SAR wind maps. The results include mean wind speed, Weibull A and k, wind power density and the number of wind maps used at each wind farm. Figure 11 shows mean wind speed per country, and Figure 12 shows Weibull A and k, and wind power density as a function of distance to the nearest coastline.
Figure 11. Mean wind speed from Envisat ASAR observations at existing and planned wind farm sites per country in the Baltic Sea study area (cf. Table A1).
Figure 11. Mean wind speed from Envisat ASAR observations at existing and planned wind farm sites per country in the Baltic Sea study area (cf. Table A1).
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Figure 12. Weibull A and k (top) and wind power density (bottom) calculated from Envisat ASAR observations at existing and planned wind farms in the study area.
Figure 12. Weibull A and k (top) and wind power density (bottom) calculated from Envisat ASAR observations at existing and planned wind farms in the study area.
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5. Discussion

5.1. Wind Direction Comparison

The comparison results between NOGAPS wind direction and meteorological observations are highly correlated with R2 of 0.950 and RMS at 6.29°. The linear regression slope is 0.99 and the bias 7.75° (i.e., ~2%). Around 900 independent samples are used. The clockwise veering is partly explained by the Ekman spiral that veers clockwise in the northern hemisphere. The overall wind direction statistics show good accuracy.
The reproducibility, i.e., the variation arising using the same method among different met-stations, is very good. Very few extreme outliers in the NOGAPS wind directions are found. Systematic problems do not appear at the investigated locations. Studies have shown that wind direction may be obtained from the SAR image itself by identification of the wind streaks aligned approximately with the dominant wind direction, e.g., [31]. The optimal situation is to use directions from streaks, yet problems associated with automatic streak detection limits this option. Further, it has been shown that using wind direction from a local mast to initiate the local wind retrieval also provides very good results locally [8]. Only very few meteorological masts are available and, for near-real-time SAR wind mapping, this is not a viable option. However, it can be done offline as post-processing for a specific local site in order to increase the accuracy nearby. It has to be kept in mind though that wind directions are neither constant in time nor in space. It is clear that mesoscale atmospheric phenomena occur in this enclosed sea with many islands, see Figure 2. But despite this fact, the NOGAPS global model appears to provide good wind directions. This is important as the wind speed retrieval is initiated with the NOGAPS wind directions.

5.2. Wind Speed Comparison

The overall statistics from the wind speed regression analysis are also of good quality, though with lower R2 than for wind directions. It is the first time that a comprehensive data set of high-quality meteorological masts—all designed for wind resource assessment—has been used for comparison to SAR-based winds. For five masts more than 100 collocated pairs are available. The wind speed statistics based on nearly 900 collocated pairs of meteorological observations from a total of ten masts and SAR-based winds in free stream (not including noise from wind turbine backscatter) show R2 0.783, SD 1.88 m s−1 and RMS 1.17 m s−1. There is a small negative bias −0.25 m s−1 (with SD 0.152 m s−1) and the linear regression slope is 0.960 (with SD 0.017). The statistics are comparable to results from Horns Rev in the North Sea [8,22] and clearly better than the nominal accuracy of the geophysical model function with ±2 m s−1 accuracy [17,32]. The water depth at FINO-2 is 25 m whereas it ranges from 4 to 10 m at Lillgrund and from 6 to 10 m at Læsø, Nysted and Omå Stålgrunde. Tidal currents are insignificant, thus effects of SAR signatures originating from currents are expected to be small. Averaging to 1 km by 1 km grid suppresses small-scale effects.

5.3. Wind Resource Comparison

In the Baltic Sea study area only wind resource statistics from FINO-2 are available for comparison with results from SAR. The results show near zero difference between mean wind speed from mast data and SAR using an extrapolation of wind speed data from 102 m to 10 m. Further the result deviates ~2% on Weibull A but ~16 % on Weibull k. It is statistically more difficult to estimate the Weibull k parameter than the Weibull A parameter. More data are needed to achieve similar accuracy. According to [25] it is necessary with ~70 samples to estimate Weibull A, ~175 samples to estimate Weibull k, and ~2,000 samples to estimate power density within ±10% accuracy at the 90% confidence interval. At FINO-2 the difference in power density values is ~29% using 409 samples comparing results from mast data observed at 102 m using maximum likelihood for Weibull fitting. Using WAsP Weibull fitting to the SAR data (shown in Figure 9 and listed in Table 5) the difference in power density is ~7% between mast data and SAR.
The uncertainty on maximum likelihood fitting is listed in Table 6 and typically is within 50 W m−2. The choice of Weibull fitting influence results as seen in Table 5. Unfortunately only one location is available for comparison of wind energy density results. The FINO-2 meteorological data shown in Figure 8 shows a tendency to have (much) higher winds high in the atmosphere than the logarithmic profile. This may be caused either by: (1) Flow distortion at lower observational heights; (2) stable stratification; or (3) coastal winds that are not fully adjusted [33]; or a combination of the all three.
The vertical extrapolation adds uncertainty. The wind speed data appear to be influenced by the relatively heavy mast construction that is likely to add flow distortion to the wind measurements. It was found that the collocated wind speeds at FINO-2 are less well correlated than for most other masts, see Table 4. No further assessment has been made. Recent results from the North Sea [10] comparing mean wind speed, Weibull A and k, and power density between three masts (Horns Rev, Høvsøre and FINO-1) and SAR-based results have shown deviations less than 5% for mean wind speed and Weibull A and deviations less than 7% for Weibull k and power density, using approximately the same number of SAR samples. Reasons for the better agreement in the North Sea compared to the Baltic Sea could be differences in atmospheric stability. The more enclosed Baltic Sea, where the coastal flow may not be fully adjusted, could be another reason [33].
Weibull statistics are published from three masts in the study area based on meteorological data observed ~50 m above sea level in the 1990’ties, i.e., prior to Envisat. The published results are Weibull A and k of 9.1 m s−1 and 2.3 at 48 m height observed from 1993 to 1997 at Vindeby [34], Weibull A and k of 8.3 m s−1 and 2.3 at 50 m observed from October 1997 to July 1998 at Midgrund [35], and Weibull A and k of 8.6 m s−1 and 2.65 observed at 50 m from March to November 1999 at Omø Stålgrunde [36]. For two masts the data cover less than one year. At Midgrund and Vindeby wind turbines influence the atmospheric flow and the SAR-based results do not reflect free flow conditions. Comparisons are not attempted due to these conditions.

5.4. Examination of Wind Resource Statistics

Examination of the SAR-based maps of Weibull A, k and wind power density (Figure 7) shows as expected higher wind power density value in relatively open seas. The lee effect of islands in the Kattegat Strait and Baltic Sea are notable with lower wind power density value near the islands. The offshore wind climate in the Danish interior seas has lower wind power density than Kattegat, Skagerrak and most of the Baltic Sea. It is noted that Weibull k appears to be higher in the southwestern part of the study area than elsewhere. High k indicates relatively steady winds.
The wind resource statistics presented for the 17 meteorological masts (Table 6, Figure 7) show a trend of higher mean wind speed further offshore. The mean wind speed ranges from 6.7 m s−1 to 8.2 m s−1 with an uncertainty of ±0.2 m s−1. The masts are located from the coast to ~40 km offshore. Midgrund is seen as an outlier with much higher mean wind speed, Weibull A and wind power density than other masts at similar distance to the coast. The high values at Midgrund are most likely due to two wind turbines located less than 600 m from the mast position, nearby islands and ships giving very high backscatter and therefore unrealistically high winds.
Reflection from turbines alters backscatter values. It is seen at the Nysted-1 wind farm (Figure 7(b–d). This wind farm has existed since 2003. Also the Lillgrund can be seen. Lillgrund has operated since 2007 whereas Rødsand-2 (from 2010) cannot be clearly seen in the maps.
The SAR-based mean wind speed, Weibull A and wind power density at the Vindeby, Lillgrund and Nysted masts appear not to be notably affected by wind turbine reflections in contrast to the Midgrund mast. This is concluded as the wind statistics at Vindeby, Lillgrund and Nysted increase gradually with distance from the coast and also compare well with similar statistics from masts not affected by wind turbines (Figure 8).
The Nysted-3/-4 masts are not affected by turbine backscatter but both are affected by wake for westerly winds, thus the results are expected to be (slightly) negatively biased compared to the condition prior to the wind farm. Wind farm wake deficit, i.e., reduced wind downwind of a wind farm, typically is of the order ~10% but may vary dependent upon turbine operations, wind speed and atmospheric static stability. For more detail on SAR-based wake mapping see [11,37].
It is remarkable how low winds are observed by SAR for Omø Stålgrunde and Sky2000. Both have mean wind speed of ~7.0 m s−1 whereas Læsø also located ~12 km offshore shows a mean wind speed of ~7.7 m s−1 (see Table 6). Near Læsø, Omø Stålgrunde and Sky2000 there are no wind farms or other obstacles and the major difference between these three masts is the more open sea at Læsø (Figure 1 and Figure 7). In Figure 7(d), the energy density map shows high values in the Great Belt between Zealand and Fyn along the Great Belt Bridge. More interestingly, an S-shape curve east of the Sprogø windfarm identical to the major ship route for large vessels shows clearly. This is probably due to reflection from ships.
The mean wind speed at existing and planned wind farm locations in the four countries (Table A1, Figure 11) shows a gradual increase as a function of further distances to the nearest coast. There is a significant variation (±0.7 m s−1) in the coastal zone from 0 to 20 km offshore with a mean wind speed ~7.0 m s−1. Beyond 20 km offshore the mean wind speed is ~8.1 m s−1 and varies only ±0.2 m s−1 in all four countries, Denmark, Germany, Poland and Sweden. Increases in coastal winds previously has been studied with similar results [33].
Further details on the SAR-based wind resource statistics are shown in Figure 10 with the Weibull A and k and wind power density results with marking of existing and planned wind farms. It is noticed that all existing wind farms are located less than 11 km offshore whereas only a few new wind farms are planned this close to land. Many wind farms are planned in the 15 to 20 km zone and wind power density is seen to vary from 400 to 700 W m−2. The two extremes are Beta Baltic and Arcadis Ost1, see Table A1. In the coastal zone from 20 km and further offshore, out to 80 km with the Swedish Södra Midsjöbanken as frontier very far offshore, the wind power density tends to range between 600 and 720 W m−2 with two outliers above, namely Rønne Banke X and V with 800 W m−2.
The statistical uncertainty on mean wind speed is ~2 to 3% when based on roughly 400 samples and similar for Weibull A. The uncertainty on wind power density is much higher ~7 to 9% and similar for Weibull k for a data set of this size. According to [25], Weibull A and k may be estimated with ±10% accuracy and 90% confidence using ~75 and ~175 samples, respectively (assuming perfect data).
The present data set represents all seasons and morning and evening conditions. The SAR coverage is not homogeneous (Figure 7(a)) and it reflects in results of Weibull k and energy density in Denmark (a northwest–southeast line) and in the Baltic Sea (a northeast–southwest line). The reason could be few particular images giving strong impact.
For Breitling only 161 valid samples are found which is due to the location. Breitling is located in an enclosed harbor area in Rostock, not truly offshore, and therefore the footprint often includes land and the values are discarded from the series. Furthermore, ocean wind mapping is not adequate in enclosed water but the wind statistics, surprisingly enough, falls nicely within the other results.
The number of samples is important as well as how well the samples represent the general wind climate as described in [10]. The variation in wind speed during the day is not resolved by SAR-based wind maps as these are observed either in the morning or evening passes according to the orbital parameters. Thus diurnal variation in wind speed may add uncertainty. Seasonal wind variations may add uncertainty in case the wind maps do not cover the full year as would be the case, for example, in cold climate regions with sea ice during winter.
SAR-based results are valid at 10 m. A challenging issue is the vertical extrapolation of the SAR-based wind results up to hub-height. The wind data from FINO-2 indicate the problem. Present and future wind turbines may operate at 100 m to 300 m above sea level. In the EU-Norsewind project the vertical extrapolation is being investigated using data from an array of wind profiling lidars observing at 70 to 200 m above sea level installed in the Northern European Seas. Lidar-based results show that the wind profile deviates from the surface-layer wind profile high in the boundary layer [38,39,40,41]. Mesoscale modeling of the offshore wind resource is on-going and comparison of results is in progress, yet beyond the scope of the present paper.
The present analysis is based on Envisat ASAR images. More Envisat ASAR images could be extracted from the archive as well as imagery from ERS-1/-2, Radarsat-1/-2 and ALOS PALSAR. The study, however, is the most comprehensive of its kind on wind resource mapping of the Baltic Sea area.

6. Conclusions

The study presents SAR-based ocean winds compared to wind observations from 10 meteorological masts erected specifically for wind energy mapping in part of the Baltic Sea. Around 900 collocated pairs of Envisat ASAR wide swath mode images and in situ data, show the wind speed to be mapped with root mean square error 1.17 m s−1, bias −0.25 m s−1, standard deviation 1.88 m s−1, and correlation coefficient R2 of 0.783. Ocean wind is mapped from CMOD-5, using wind direction input from a global atmospheric model, and comparison results on wind direction between the model and in situ data are root mean square error 6.29°, bias 7.75°, standard deviation 20.11°, and R2 of 0.950. Using more than 1000 Envisat ASAR wind maps, SAR-based wind resource statistics are examined for the 12 existing and 42 planned wind farms in the study area. It is found that the variation in mean wind is highly variable in the near coastal zone from 0 to 20 km. All existing wind farms are located less than 11 km from the nearest coast but most of the planned wind farms will be located further offshore. Here the SAR-based results indicate high mean wind speed and high wind power density. It is noted that the wind power density ranges from 300 to 800 W m−2 for the planned wind farms. Wind resource statistics are compared only at one meteorological mast, FINO-2, showing Weibull A to deviate ~2% between in situ and SAR-based results, but Weibull k to deviate ~16%. The power density is found to deviate ~29% which is considerably higher than found in a recent study in the North Sea using in situ data from three masts. In the North Sea, the deviations between masts data and SAR-based results were within 7% on Weibull k and power density using approximately a similar number of samples and similar wind retrieval. Further investigation on vertical extrapolation is needed.

Acknowledgements

The work was supported by the EU-Norsewind project (TREN-FP7EN-21908) and the EU-South Baltic OFF.E.R (EU European Development Fund and the South Baltic Program). Satellite data are provided by the European Space Agency (Cat. 1 project 3644 and ESA-CSA SOAR project 6773). Meteorological data from DONG Energy from Nysted, Omø Stålgrunde and Læsø masts as well as meteorological data from Vattenfall from the Lillgrund masts are greatly acknowledged. Also FINO-2 meteorological data from the Forschungsplattformen in Nord- und Ostsee from Bundesamt für Seeschifffahrt und Hydrographie (BSH) are greatly acknowledged. The Johns Hopkins University, Applied Physics Laboratory, USA is thanked for providing and supporting the APL/NOAA SAR Wind Retrieval System (ANSWRS).

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Appendix 1

Table A. Offshore wind farms in operation, under construction and in planning: Number of turbines (T), wind farm capacity (Cap. in MW), geographical position (latitude and longitude), distance (D in km) from nearest coastline (from http://www.4coffshore.com/windfarms) and calculated wind statistics from satellite Envisat ASAR mean wind speed (U in m s−1), Weibull A (m s−1) and k (−), wind power density (E in W m−2)) and the number (N) of wind samples. Tables are given for Denmark (DK), Sweden (SE), Germany (DE) and Poland (PL).
Table A. Offshore wind farms in operation, under construction and in planning: Number of turbines (T), wind farm capacity (Cap. in MW), geographical position (latitude and longitude), distance (D in km) from nearest coastline (from http://www.4coffshore.com/windfarms) and calculated wind statistics from satellite Envisat ASAR mean wind speed (U in m s−1), Weibull A (m s−1) and k (−), wind power density (E in W m−2)) and the number (N) of wind samples. Tables are given for Denmark (DK), Sweden (SE), Germany (DE) and Poland (PL).
DKWind farmYearTCap.Lat. Long.DUAkEN
1Vindeby1991114.954.97N 11.13E1.86.797.601.66461469
2Tunø Knob199510555.97N 10.36E5.56.467.302.08309497
3Middelgr.2000204055.69N 12.68E4.77.368.241.68575422
4Rødsand I20037216654.55N 11.71E10.97.808.812.21514438
5Samsø2003102355.72N 10.58E4.07.238.162.13423483
6Fr.havn I200337.657.43N 10.59E2.26.847.651.67468520
7Sprogø200972155.34N 10.96E9.36.527.352.02326510
8Avedøre201031155.60N 12.46E0.46.467.261.79360484
9Rødsand II20109020754.56N 11.55E8.67.228.152.05437442
10Fr.havn. II201263657.46N 10.64E7.97.017.861.71489527
11Anholt P201220056.50N 11.28E20.97.808.802.02559546
12Anholt O201220056.62N 11.18E18.27.868.871.92604549
13GrenåHavn31856.42N 10.97E2.66.997.892.04400509
14KriegersFlakR20055.10N 12.81E20.77.898.881.84639417
15KriegersFlakS20055.00N 13.07E33.48.159.201.99647385
16KriegersFlakT20055.04N 12.98E28.57.938.941.93617426
17KriegersFlakU20054.93N 12.98E27.57.928.931.87634420
18RønneBankeX20054.95N 14.42E23.48.369.381.75802419
19RønneBankeV20054.89N 14.29E348.379.391.75809420
20Stora Midlgr.Q20056.50N 12.04E448.009.021.95624524
SEWind farmYearTCap.Lat. Long.DUAkEN
1Bockstigen19985357.04N 18.15E5.87.087.971.86456442
2Utgrunden I200071056.34N 16.28E7.36.527.351.89349485
3Ytre Stengr.200151056.17N 16.02E3.76.627.451.89364459
4Lillgrund20074811055.51N 12.78E9.37.738.701.86592419
5Taggen20128330055.86N 14.57E16.37.097.991.88453436
6KriegersFlakII201512864055.07N 13.10E32.47.958.951.83657407
7StoraMiddelgr.201610854056.61N 12.11E34.37.968.981.97610525
8Kårehamn20165056.98N 17.02E7.06.597.431.93354482
9Utgrunden II2016249056.38N 16.27E8.06.347.141.84331482
10Blekinge2019500250055.93N 15.02E19.57.498.452.02494444
11Trollboda3015056.30N 16.18E7.76.247.031.91303481
12Södra Midsjö.90055.67N 17.27E78.98.339.401.96702461
13Klasarden164857.06N 18.16E1.66.937.811.88422442
DE
1Breitling200812.554.16N 12.13E0.37.338.241.81523161
2EnBW Baltic12010214854.61N 12.65E17.17.448.381.84537435
4VentotecOst220148040054.83N 14.07E40.08.309.341.86733406
5ArkonaBeck Süd.8040054.78N 14.12E37.68.179.191.83679407
6GEOFReE52554.25N 11.40E18.66.917.801.97714419
7Beta Baltic5011554.28N 11.40E15.86.997.892.02585418
8ArkoniaSee Sud808054.78N 13.87E26.48.199.241.93403385
9ArkoniaSee West808054.80N 13.80E25.88.179.211.88679387
10ArcadisOstI7035054.83N 13.60E20.08.159.181.83690409
11ArcadisOst2257554.82N 14.13E40.98.169.181.84 707398
12Baltic Eagle8048054.83N 13.87E30.88.259.311.96707386
13BalticPower West8040054.93N 13.08E31.88.099.131.98 682386
14Baltic Power East8040054.97N 13.24E33.48.239.271.87637411
15AldergrundNord.3115554.85N 14.06E40.28.259.291.87718405
16Aldergrund GAP3118654.82N 14.13E40.98.169.181.84707398
17Aldergrund 500207254.82N 14.1E39.08.269.291.84729408
18Arkona SeeOst15054.86N 14.02E39.88.259.281.84726405
19Beltsee2512554.44N 11.51E13.27.148.062.03427434
PL
1Poland P122555.07N 16.64E54.17.848.781.70689417
2Poland P222555.08N 16.9E46.78.159.181.89683451
3Poland P322554.96N 18.21E14.67.798.741.72668411
4Poland P422554.94N 18.37E11.87.848.781.70689417

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MDPI and ACS Style

Hasager, C.B.; Badger, M.; Peña, A.; Larsén, X.G.; Bingöl, F. SAR-Based Wind Resource Statistics in the Baltic Sea. Remote Sens. 2011, 3, 117-144. https://doi.org/10.3390/rs3010117

AMA Style

Hasager CB, Badger M, Peña A, Larsén XG, Bingöl F. SAR-Based Wind Resource Statistics in the Baltic Sea. Remote Sensing. 2011; 3(1):117-144. https://doi.org/10.3390/rs3010117

Chicago/Turabian Style

Hasager, Charlotte B., Merete Badger, Alfredo Peña, Xiaoli G. Larsén, and Ferhat Bingöl. 2011. "SAR-Based Wind Resource Statistics in the Baltic Sea" Remote Sensing 3, no. 1: 117-144. https://doi.org/10.3390/rs3010117

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