GASP Global: Difference between revisions

From Wiki-WindPRO
Jump to navigation Jump to search
 
(34 intermediate revisions by the same user not shown)
Line 15: Line 15:
** ''Vertical'': 50m, 100m and 150m as vertical levels
** ''Vertical'': 50m, 100m and 150m as vertical levels
* '''Data-type:''' [[:Category%3AAtlas_Data|Atlas]]
* '''Data-type:''' [[:Category%3AAtlas_Data|Atlas]]
* '''Reference period:''' 10 years (2008-2017)
* '''Coordinate system:''' Geographical coordinates (EPSG: 4326) in original data
* '''Coordinate system:''' Geographical coordinates (EPSG: 4326) in original data
* '''Version:''' 1.0
* '''Version:''' 1.0


== Usage Notes ==
== Validation and Usage Notes ==
* '''Need turbulence intensity instead of the GASP windspeed standard deviations?''' We have prepared a small pdf that describes how to convert to turbulence intensity and to use the two paramsters (A) and (B) to derive the turbulence intensity at any wind speed - read more here [https://help.emd.dk/mediawiki/images/4/43/20210806_TurbulenceFromGASPdata.pdf HERE].
* '''How accurate is your resource prospecting based on GASP data in windPRO or windPROSPECTING? '''<br>We have prepared a small validation note - based on data from 241 high quality meteorological towers - that gives you a first hint on bias and uncertainty - read more - [https://help.emd.dk/mediawiki/images/f/fc/20210903_AccuracyGASPWindSpeeds.pdf HERE].
* '''Need turbulence intensity instead of the GASP windspeed standard deviation?''' <br>We have prepared a small pdf that describes how to convert from wind speed standard deviations to turbulence intensities - and how to use the two model parameters (A) and (B) to derive the turbulence intensity at any wind speed - read more - [https://help.emd.dk/mediawiki/images/4/43/20210806_TurbulenceFromGASPdata.pdf HERE].
* '''How is the GASP shear calculated?'''<br>The shear values from GASP are estimated using the DTU-LINCOM flow model. According to DTU, this was the best "local" source of shear given the models available during development of the GASP dataset (neutral atmospheric stability assumed, so the reported GASP shear is representative for "higher" wind speeds). Another option would have been to estimate the shear using the WAsP model (with default or custom-specified atmospheric stability parameters). However, if you are interested in "WAsP-shear" values, it is perfectly possible to derive those directly (but manually) from existing GASP  annual average wind speeds in 50m, 100m and 150m [parameter: wsp]. The "WAsP-shear" is currently not included in the GAsP dataset version 1.0, but under consideration for a future dataset update.


== Availability from EMD's software ==
== Availability from EMD's software ==
Line 31: Line 34:
== Parameters and Dimensions ==
== Parameters and Dimensions ==
As seen from the tables below, a very wide range of omnidirectional and sectorwise parameters are available from GASP. These parameters are divided into four main categories:
As seen from the tables below, a very wide range of omnidirectional and sectorwise parameters are available from GASP. These parameters are divided into four main categories:
# Wind Resources / Atmospheric Parameters
* Wind Resources / Atmospheric Parameters
# Siting Parameters – Fatigue
* Siting Parameters – Fatigue
# Siting Parameters – Extremes  
* Siting Parameters – Extremes  
# Turbine Design Classification - with recommended turbine class
* Turbine Design Classification - with recommended turbine class. 3 separate aeroelastic models are used as representative for the 3 heights
** 50m: WindPACT 1.5MW
** 100m: NREL 5MW
** 150m: DTU 10MW
The tables below provides an overview of all parameters available and at which dimensions that they are available. We have used the following dimensions for the GASP parameters: The first four (longitude, latitude, height and sector) are used for the basic parameters; the last three (ws_class, iec_class and turbine_component) are used for the turbine design classification - and are releated to the IEC61400-1 code and the aeroelastic load model. Please note that not all dimensions are relevant or used for every GASP parameter.
The tables below provides an overview of all parameters available and at which dimensions that they are available. We have used the following dimensions for the GASP parameters: The first four (longitude, latitude, height and sector) are used for the basic parameters; the last three (ws_class, iec_class and turbine_component) are used for the turbine design classification - and are releated to the IEC61400-1 code and the aeroelastic load model. Please note that not all dimensions are relevant or used for every GASP parameter.
{| class="wikitable"
{| class="wikitable"
Line 153: Line 159:
|-
|-
|elevation
|elevation
|Air density (annual mean/average)
|Terrain Elevation
|kg/m3
|m
|lon, lat, h
|lon, lat
|}
|}


Line 214: Line 220:
|lon, lat, h
|lon, lat, h
|-
|-
|sigma_P90A
|sigma_P90A<ref name="SigmaTurbulence">Note: This parameter is windspeed standard deviation. It can be converted into a turbulence intensity - see more at the usage note section above. </ref>
|Turbulence slope parameter from IEC 61400-1 (ed4) – P90
|Turbulence slope parameter from IEC 61400-1 (ed4) – P90
|
|
|lon, lat, h
|lon, lat, h
|-
|-
|sigma_P90B
|sigma_P90B<ref name="SigmaTurbulence" />
|Turbulence offset parameter from IEC 61400-1 (ed4) – P90
|Turbulence offset parameter from IEC 61400-1 (ed4) – P90
|m/s
|m/s
Line 252: Line 258:
|lon, lat, h, s
|lon, lat, h, s
|-
|-
|sigma_meanA
|sigma_meanA<ref name="SigmaTurbulence" />
|Turbulence slope parameter from IEC 61400-1 (ed4) – Mean
|Turbulence slope parameter from IEC 61400-1 (ed4) – Mean
|m/s
|m/s
|lon, lat, h, s
|lon, lat, h, s
|-
|-
|sigma_meanB
|sigma_meanB<ref name="SigmaTurbulence" />
|Turbulence offset parameter from IEC 61400-1 (ed4) – Mean
|Turbulence offset parameter from IEC 61400-1 (ed4) – Mean
|m/s
|m/s
|lon, lat, h, s
|lon, lat, h, s
|-
|-
|sigma_P90A
|sigma_P90A<ref name="SigmaTurbulence" />
|Turbulence slope parameter from IEC 61400-1 (ed4) – P90
|Turbulence slope parameter from IEC 61400-1 (ed4) – P90
|
|
|lon, lat, h, s
|lon, lat, h, s
|-
|-
|sigma_P90B
|sigma_P90B<ref name="SigmaTurbulence" />
|Turbulence offset parameter from IEC 61400-1 (ed4) – P90
|Turbulence offset parameter from IEC 61400-1 (ed4) – P90
|m/s
|m/s
Line 376: Line 382:
The data is available through a [https://creativecommons.org/licenses/by/4.0/ Creative commons 4.0 by attribution license] (CC BY 4.0). <br>Please accept the license conditions and use a proper attribution when using this dataset, such as:  
The data is available through a [https://creativecommons.org/licenses/by/4.0/ Creative commons 4.0 by attribution license] (CC BY 4.0). <br>Please accept the license conditions and use a proper attribution when using this dataset, such as:  
<pre>
<pre>
GASP 1.0, by EMD and DTU, is a free dataset accessible via windprospecting.com, windPRO and EMD-API.
GASP 1.0: Global Atlas of Siting Parameters 1.0 by EMD and DTU, is a free dataset accessible via  
EMD (windprospecting.com, windPRO & EMD-API) and DTU (globalwindatlas.info, science.globalwindatlas.info & data.dtu.dk).
License: CC-BY-4.0
</pre>
</pre>


Line 384: Line 392:


== External Links & References ==
== External Links & References ==
* GASP Project Home-Page at DTU - [https://windenergy.dtu.dk/english/research/research-projects/gasp here]
* GASP Project Home-Page at DTU - [https://wind.dtu.dk/projects/Research-Projects/Completed-projects/GASP here]
* A peer-reviewed paper is being prepared and will be referenced here as the main reference for the GASP methods and technologies
* An open-access, peer-reviewed paper is available from the Wind Energy Journal: <br>[https://onlinelibrary.wiley.com/doi/10.1002/we.2771 The Global Atlas for Siting Parameters project: Extreme wind, turbulence, and turbine classes] by Xiaoli Guo Larsén, Neil Davis, Ásta Hannesdóttir, Mark Kelly, Lasse Svenningsen, René Slot, Marc Imberger, Bjarke Tobias Olsen and. Rogier Floors.
* GASP data is available from the Global Wind Atlas App (from version 3.3) - [https://globalwindatlas.info/en here]
* GASP data from DTU data portal - [https://data.dtu.dk/articles/dataset/Global_Atlas_of_Siting_Parameters_V1/14753349 here]
 
== Footnotes ==
<references/>

Latest revision as of 11:05, 21 May 2024

Spatial coverage of the GASP-Global datasets.

Introduction

"GASP Global" is short for "GASP 1.0 - Global of Atlas of Siting Parameters". It is released with windPRO 3.5+ as a global atlas dataset with the following key features:

  • Global 250m wind resources, siting parameters & turbine design classification
  • Builds on DTU GWA (Global Wind Atlas) datasets and EMD's Load Response technology
  • A joint project by EMD and DTU

Dataset Overview

  • Spatial coverage:
    • Onshore: Near global (all land areas from N80 to S58)
    • Offshore: Areas are covered up to 200 km from the coastline
  • Resolution:
    • Horizontal: 250m in grid resolution
    • Vertical: 50m, 100m and 150m as vertical levels
  • Data-type: Atlas
  • Reference period: 10 years (2008-2017)
  • Coordinate system: Geographical coordinates (EPSG: 4326) in original data
  • Version: 1.0

Validation and Usage Notes

  • How accurate is your resource prospecting based on GASP data in windPRO or windPROSPECTING?
    We have prepared a small validation note - based on data from 241 high quality meteorological towers - that gives you a first hint on bias and uncertainty - read more - HERE.
  • Need turbulence intensity instead of the GASP windspeed standard deviation?
    We have prepared a small pdf that describes how to convert from wind speed standard deviations to turbulence intensities - and how to use the two model parameters (A) and (B) to derive the turbulence intensity at any wind speed - read more - HERE.
  • How is the GASP shear calculated?
    The shear values from GASP are estimated using the DTU-LINCOM flow model. According to DTU, this was the best "local" source of shear given the models available during development of the GASP dataset (neutral atmospheric stability assumed, so the reported GASP shear is representative for "higher" wind speeds). Another option would have been to estimate the shear using the WAsP model (with default or custom-specified atmospheric stability parameters). However, if you are interested in "WAsP-shear" values, it is perfectly possible to derive those directly (but manually) from existing GASP annual average wind speeds in 50m, 100m and 150m [parameter: wsp]. The "WAsP-shear" is currently not included in the GAsP dataset version 1.0, but under consideration for a future dataset update.

Availability from EMD's software

Wind Resouces in 100m height at Lillgrunden, Sweden. GASP data accessed through windPRO 3.5.
50yr Extreme Wind Speeds in 100m height at Tasmania, Australia. GASP data accessed through http://www.windPROSPECTING.com platform.
50yr Extreme Wind Speeds in 100m height at Danish Offshore Wind Farms. GASP data accessed through the EMD-API platform, http://api.emd.dk
  • windPRO: In 'Data' menu click 'Siting parameters (GASP etc)' to access the download tool. Data is loaded into a result layer with a .siteres file acting as the data-container.
    • The .siteres file can be used in PARK, Site Compliance, Load Response and Optimization calculations.
  • windPROSPECTING: GASP data is available through the data-tab named 'Site-prospecting'. Free access to windPROSPECTING - here.
    • windprospecting offers spatial view of omnidirectinal parameters and detailed point-data with directional results and statistics.
  • EMD-API: Read more at the dedicated wiki-page for our Global Atlas Data Services - here. If you are accessing the GASP data from within the EMD-API, you will use the parameter group-names in order to request specific data-packages [resource-omni, resource-sector, siting-extremes, siting-fatigue-omni, siting-fatigue-sector, turbine-fatigue, turbine-fatigue-recommend, turbine-extreme, turbine-extreme-recommend].

Parameters and Dimensions

As seen from the tables below, a very wide range of omnidirectional and sectorwise parameters are available from GASP. These parameters are divided into four main categories:

  • Wind Resources / Atmospheric Parameters
  • Siting Parameters – Fatigue
  • Siting Parameters – Extremes
  • Turbine Design Classification - with recommended turbine class. 3 separate aeroelastic models are used as representative for the 3 heights
    • 50m: WindPACT 1.5MW
    • 100m: NREL 5MW
    • 150m: DTU 10MW

The tables below provides an overview of all parameters available and at which dimensions that they are available. We have used the following dimensions for the GASP parameters: The first four (longitude, latitude, height and sector) are used for the basic parameters; the last three (ws_class, iec_class and turbine_component) are used for the turbine design classification - and are releated to the IEC61400-1 code and the aeroelastic load model. Please note that not all dimensions are relevant or used for every GASP parameter.

Table: List of dimensions in GASP data.
Dimension Abbreviation Unit Range
longitude lon deg 180 to -180
latitude lat deg 90 to -90
height h m 50,100,150
sector s deg 0,30,...,330
ws_class wcl I,II,III,T
iec_class iecc IA+, IA,...IIIC
turbine_component tc 0,1,2,3

Parameters: Wind Resource

The two tables below show the GASP parameters for wind resource data divided in omnidirectional data [resource-omni] and sectorwise data [resource-sector].

Table: Resource / Atmospheric Omni-directional Parameters [resource-omni]
Variable Description Unit Dimensions
weib_A Wind distribution: A (Scale) parameter in Weibull distribution m/s lon, lat, h
weib_k Wind distribution: k (shape) parameter in Weibull distribution lon, lat, h
wsp Wind speed - annual average m/s lon, lat, h
wpd Wind power density – annual average W/m2 lon, lat, h
air_dens Air density (annual mean/average) kg/m3 lon, lat, h
Table: Resource / Atmospheric Sector-wise Parameters [resource-sector]
Variable Description Unit Dimensions
weib_A Wind distribution: A (Scale) parameter in Weibull distribution m/s lon, lat, h, s
weib_k Wind distribution: k (shape) parameter in Weibull distribution lon, lat, h, s
sector_freq Wind distribution: Sector frequency lon, lat, h, s
wsp Wind speed - annual average m/s lon, lat, h, s
wpd Wind power density – annual average W/m2 lon, lat, h, s
air_dens Air density (annual mean/average) kg/m3 lon, lat, h
elevation Terrain Elevation m lon, lat

Parameters: Siting Classification - Wind Extremes

The table below shows the GASP parameters for the extreme event data [siting-extremes]. Please note that this extreme data is only available as omnidirectional parameters.

Table: Siting Parameters – Extremes [siting-extremes]
Variable Description Unit Dimensions
air_dens_p98 Air density at 98th percentile of wind speed kg/m3 lon, lat, h
wsp_50yr 50yr extreme wind speed: Average m/s lon, lat, h
gumbel_alpha 50yr extreme wind speed: Gumbel distribution – alpha parameter m/s lon, lat, h
gumbel_beta 50yr extreme wind speed: Gumbel distribution – beta parameter m/s lon, lat, h

Parameters: Siting Classification - Wind Fatigue Parameters

The two tables below show the GASP parameters for the siting-fatigue parameters - given either omnidirectional or sectorwise data-requests [siting-fatigue-omni, siting-fatigue-sector].

Table: Siting Parameters Omnidirectional – Fatigue [siting-fatigue-omni]
Variable Description Unit Dimensions
shear_exp Wind shear exponent (calculated using LINCOM model) - Mean lon, lat, h
flow_inc Flow inclination (calculated using LINCOM model) deg lon, lat, h
terrain_ic Terrain complexity as defined in IEC 61400-1 standard (ed 4) lon, lat, h
sigma_P90A[1] Turbulence slope parameter from IEC 61400-1 (ed4) – P90 lon, lat, h
sigma_P90B[1] Turbulence offset parameter from IEC 61400-1 (ed4) – P90 m/s lon, lat, h
sigma_P90U15 Turbulence P90 at a fixed windspeed of 15 m/s m/s lon, lat, h
air_dens Air density (annual mean/average) kg/m3 lon, lat, h
Table: Siting Parameters – Fatigue [siting-fatigue-sector]
Variable Description Unit Dimensions
shear_exp Wind shear exponent (calculated using LINCOM model) - Mean lon, lat, h, s
flow_inc Flow inclination (calculated using LINCOM model) deg lon, lat, h, s
sigma_meanA[1] Turbulence slope parameter from IEC 61400-1 (ed4) – Mean m/s lon, lat, h, s
sigma_meanB[1] Turbulence offset parameter from IEC 61400-1 (ed4) – Mean m/s lon, lat, h, s
sigma_P90A[1] Turbulence slope parameter from IEC 61400-1 (ed4) – P90 lon, lat, h, s
sigma_P90B[1] Turbulence offset parameter from IEC 61400-1 (ed4) – P90 m/s lon, lat, h, s

Parameters: Turbine Design – Loads

The four tables below show the GASP parameters for the turbine design classification. The two main groups are fatigue and extreme load cases, divided into four data-groups so requests is possible for turbine load indexes and iec class recommendations: [turbine-fatigue, turbine-fatigue-recommend, turbine-extreme, turbine-extreme-recommend].

Table: Turbine Design – Fatigue [turbine-fatigue]
Variable Description Unit Dimensions
flsidx Load index for the fatigue limit state % lon, lat, h, iecc, tc
flsidx_w Load load index for the fatigue limit state with wakes % lon, lat, h, iecc, tc
tc_woehler Turbine component (tc): Wöhler exponent used lon, lat, h, iecc, tc
tc_name Turbine component (tc): Name lon, lat, h, iecc, tc
tc_sensor Turbine component (tc): Sensor name lon, lat, h, iecc, tc
Table: Turbine Design – Fatigue Recommendations [turbine-fatigue-recommend]
Variable Description Unit Dimensions
iecr_fls_id IEC Class Recommendation – fatigue limit state (FLS) - id lon, lat, h
iecr_fls_txt IEC Class Recommendation – fatigue limit state (FLS) - text lon, lat, h
iecr_flsw_id IEC Recommendation (with wakes) – fatigue limit state (FLS) - id lon, lat, h
iecr_flsw_txt IEC Recommendation (with wakes) – fatigue limit state (FLS) - text lon, lat, h
Table: Turbine Design – Extreme Loading [turbine-extreme]
Variable Description Unit Dimensions
ulsidx Design load index for ultimate limit state (ULS) % lon, lat, h, wcl
Turbine Design – Extreme Recommendations [turbine-extreme-recommend]
Variable Description Unit Dimensions
iecr_uls_id Design load index for ultimate limit state (ULS) lon, lat, h
iecr_uls_txt IEC Class Recommendation – ultimate limit state (ULS) – text lon, lat, h

License and Attribution

The data is available through a Creative commons 4.0 by attribution license (CC BY 4.0).
Please accept the license conditions and use a proper attribution when using this dataset, such as:

GASP 1.0: Global Atlas of Siting Parameters 1.0 by EMD and DTU, is a free dataset accessible via 
EMD (windprospecting.com, windPRO & EMD-API) and DTU (globalwindatlas.info, science.globalwindatlas.info & data.dtu.dk). 
License: CC-BY-4.0

Acknowledgement

  • GASP is the result of a BIG collective effort by many people at: EMD International A/S & DTU Wind Energy, with overall project manager Xiaoli Larsén (DTU)
  • Develoment and integration of this dataset into EMD services was done through the GASP project which is co-funded by the EUDP and the Danish Energy Agency

External Links & References

Footnotes

  1. 1.0 1.1 1.2 1.3 1.4 1.5 Note: This parameter is windspeed standard deviation. It can be converted into a turbulence intensity - see more at the usage note section above.