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Wind poWer information kit

Contents

Wind powerInformation Kit

■ WorkfLoWs for technicaL computing and modeL-Based design

■ user stories

■ technicaL articLes

■ on-demand WeBinars

■ demo videos

■ keY products

■ additionaL energY segments

www.mathworks.com © 2010 The MathWorks, Inc. MATLAB and Simulink are registered trademarks of The MathWorks, Inc. See www.mathworks.com/trademarks for a list of additional trademarks. Other product or brand names may be trademarks or registered trademarks of their respective holders.

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Wind poWer information kit

4 MATLAB Digest | academic edit ionwww.mathworks.com

Wind poWer information kit

Workflow for Technical Computing

harnessing one of the most abundant resources on earth requires the coordination of many disciplines. With mathWorks technical computing software, power engineers can:•Analyzeandpredictwindconditionstooptimizewindfarmsites•Monitorandprocessdatatoensurewindturbineavailability

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Data Analysis & Modeling

Algorithm Development

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Application Development

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Option 1

Option 2

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Access

Databases

Hardware

Explore & Discover Share

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PDF

Reporting andDocumentation

Outputs for Design

Deployment

Files

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Wind poWer information kit

Workflow for Model-Based Design

harnessing one of the most abundant resources on earth requires the coordination of many disciplines. With mathWorks software for model-Based design, power engineers can:•Determinethepropervoltagecompensationtousewindfarmsintotheelectricgrid•Developnext-generationwindturbines

INTEGRATION

IMPLEMENTATION

Environmental Models

Physical Components

Algorithms

DESIGN

C, C++ VHDL, Verilog

StructuredText

MCU DSP FPGA ASIC PLC/PAC

RESEARCH REQUIREMENTS

TEST AN

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ERIFICA

TION

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Wind poWer information kit

User Stories

■ Horizon Wind Energy Develops Revenue Forecasting and Risk Analysis Tools for Wind Farms

■ UNION FENOSA Predicts Energy Supply and Demand Using MathWorks Tools

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Wind poWer information kit

Technical Articles

■ Modeling Flexible Bodies in SimMechanics

Inthisarticle,SimMechanicsisusedtoapplythetwomostcommonflex-iblebodyapproximationmethodstomodelingbeams:thelumped-parameterapproximationandthestatespace/frequencyresponsemethodusingfiniteelement analysis (fea) results. Both methods assume that beam deflection is small and in the linear regime.

■ Simulating Mechanical Systems with SimMechanics Thispapersystematicallypresentsthemathematicalandsoftwaredevelopmentsneeded for efficient simulation of mechanical systems in simulink.

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Wind poWer information kit

4 MATLAB Digest | academic edit ionwww.mathworks.com

On-Demand Webinars

■ Applied Data Analysis Using MATLAB: “Catching the Wind” LearnhowtouseMATLABfordataanalysisfromdataaccessthroughvisualizationand modeling. using measured wind data for wind farm siting, mathWorks engi-neers will demonstrate the use of matLaB and data analysis products for the entire data analysis and modeling process.

■ Developing Wind Power Systems Using MathWorks Tools

Learnhowdevelopingwindturbinesinasinglesimulationenvironmentcanoffersignificantimprovementsoveratraditionaldevelopmentprocess.MathWorksengineers will demonstrate how to model a complete wind turbine including mechanical, electrical and hydraulic systems using model-Based design. presented infourmodules,theseriescovers:

•Model-BasedDesignofaWindTurbine

•DeterminingMechanicalLoadsforWindTurbines

•DesigningPitchandYawActuatorsforWindTurbines

•DesigningControlSystemsforWindTurbines

■ Investigating Reactive Power Management of Mixed-Technology Wind Farms Using Modeling and Simulation

mathWorks engineers will demonstrate how modeling and simulation allows effectiveinvestigationofreactivepowermanagementwithinthecontextofamixed-technology wind farm, with consideration of squirrel-cage and dfig wind turbines. Thedemonstrationwillconsidermodelabstractiontechniquestoimprovesimulationspeed,includingtheuseofaverage-valuepower-electronicconvertersandaggre-gated wind turbine representations.

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Wind poWer information kit

4 MATLAB Digest | academic edit ionwww.mathworks.com

Demo Videos

■ Integrating Physical Systems and Controller

Detectintegrationissueswhendevelopingawindturbine.Modelsofmechanical,hydraulic, electrical, and control systems are gradually integrated into a system-levelmodelofawindturbine,enablingengineerstotestsystemsinisolationandtotestoverallsystemperformance.

■ Analyzing and Documenting Results

automatically run tests on a wind turbine model and generate a report document-ing simulation results. simulink report generator™isusedtoruntests,evaluateperformance, and capture screenshots of the model and simulation results into a document.

■ Optimizing System Performance

Useoptimizationalgorithmstoautomaticallytunetheperformanceofahydro mechanical pitch control system in a wind turbine until it meets system requirements.

■ Real-Time Simulation of a Hydromechanical Pitch Actuation System

Evaluatetheperformanceofahydromechanicalsystemusingreal-timesimulationbeforevalidatingitwithhardwareprototypes.Real-timesimulationoffersacost-effectivewaytotestcontrolstrategiesagainstrealisticplantmodels.

■ Real-Time Testing Blade Pitch Control Systems Using Hardware-in-the-Loop (HIL)

use hiL testing instead of hardware prototypes to test control algorithms. a simulink model of a wind turbine built with mathWorks physical modeling tools isconvertedtoCcodeanddownloadedontoBachmannelectronicM1hardwarecontroller.

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Key Products for Technical Computing

■ MATLAB

The Language of Technical Computing

matLaB®isahigh-levellanguageandinteractiveenvironmentthatenablesyoutoperformcomputationallyintensivetasksfasterthanwithtraditionalprogramminglanguages such as c, c++, and fortran.

■ Statistics Toolbox

Perform statistical analysis, modeling, and algorithm development

StatisticsToolbox™providesacomprehensivesetoftoolstoassessandunderstanddata.StatisticsToolboxincludesfunctionsandinteractivetoolsformodelingdata,analyzinghistoricaltrends,simulatingsystems,developingstatisticalalgorithms,and learning and teaching statistics.

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Key Products for Technical Computing

■ Curve Fitting Toolbox

Fit curves and surfaces to data using regression, interpolation, and smoothing

CurveFittingToolbox™providesgraphicaluserinterfaces(GUIs)andcommand-linefunctionsforfittingcurvesandsurfacestodata.Thetoolboxletsyouperformexploratorydataanalysis,preprocessandpost-processdata,comparecandidatemodels,andremoveoutliers.Youcanconductregressionanalysisusingthelibraryoflinearandnonlinearmodelsprovidedorspecifyyourowncustomequations.Thetoolboxalsosupportsnonparametricmodelingtechniques,suchasinterpola-tion and smoothing.

■ MATLAB Compiler

Build standalone executables and software components from MATLAB code

matLaB compiler™letsyoushareyourMATLABapplicationasanexecutableorasharedlibrary.ExecutablesandlibrariescreatedwiththeMATLABCompilerproduct use a runtime engine called the matLaB compiler runtime (mcr). the MCRisprovidedwithMATLABCompilerfordistributionwithyourapplicationandcan be deployed royalty-free.

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Key Products for Model-Based Design

■ Simulink

Simulation and Model-Based Design

simulink®isanenvironmentformultidomainsimulationandModel-BasedDesignfordynamicandembeddedsystems.Itprovidesaninteractivegraphicalenvi-ronmentandacustomizablesetofblocklibrariesthatletyoudesign,simulate,implement,andtestavarietyoftime-varyingsystems,includingcommunications,controls,signalprocessing,videoprocessing,andimageprocessing.

■ Simscape

Model and simulate multidomain physical systems

simscape™extendsSimulinkwithtoolsformodelingsystemsspanningmechanical,electrical,hydraulic,andotherphysicaldomainsasphysicalnetworks.Itprovidesfundamental building blocks from these domains to let you create models of customcomponents.TheMATLABbasedSimscapelanguageenablestext-basedauthoring of physical modeling components, domains, and libraries.

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Key Products for Model-Based Design

■ SimMechanics

Model and simulate mechanical systems

simmechanics™ extendsSimscapewithtoolsformodelingthree-dimensionalmechanical systems within the simulink environment.Insteadofderivingandpro-gramming equations, you can use this multibody simulation tool to build a model composed of bodies, joints, constraints, and force elements that reflects the struc-tureofthesystem.Anautomaticallygenerated3Danimationletsyouvisualizethesystem dynamics. You can import models complete with mass, inertia, constraint, and3DgeometryfromseveralCADsystems.

■ SimPowerSystems

Model and simulate electrical power systems

simpowersystems™extendsSimulinkwithtoolsformodelingandsimulatingthegeneration, transmission, distribution, and consumption of electrical power. it pro-videsmodelsofmanycomponentsusedinthesesystems,includingthree-phasemachines,electricdrives,andlibrariesofapplication-specificmodelssuchasFlexibleACTransmissionSystems(FACTS)andwind-powergeneration.Harmonicanalysis, calculation of total harmonic distortion (thd), load flow, and other key power system analyses are automated. simpowersystems models can be dis-cretizedtospeedupsimulations.

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Wind poWer information kit

Additional Energy Segments

engineers and scientists worldwide rely on mathWorks software to perform the challenginganalysis,simulation,andproductdevelopmenttasksnecessarytoaddresstheworld’senergyneeds.YoucanuseMATLABandSimulinktoevaluateenergyresources,developsystemsforpowergenerationanddistribution,modelenergymarkets,andcreateproductsthatconsumelessenergyandareenvironmen-tally friendly.

Electric Utilities

Oil and Gas

Trading and Risk

Solar Power

Wind Power

Electric Vehicles