> JI \pJava Excel API v2.6.10 Ba==h\:#8X@"1Arial1Arial1Arial1Arial  + ) , * `fZUnknown, 2RankNameURL1jNumerical study of a timedomain finite element method for nonlinear magnetic problems in three dimensionsnhttps://experts.illinois.edu/en/publications/numericalstudyofatimedomainfiniteelementmethodfornonlin2PParallel FETIDP for efficient em analysis of general objects and antenna arraysnhttps://experts.illinois.edu/en/publications/parallelfetidpforefficientemanalysisofgeneralobjectsand3nParallelized multilevel fast multipole algorithm for scattering by objects with anisotropic impedance surfacesnhttps://experts.illinois.edu/en/publications/parallelizedmultilevelfastmultipolealgorithmforscatteringb4GRobust domain decomposition methods for modeling of large phased arraysnhttps://experts.illinois.edu/en/publications/robustdomaindecompositionmethodsformodelingoflargephased5rTheoretical formulation of a timedomain finite element method for nonlinear magnetic problems in three dimensionsnhttps://experts.illinois.edu/en/publications/theoreticalformulationofatimedomainfiniteelementmethodfo6STimedomain finite element modeling of nonlinear conductivity using Newton's methodnhttps://experts.illinois.edu/en/publications/timedomainfiniteelementmodelingofnonlinearconductivityusi7^Timedomain nonlinear finite element analysis of air breakdown using a simplified plasma modelnhttps://experts.illinois.edu/en/publications/timedomainnonlinearfiniteelementanalysisofairbreakdownus8YTransient electricalthermal Cosimulation in the design of onchip and 3D interconnectsnhttps://experts.illinois.edu/en/publications/transientelectricalthermalcosimulationinthedesignofonch9PAcceleration of the dualfield domain decomposition algorithm using GPU clustersnhttps://experts.illinois.edu/en/publications/accelerationofthedualfielddomaindecompositionalgorithmusi10mAcceleration of the dualfield domain decomposition algorithm using MPICUDA on largescale computing systemsphttps://experts.illinois.edu/en/publications/accelerationofthedualfielddomaindecompositionalgorithmusi211BAcceleration of the finite element method using hybrid OpenMPCUDAnhttps://experts.illinois.edu/en/publications/accelerationofthefiniteelementmethodusinghybridopenmpcud12dAccurate and efficient simulation of scattering by large objects with anisotropic impedance surfacesnhttps://experts.illinois.edu/en/publications/accurateandefficientsimulationofscatteringbylargeobjects13]A FETIDP method enhanced with secondorder transmission condition for antenna array analysisnhttps://experts.illinois.edu/en/publications/afetidpmethodenhancedwithsecondordertransmissionconditio14sA finiteelementbased domain decomposition method for efficient simulation of nonlinear electromechanical problemsnhttps://experts.illinois.edu/en/publications/afiniteelementbaseddomaindecompositionmethodforefficient15UA GPUaccelerated integralequation solution for largescale electromagnetic problemsnhttps://experts.illinois.edu/en/publications/agpuacceleratedintegralequationsolutionforlargescaleelec16eA hybrid conformal/nonconformal domain decomposition method for multiregion electromagnetic modelingnhttps://experts.illinois.edu/en/publications/ahybridconformalnonconformaldomaindecompositionmethodformu17xAn accurate and efficient finite elementboundary integral method with GPU acceleration for 3D electromagnetic analysisnhttps://experts.illinois.edu/en/publications/anaccurateandefficientfiniteelementboundaryintegralmethod18LAn FEBIMLFMA with GPU acceleration for electromagnetic scattering analysisnhttps://experts.illinois.edu/en/publications/anfebimlfmawithgpuaccelerationforelectromagneticscatteri19A nonconformal FEMDDM with treecotree splitting and improved transmission condition for modeling subsurface detection problemsnhttps://experts.illinois.edu/en/publications/anonconformalfemddmwithtreecotreesplittingandimprovedtr20AA nonconformal FETI method with a reduced global interface < systemnhttps://experts.illinois.edu/en/publications/anonconformalfetimethodwithareducedglobalinterfacesystem21pA nonuniform timestepping scheme for nonlinear electromagnetic analysis using timedomain finite element methodnhttps://experts.illinois.edu/en/publications/anonuniformtimesteppingschemefornonlinearelectromagnetica22pApplication of an oblique absorbing boundary condition in the finite element simulation of phasedarray antennasnhttps://experts.illinois.edu/en/publications/applicationofanobliqueabsorbingboundaryconditioninthefin23A preconditioned dualprimal finite element tearing and interconnecting method for solving 3D timeharmonic Maxwell's equationsnhttps://experts.illinois.edu/en/publications/apreconditioneddualprimalfiniteelementtearingandinterconn24A preconditioned dualprimal finite element tearing and interconnecting method for solving threedimensional timeharmonic Maxwell's equationsphttps://experts.illinois.edu/en/publications/apreconditioneddualprimalfiniteelementtearingandinterconn225[Combining secondorder transmission condition with lagrange multiplierbased FETIDP methodnhttps://experts.illinois.edu/en/publications/combiningsecondordertransmissionconditionwithlagrangemulti26VElectricalthermal cosimulation for DC IRdrop analysis of largescale power deliveryphttps://experts.illinois.edu/en/publications/electricalthermalcosimulationfordcirdropanalysisoflarge227SFast and accurate analysis of scattering from anisotropic surface impedance objectsnhttps://experts.illinois.edu/en/publications/fastandaccurateanalysisofscatteringfromanisotropicsurface28Fast and accurate finite element analysis of largescale threedimensional photonic devices with a robust domain decomposition methodnhttps://experts.illinois.edu/en/publications/fastandaccuratefiniteelementanalysisoflargescalethreedi29`Finiteelement domain decomposition methods for analysis of largescale electromagnetic problemsnhttps://experts.illinois.edu/en/publications/finiteelementdomaindecompositionmethodsforanalysisoflarge30GGPU accelerated finiteelement computation for electromagnetic analysisnhttps://experts.illinois.edu/en/publications/gpuacceleratedfiniteelementcomputationforelectromagnetican31NIncorporating specific absorption rate constraints into wireless signal designnhttps://experts.illinois.edu/en/publications/incorporatingspecificabsorptionrateconstraintsintowireless32^Modal expansion approach for accurately computing resonant modes in a highQ optical resonatornhttps://experts.illinois.edu/en/publications/modalexpansionapproachforaccuratelycomputingresonantmodes33KMultiscale modeling of an aircraft coated with complex composite materialsnhttps://experts.illinois.edu/en/publications/multiscalemodelingofanaircraftcoatedwithcomplexcomposite34Plane wave discontinuous galerkin method with lagrange multipliers for solving timeHarmonic Maxwell's equations in three dimensionsnhttps://experts.illinois.edu/en/publications/planewavediscontinuousgalerkinmethodwithlagrangemultiplier35[Thermalaware highfrequency characterization of largescale throughsiliconvia structuresnhttps://experts.illinois.edu/en/publications/thermalawarehighfrequencycharacterizationoflargescalethro36STimedomain finite element analysis of ferromagnetic hysteresis in three dimensionsnhttps://experts.illinois.edu/en/publications/timedomainfiniteelementanalysisofferromagnetichysteresisi37lTransient electricalthermal analysis of 3D power distribution network with FETIEnabled parallel computingphttps://experts.illinois.edu/en/publications/transientelectricalthermalanalysisof3dpowerdistributionn238WAccuracy improvement of the secondkind integral equations for generally shaped objectsnhttps://experts.illinois.edu/en/publications/accuracyimprovementofthesecondkindintegralequationsforge39ZAccurate and highly convergent solution of integral equations for electromagnetic pro<blemsnhttps://experts.illinois.edu/en/publications/accurateandhighlyconvergentsolutionofintegralequationsfor40nA CUDA implementation of the finite elementboundary integral method for electromagnetic scattering simulationnhttps://experts.illinois.edu/en/publications/acudaimplementationofthefiniteelementboundaryintegralmet41A dualprimal finiteelement tearing and interconnecting method combined with treecotree splitting for modeling electromechanical devicesnhttps://experts.illinois.edu/en/publications/adualprimalfiniteelementtearingandinterconnectingmethodc42WA fast 3D fullwave inverse method implemented within a domain decomposition frameworknhttps://experts.illinois.edu/en/publications/afast3dfullwaveinversemethodimplementedwithinadomaind43nA hybrid nonconformal FETI/conformal FETIDP method for arbitrary nonoverlapping domain decomposition modelingnhttps://experts.illinois.edu/en/publications/ahybridnonconformalfeticonformalfetidpmethodforarbitrary44VAnalysis of nonlinear electromagnetic problems using timedomain finite element methodnhttps://experts.illinois.edu/en/publications/analysisofnonlinearelectromagneticproblemsusingtimedomain45oAn efficient domain decomposition method for 3D finite element analysis of nonlinear electric machine problemsnhttps://experts.illinois.edu/en/publications/anefficientdomaindecompositionmethodfor3dfiniteelementa46An OpenMPCUDA implementation of multilevel fast multipole algorithm for electromagnetic simulation on multiGPU computing systemsnhttps://experts.illinois.edu/en/publications/anopenmpcudaimplementationofmultilevelfastmultipolealgori47jA novel secondorder transmission condition for a fast convergent nonconformal FEMDDM at any frequenciesnhttps://experts.illinois.edu/en/publications/anovelsecondordertransmissionconditionforafastconvergent48~Application of the LU recombination method to the FETIDP method for solving lowfrequency multiscale electromagnetic problemsnhttps://experts.illinois.edu/en/publications/applicationofthelurecombinationmethodtothefetidpmethod49VA selfdual integral equation for solving em scattering from PEC, PMC, and IBC objectsnhttps://experts.illinois.edu/en/publications/aselfdualintegralequationforsolvingemscatteringfrompec50;A twolevel nested FETI/FETIDP domain decomposition methodghttps://experts.illinois.edu/en/publications/atwolevelnestedfetifetidpdomaindecompositionmethodj".
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