1 / 13

Uncertainty Analyses of an Indian Summer Monsoon Model: Methods and Results

Outline Phenomenon, model, aims Methodical approach Monsoon stability under uncertainty Conclusions PIK - Potsdam Institute for Climate Impact Research, Germany http://www.pik-potsdam.de Michael Flechsig & Brigitte Knopf

ostinmannual
Télécharger la présentation

Uncertainty Analyses of an Indian Summer Monsoon Model: Methods and Results

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Outline Phenomenon, model, aims Methodical approach Monsoon stability under uncertainty Conclusions PIK - Potsdam Institute for Climate Impact Research, Germany http://www.pik-potsdam.de Michael Flechsig & Brigitte Knopf Uncertainty Analyses of an Indian Summer Monsoon Model: Methods and Results

  2. ITCZ N-Summer Equator ITCZ N-Winter © Paul R. Baumann State University of New York The Indian Monsoon • Semi-annual shift of the intertropical convergence zone ITCZ in conjunction with Temperature gradients in the atmosphere between land surface and ocean lead toIndian Monsoon: wet summers and relatively dry winters over the Indian sub-continent • Economic implications of the monsoon stability for India: • Agriculture accounts for 25% of the GDP • Agriculture employs 70% of the population

  3. Stratosphere Tibetan Plateau stable states instable states Indian Ocean Indian Ocean (20N , 75W) LandSurface 2 Soil Layers instable stable stable present value The Model(Zickfeld et al., GRL 32, 2005) • One-dimensional (idealised) box model of the tropical atmosphere over India with about 60 parameters for qualitative studies • Prognostic state variables • Air temperature • Specific air humidity • Moisture in two soil layers • Drivers: boundary conditions for • Air temperature • Air humidity • Cloudiness • For the summer monsoon the model shows a saddle node bifurcationagainst parameters that govern the heat budget • Atmospheric CO2 concentration • Solar insolation • Albedo As of the land surface(AS for broad-leafed trees = 0.12, for desert = 0.30)

  4. Aims and Applied Methods • Study the stability of the Indian summer monsoon under potential land use and climate change • Determine robustness of the bifurcation at SN1against the surface albedo AS under parameter uncertainty • Consider three parameter / initial value spaces (all without parameter As) • T38 the total space of all 38 uncertain parameters:determine most important parameters • S5 a 5-dimensional subspace of the most influential parameters: study parameter sensitivity • A5 a 5-dimensional subspace of anthropogenically influenceable parameters: get implications of potential climate change • Applied methods and used tools: • Combine a qualitative analysis (QA) of a model (“bifurcation analysis”)AUTO (Doedel, 1981) • with multi-run model sensitivity and uncertainty analysesSimEnv (Flechsig et al., 2005)

  5. ExperimentPerformance ExperimentPostprocess. OriginalModel InterfacedModel ExperimentPreparation ResultEvaluation Multi-Run SimEnv Approach • Consider Y = F(X) SN1 = QA ( model ( [ T38 | S5 | A5 ] ) ) • X factor space: model parameters, initial values, boundary values, drivers • Y model output (multi-dimensional, large volume) • Apply deterministic and random sampling techniques in the multi-factor space Xto study model sensitivity and uncertainty of model output Y multi-run experiments • Simple model interface to SimEnv for factors X and model output Y “Include for each factor and for each model output field one SimEnv function call into the model source code” • at programming language level: C/C++ Fortran Python • at modelling language level: MatLab Mathematica GAMS • at shell script level

  6. x2 x1 assessment strategy SimEnv Experiment Types • SimEnv provides generic multi-run simulation experiment typesthat differ in their sampling strategies • To generate a sample in the factor space under study a selected experiment type has to be equipped with numerical information o = default value x = 1 single run x = 2nd sample

  7. Monsoon Model Uncertainty Analyses Model interface: Experiments: • Global sensitivity analysis in T38 • Behavioural analysis in S5 • Monte Carlo analysis in T38 and A5

  8. k=2 factors p=5 levelsNTraject=4 trajectoriestrajectory σ nonlinear effect on model output  μabs sensitivity w.r.t. model output  Morris’ Design (1991)model free • Modified by Campolongo et al. (2005) • Grid factor space x = (x1 ,…, xk) with p levels for each factor and constant grid widths Δi (i=1,…,k) • Define a local elementary effect di of xifrom two grid points in xthat differ only in one factor xi by Δi bydi := Y(x+eiΔi) - Y(x) • Select randomly NTraject trajectories of length k (from k+1 points) where exactly one elementary effect dij (j=1,…,NTraject) can be derived from two consecutive points • Consider distributions Fiabs = { |dij| } and compute μiabs = mean of Fiabs Fi = { dij } and compute σi = standard deviation of Fi Interpretation: • high μiabs :factor xi has an important overall influence on model output Y • high σi:factor xi is involved in interactions with other factors w.r.t. Yoreffect of factor xi on Y is nonlinear

  9. σ -nonlinear effects with respect to SN1 μabs - sensitivity with respect to SN1 Global Sensitivity Analysis • Morris’ design for all 38 parameters T38 • p = 7-level grid for the variation rangesof the 38 parameters • NTraject = 1,000 trajectories • Resulting in 39,000 single model runs • 93.1% of all runs show a bifurcation • Some outstanding parameters and one cluster S5most influential parameters A5anthropogenically influenceable parameters

  10. Maximum value Asat the bifurcation pointover the 5*5 single runs of the two dimensions that are not shown rank 1 rank 5 Behavioural Analysis • Deterministic screening exercise for the 5 most sensitive parameters S5 • for deep insight into the model • 5 equidistant values per parameterin its variation range result in 55 single model runs • All runs show a bifurcation • Most sensitive parameters show largest variation

  11. T38 A5 value without uncertainty present value Monte Carlo Analyses • For all 38 parameters T38 and the 5 anthropogenic parameters A5 • Uniform marginal distributions on their variation ranges • Latin hypercube sampling • 20,000 single model runs • 94.4% of all runs in T38,all runs in A5show a bifurcation • According to the model it is not likelythat the system reaches the bifurcation point under influence of human activity • Variation of As for T38 at the bifurcation point SN1 is the same as variation of As for current vegetation

  12. Conclusions Methods: • Combination of a bifurcation analysis with multi-parameter uncertainty studies enabled qualitative considerations for the whole parameter space • SimEnv as a multi-run simulation environment with the focus on model sensitivity and uncertainty studies Model results: • Bifurcation for surface albedo in the model is robust under parameter uncertainty though the value of the bifurcation point varies • The present state of the system is far away from the variability range of the bifurcation point • More detailed studies are necessaryExample: • System: air pollutants  aerosols  optical thickness of stratum clouds • Model: parameter τst bifurcation point for surface albedo

  13. Thank you for your Attention SimEnv on the Internet: http://www.pik-potsdam.de/software/simenv

More Related