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1 PEHRPP Workshop Dec. 3, 2007 Geneva GSMaP Passive Microwave Precipitation Retrieval Algorithm Kazumasa Aonashi (MRI/JMA)

2 Passive Microwave Precipitation Retrieval GSMaP Retrieval Algorithm Global Satellite Mapping of Precipitation Project started in Leader: Prof. Ken ich Okamoto (Osaka Pref. Univ.) Funded by JST/CREST The goal is to produce accurate precip map using mainly satellite microwave radiometer. Passive microwave precip retrieval (Aonashi) Passive microwave precip+ IR wind (Dr. Ushio)

3 Outline Introduction Algorithm Description Forward Calculation (precip cloud models) Retrieval Part Validation (TRMM PR, Ground-based Obs.) Future Directions Improvement of Scattering part Summary

4 Algorithm Description Forward Calculation Retrieval Part

Retrieval Calculation Screening Inhomogeneity estimation Scattering part Radiation part Find the

5 Basic Idea of the Retrieval Algorithm Forward calculation Precip Cloud Models FLH Precip Profiles DSD Mixed phase inhomogeneity RTM Look-up Table Observed TBs Precip. Retrieval Calculation Screening Inhomogeneity estimation Scattering part Radiation part Find the optimal precipitation that gives RTM-calculated TBs fitting best with the observed TBs: PCT37, PCT85 (land) TB10v,TB19v, PCT37, PCT85 (sea)

6 Precipitating Cloud Model for forward calculation Stratiform/ Convective Freezing Level Height Frozen Precip Rain Precipitation typ Precipitation Profile model Freezing Level Mixed-phase model Particle Size Distribution Atmosphere & Surfac (GANAL)

7 Parameters used in the Algorithm: Atmospheric & surface variables Atmospheric variables (Temp,FLH), surface variables(ts, SSW, SST) are derived from the Global Analysis data of JMA Temperature bias of GANAL against sonde Freezing Level Height for Jan.1, 2003

1: shower, 2: shallow, 3: frontal rain, 4: organized rain 5: highland (sea) 6: shallow 7:frontal rain, 8:transit,

8 Precip type classification Data base 10 types (land 6, sea 4) are classified from TRMM PR data (2.5 deg, 3 monthly) Precipitation Profile Model Height from 1 deg level [km] Precip Profile 1 level (land) 0: thunderstorm, 1: shower, 2: shallow, 3: frontal rain, 4: organized rain 5: highland (sea) 6: shallow 7:frontal rain, 8:transit, 9:organized rain Precip profile data base Example: TRMM PR averaged preciptation profiles for each type, surface precip, conv/stra Rainfall rate [mm/h]

9 Particle Size Distribution DSD for rain: Kozu model (2A25 average distribution calibrated with averaged epsillon) epsillon =1 for stratiform rain μ N( D) = N0D exp( ΛD) PSD for frozen particles: Marshall-Palmer distribution Data base of conv. Epsillon Averaged for each precip type

10 Nishitsuji (Mixed-Phase) Model for Stratiform Rain On the basis of the filed experiment, the following parameters are modeled Volume liquid water fraction (Pw) ε s 1 ε w 1 ε i 1 ε a 1 = Pw + Pi + Pa shape parameter of the dielectric constant (U) ε + U ε + U ε + U ε + U DSD parameter (B) is a function of Pw Ba 3 1 N( D) = N 010 ( m mm ) (a Density ρ= Pw Fall velocity Magono-Nakamura(1965) for snow and Foot and Du Toit for rain s w i a : radius in cm) Pw and U profile U Relationship between B and Pw Distance below BB (km) U PW B PW

11 where μ = P is LUT calculation (1) TBs for homogeneous precip dtb( τ, μ, ϕ) μ = TB (1 ω0 ) T ( τ ) dτ ω0 ' ' ' ' ' ' P( τ, μ, ϕ, μ, ϕ ) TB( τ, μ, ϕ ) dμ dϕ 4π phase cosθ, τ = function K K dz, ω /( K Radiative Transfer Code (Liu,1998) One-dimensional model (Plane-parallel) Mie Scattering (Sphere) 4 stream approximation Calculate TBs for homogeneous, convective & stratiform precip with each precip types. K ab + sc 0 = sc ab + sc ), K

12 LUT calculation (2): LUTs for inhomo precip The calculated TBs are converted into TBs for inhomogeneous precip with Aonashi and Liu s s method (2000). LUT used for retrieval is weighted average of convective & stratiform TBs. 2.0 LOOK-UP TABLE (LUT) 1.5 STD of Log(Pr) ) is estimated from STD of Log(rain85) statistically. SIGMA *sigma85o SIGMA85O STDLGPRH STD LN(PR) (PCT85ra < 260K)

13 Flow of the Retrieval Part Observed TBs Screening of Precip Areas rain flag Inhomo. Estimation / LUT selection LOOK-UP TABLE (LUT) Inhomogeneity (STD of Log (Pr)) First-guess of Precipitation (scattering) rain37 PCT37+LUT rain85 PCT85+LUT TB10v,TB19v Minimization of Σ(TBc-TBo)**2 Over Ocean Retrivals Over Land Retrievals

14 Validation Comparison with TRMM PR & Ground-based observations

15 Multi-Satellite Precip Composite (GSMaP_MWR, daily precip) TMI+AMSR+AMSR-E+SSM/I (F13, F14, F15),

16 Zonal Mean TRMM Precip over Ocean GSMaP, GPROF, PR (1998~2006) PR 2A25V6 TMI 2A12V6 GSMaP V PR swath only

17 Comparison with ground-based radar (0.25 x 0.25 deg in lat-lon lon grid) COBRA(Okinawa) 4 cases in June 2004 Kwajalein Radar 10 cases in May 2003 Corretation:0.82(No:253) RMSE:1.37 mm/hr Correlation:0.65(No:1139) RMSE:1.78 mm/hr

18 PR 2A25V6 TMI 2A12V6 GSMaP V PR swath only Zonal Mean TRMM Precip over Land GSMaP, GPROF, PR (1998~2006)

Comparison with GPCC data Comparison with GPCC data GSMaP_MWR:monthly mean preciptation (1x1 deg) GPCC Monthly Precipitation (Monitoring) Product

19 Comparison with GPCC data Comparison with GPCC data GSMaP_MWR:monthly mean preciptation (1x1 deg) GPCC Monthly Precipitation (Monitoring) Product (Rudolf et al. 2006): Correlation: 0.80 for 45S~45N (sample: 69440) 0.85 for 15S~15N (sample: 2177) Fitting: y=1.14 x [40S~40N] y=1.21 x [15S~15N]

20 Ratio of TMI scattering signals to PR in terms of precip top level (July, 1998) (Rain37/rainsurf) (Rain85/rainsurf) rain37/rainsurf R 2 乗 = PR DTOP top level FLH (m) rain85/rainsurf R 2 乗 = PR DTOPtop level FLH (m) Precip is over-(under-)estimated for PR high (low) top level. (Rain85/rainsurf) is sensitive to PR top level.

21 Future Directions PSD, densities of frozen particles Scattering properties of Non-spherical particles

22 Estimation of realistic PSD, density etc. PSD (field campaign) RTM simulation Observed Radar & MWR data

Scattering properties of non-spherical frozen particles (Liu, 2004)

to an electric by an field array which of dipoles.

23 Scattering properties of non-spherical frozen particles (Liu, 2004) DDA :Each An of the actual dipoles target is subject is approximated to an electric by an field array which of dipoles. is the sum of the incident wave and the electric fields due to all of the other dipoles. Non- Sphere From Mishchenko et al (2000) Dmax D0: diameter of solid sphere SP=(D-D0)/(Dmax-D0) D Keeping the single scattering properties Sphere

24 Summary GSMaP passive microwave precipitation retrieval algorithm: Atmopheric & surface variables from GANAL Precip profile, DSD & inhomo. from PR statistics Mixed-phase model The retrieved precipitation agreed well with PR, radar data over ocean. The over-land algorithm underestimated the GPCC precipitation, and showed bias in terms of precipitation top level. Introduction of the scattering of non-spherical particles, realistic PSD etc.

25 Thank you. END

26 放射伝達方程GSMaP MWR algorithm アルゴリズム本体 ( リトリーバル ) 観測データ降水物理モデル ( フォワード計算 ) 放射アルゴリズム (10, 19, 37GHz) 陸上降雨有無判定海上降雨有無判定海岸降雨有無判定降水の非一様性補正散乱アルゴリズム (85, 37GHz) 各種判定補正降水強度推定降水強度式ルックアップテーブル (LUT) GANAL( 大気地表面物理量 ) 降水タイプ分類 ( 陸上 6 種海上 4 種 ) 降水 ( 鉛直 ) プロファイルモデル雨滴粒径分布モデル融解層モデル層状性降雨対流性降雨分類衛星が観測するのは放射散乱強度の積分値を表す輝度温度である降水物理モデルを仮定して放射伝達方程式を計算し輝度温度と降水強度の関係をテーブル化し観測値に近い輝度温度を与える降水強度を解としている

Particle Size Distribution Model 全球で取得可能なDSD パラメータ (TRMM PRの ε) の分布と降水タイプ分類のパターンの類似性から降水タイプ分類と関係づけたデータベース 450 400 350 300 kt-5deg98-04 kt-disd01-03 kt-1deg98-05

27 Particle Size Distribution Model 全球で取得可能なDSD パラメータ (TRMM PRの ε) の分布と降水タイプ分類のパターンの類似性から降水タイプ分類と関係づけたデータベース kt-5deg98-04 kt-disd01-03 kt-1deg98-05 地上ディスドロメータデータによる検証 a Jan Feb Mar Apr May Jun Jul Kototabang Aug Sep Oct Nov Dec Jan TRMM PR から推定した Z-R 関係の係数 a とディスドロメータから推定した a の比較. コトタバン ( 西スマトラ山岳地帯 ) Month

28 リーバル値と PR( 降水レーダ ) の地上降水強度の比較 (98 年 7 月 ) RAIN R 2 乗 = RAINSURF RAIN37 RAINSURF R 2 乗 = RAIN85 RAINSURF R 2 乗 = rain85/rainsurf R 2 乗 = rain37/rainsurf R 2 乗 = DTOP 降水トップの高い ( 低い ) 降水を過大 ( 過小 ) 評価する特に 85GHz の散乱シグナルは降水トップへの感度が大きい DTOP

29 Evaluation using PR Match-up data We were able to generate 141 AMSR-E vs. PR match-up data within observation time difference 5 minutes for Jan,Feb,Mar,Jun,Jul,Aug This figure shows distribution of the match-up locations. Total:141

30 Evaluation using PR Match-up data Distribution of the bias

31 Evaluation using PR Match-up data This figure shows the histogram of BIAS which are calculated from 141 match-up data. Liu Petty Aonashi Average=0.08 Average=0.12 Average=-0.04

32 Evaluation using PR Match-up data Distribution of the RMSE <

33 Evaluation using PR Match-up data This figure shows the frequency of RMSE which are calculated from 141 match-up data. Liu Petty Aonashi Average=1.40 Average=1.40 Average=1.33

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