MODULE module_ra_rrtm 2
! Parameters
INTEGER, PRIVATE :: IDATA
INTEGER, PARAMETER :: MG=16
INTEGER, PARAMETER :: NBANDS=16
INTEGER, PARAMETER :: NGPT=140
INTEGER, PARAMETER :: NG1=8
INTEGER, PARAMETER :: NG2=14
INTEGER, PARAMETER :: NG3=16
INTEGER, PARAMETER :: NG4=14
INTEGER, PARAMETER :: NG5=16
INTEGER, PARAMETER :: NG6=8
INTEGER, PARAMETER :: NG7=12
INTEGER, PARAMETER :: NG8=8
INTEGER, PARAMETER :: NG9=12
INTEGER, PARAMETER :: NG10=6
INTEGER, PARAMETER :: NG11=8
INTEGER, PARAMETER :: NG12=8
INTEGER, PARAMETER :: NG13=4
INTEGER, PARAMETER :: NG14=2
INTEGER, PARAMETER :: NG15=2
INTEGER, PARAMETER :: NG16=2
INTEGER, PARAMETER :: MAXINPX=35
INTEGER, PARAMETER :: MAXXSEC=4
INTEGER, PARAMETER :: NMOL = 6
REAL, PARAMETER :: ONEMINUS = 1. - 1.E-6
REAL, PARAMETER :: deltap = 4. ! Pressure interval for buffer layer in mb
! var
REAL , SAVE :: FLUXFAC
INTEGER , SAVE :: NLAYERS
!
! data 1
!
REAL,SAVE :: abscoefL1(5,13,MG), abscoefH1(5,13:59,MG), &
SELFREF1(10,MG)
REAL,SAVE :: abscoefL2(5,13,MG), abscoefH2(5,13:59,MG), &
SELFREF2(10,MG)
REAL,SAVE :: abscoefL3(10,5,13,MG), abscoefH3(5,5,13:59,MG), &
SELFREF3(10,MG)
REAL,SAVE :: abscoefL4(9,5,13,MG), abscoefH4(6,5,13:59,MG), &
SELFREF4(10,MG)
REAL,SAVE :: abscoefL5(9,5,13,MG), abscoefH5(5,5,13:59,MG), &
SELFREF5(10,MG)
REAL,SAVE :: abscoefL6(5,13,MG), SELFREF6(10,MG)
REAL,SAVE :: abscoefL7(9,5,13,MG), abscoefH7(5,13:59,MG), &
SELFREF7(10,MG)
REAL,SAVE :: abscoefL8(5,7,MG), abscoefH8(5,7:59,MG), &
SELFREF8(10,MG)
REAL,SAVE :: abscoefL9(11,5,13,MG), abscoefH9(5,13:59,MG), &
SELFREF9(10,MG)
REAL,SAVE :: abscoefL10(5,13,MG), abscoefH10(5,13:59,MG)
REAL,SAVE :: abscoefL11(5,13,MG), abscoefH11(5,13:59,MG), &
SELFREF11(10,MG)
REAL,SAVE :: abscoefL12(9,5,13,MG), SELFREF12(10,MG)
REAL,SAVE :: abscoefL13(9,5,13,MG), SELFREF13(10,MG)
REAL,SAVE :: abscoefL14(5,13,MG), abscoefH14(5,13:59,MG), &
SELFREF14(10,MG)
REAL,SAVE :: abscoefL15(9,5,13,MG), SELFREF15(10,MG)
REAL,SAVE :: abscoefL16(9,5,13,MG), SELFREF16(10,MG)
!
! data 2
!
INTEGER,SAVE :: NGM(MG*NBANDS), NGC(NBANDS), NGS(NBANDS), &
NGN(NGPT), NGB(NGPT)
REAL,SAVE :: WT(MG)
!
! data 3
!
REAL,SAVE :: FRACREFA1(MG), FRACREFB1(MG), FORREF1(MG)
REAL,SAVE :: FRACREFA2(MG,13), FRACREFB2(MG), FORREF2(MG)
REAL,SAVE :: FRACREFA3(MG,10), FRACREFB3(MG,5)
REAL,SAVE :: FORREF3(MG), ABSN2OA3(MG), ABSN2OB3(MG)
REAL,SAVE :: FRACREFA4(MG,9), FRACREFB4(MG,6)
REAL,SAVE :: FRACREFA5(MG,9), FRACREFB5(MG,5), CCL45(MG)
REAL,SAVE :: FRACREFA6(MG), ABSCO26(MG), CFC11ADJ6(MG), CFC126(MG)
REAL,SAVE :: FRACREFA7(MG,9), FRACREFB7(MG), ABSCO27(MG)
REAL,SAVE :: FRACREFA8(MG), FRACREFB8(MG), ABSCO2A8(MG), ABSCO2B8(MG)
REAL,SAVE :: ABSN2OA8(MG), ABSN2OB8(MG), CFC128(MG), CFC22ADJ8(MG)
REAL,SAVE :: FRACREFA9(MG,9), FRACREFB9(MG), ABSN2O9(3*MG)
REAL,SAVE :: FRACREFA10(MG), FRACREFB10(MG)
REAL,SAVE :: FRACREFA11(MG), FRACREFB11(MG)
REAL,SAVE :: FRACREFA12(MG,9)
REAL,SAVE :: FRACREFA13(MG,9)
REAL,SAVE :: FRACREFA14(MG), FRACREFB14(MG)
REAL,SAVE :: FRACREFA15(MG,9)
REAL,SAVE :: FRACREFA16(MG,9)
!
! data 4
!
INTEGER,SAVE :: NXMOL, IXINDX(MAXINPX)
! data 5
REAL,SAVE :: WAVENUM1(NBANDS),WAVENUM2(NBANDS),DELWAVE(NBANDS)
! data 6
INTEGER,SAVE :: NG(NBANDS),NSPA(NBANDS),NSPB(NBANDS)
REAL, SAVE :: HEATFAC
REAL, SAVE :: PREF(59),PREFLOG(59),TREF(59)
! data 7
REAL, SAVE :: TOTPLNK(181,NBANDS), TOTPLK16(181)
! data
REAL, SAVE :: TAU(0:5000),TF(0:5000),TRANS(0:5000)
!
REAL, SAVE :: ABSA1(5*13,NG1), ABSB1(5*(59-13+1),NG1), &
SELFREFC1(10,NG1), FORREFC1(NG1)
REAL, SAVE :: ABSA2(5*13,NG2), ABSB2(5*(59-13+1),NG2), &
SELFREFC2(10,NG2), FORREFC2(NG2)
REAL, SAVE :: ABSA3(10*5*13,NG3), ABSB3(5*5*(59-13+1),NG3), &
SELFREFC3(10,NG3), FORREFC3(NG3), &
ABSN2OAC3(NG3), ABSN2OBC3(NG3)
REAL, SAVE :: ABSA4(9*5*13,NG4), ABSB4(6*5*(59-13+1),NG4), &
SELFREFC4(10,NG4)
REAL, SAVE :: ABSA5(9*5*13,NG5), ABSB5(5*5*(59-13+1),NG5), &
SELFREFC5(10,NG5), CCL4C5(NG5)
REAL, SAVE :: ABSA6(5*13,NG6), SELFREFC6(10,NG6), &
ABSCO2C6(NG6), CFC11ADJC6(NG6), CFC12C6(NG6)
REAL, SAVE :: ABSA7(9*5*13,NG7), ABSB7(5*(59-13+1),NG7), &
SELFREFC7(10,NG7), ABSCO2C7(NG7)
REAL, SAVE :: ABSA8(5*7,NG8), ABSB8(5*(59-7+1),NG8), &
SELFREFC8(10,NG8), &
ABSCO2AC8(NG8), ABSCO2BC8(NG8), &
ABSN2OAC8(NG8), ABSN2OBC8(NG8), &
CFC12C8(NG8), CFC22ADJC8(NG8)
REAL, SAVE :: ABSA9(11*5*13,NG9), ABSB9(5*(59-13+1),NG9), &
SELFREFC9(10,NG9), ABSN2OC9(3*NG9)
REAL, SAVE :: ABSA10(5*13,NG10), ABSB10(5*(59-13+1),NG10)
REAL, SAVE :: ABSA11(5*13,NG11), ABSB11(5*(59-13+1),NG11), &
SELFREFC11(10,NG11)
REAL, SAVE :: ABSA12(9*5*13,NG12), SELFREFC12(10,NG12)
REAL, SAVE :: ABSA13(9*5*13,NG13), SELFREFC13(10,NG13)
REAL, SAVE :: ABSA14(5*13,NG14), ABSB14(5*(59-13+1),NG14), &
SELFREFC14(10,NG14)
REAL, SAVE :: ABSA15(9*5*13,NG15), SELFREFC15(10,NG15)
REAL, SAVE :: ABSA16(9*5*13,NG16), SELFREFC16(10,NG16)
REAL, SAVE :: FRACREFAC1(NG1), FRACREFBC1(NG1)
REAL, SAVE :: FRACREFAC2(NG2,13), FRACREFBC2(NG2)
REAL, SAVE :: FRACREFAC3(NG3,10), FRACREFBC3(NG3,5)
REAL, SAVE :: FRACREFAC4(NG4,9), FRACREFBC4(NG4,6)
REAL, SAVE :: FRACREFAC5(NG5,9), FRACREFBC5(NG5,5)
REAL, SAVE :: FRACREFAC6(NG6)
REAL, SAVE :: FRACREFAC7(NG7,9), FRACREFBC7(NG7)
REAL, SAVE :: FRACREFAC8(NG8), FRACREFBC8(NG8)
REAL, SAVE :: FRACREFAC9(NG9,9), FRACREFBC9(NG9)
REAL, SAVE :: FRACREFAC10(NG10), FRACREFBC10(NG10)
REAL, SAVE :: FRACREFAC11(NG11), FRACREFBC11(NG11)
REAL, SAVE :: FRACREFAC12(NG12,9)
REAL, SAVE :: FRACREFAC13(NG13,9)
REAL, SAVE :: FRACREFAC14(NG14), FRACREFBC14(NG14)
REAL, SAVE :: FRACREFAC15(NG15,9)
REAL, SAVE :: FRACREFAC16(NG16,9)
REAL, SAVE :: CORR1(0:200),CORR2(0:200)
REAL, SAVE :: BPADE
REAL, SAVE :: RWGT(MG*NBANDS)
!----------------------------------------------------------------------------
!
! start data 2
! Arrays for the g-point reduction from 256 to 140 for the 16 LW bands:
! This mapping from 256 to 140 points has been carefully selected to
! minimize the effect on the resulting fluxes and cooling rates, and
! caution should be used if the mapping is modified.
!
! NGPT The total number of new g-points
! NGC The number of new g-points in each band
! NGM The index of each new g-point relative to the original
! 16 g-points for each band.
! NGN The number of original g-points that are combined to make
! each new g-point in each band.
! NGB The band index for each new g-point.
! WT RRTM weights for 16 g-points.
! Data Statements
DATA NGC /8,14,16,14,16,8,12,8,12,6,8,8,4,2,2,2/
DATA NGS /8,22,38,52,68,76,88,96,108,114,122,130,134,136,138,140/
DATA NGM /1,1,2,2,3,3,4,4,5,5,6,6,7,7,8,8, & ! Band 1
1,2,3,4,5,6,7,8,9,10,11,12,13,13,14,14, & ! Band 2
1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! Band 3
1,2,3,4,5,6,7,8,9,10,11,12,13,14,14,14, & ! Band 4
1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16, & ! Band 5
1,1,2,2,3,3,4,4,5,5,6,6,7,7,8,8, & ! Band 6
1,1,2,2,3,4,5,6,7,8,9,10,11,11,12,12, & ! Band 7
1,1,2,2,3,3,4,4,5,5,6,6,7,7,8,8, & ! Band 8
1,2,3,4,5,6,7,8,9,9,10,10,11,11,12,12, & ! Band 9
1,1,2,2,3,3,4,4,5,5,5,5,6,6,6,6, & ! Band 10
1,2,3,3,4,4,5,5,6,6,7,7,7,8,8,8, & ! Band 11
1,2,3,4,5,5,6,6,7,7,7,7,8,8,8,8, & ! Band 12
1,1,1,2,2,2,3,3,3,3,4,4,4,4,4,4, & ! Band 13
1,1,1,1,1,1,1,1,2,2,2,2,2,2,2,2, & ! Band 14
1,1,1,1,1,1,1,1,2,2,2,2,2,2,2,2, & ! Band 15
1,1,1,1,1,1,1,1,2,2,2,2,2,2,2,2/ ! Band 16
DATA NGN /2,2,2,2,2,2,2,2, & ! Band 1
1,1,1,1,1,1,1,1,1,1,1,1,2,2, & ! Band 2
16*1, & ! Band 3
1,1,1,1,1,1,1,1,1,1,1,1,1,3, & ! Band 4
16*1, & ! Band 5
2,2,2,2,2,2,2,2, & ! Band 6
2,2,1,1,1,1,1,1,1,1,2,2, & ! Band 7
2,2,2,2,2,2,2,2, & ! Band 8
1,1,1,1,1,1,1,1,2,2,2,2, & ! Band 9
2,2,2,2,4,4, & ! Band 10
1,1,2,2,2,2,3,3, & ! Band 11
1,1,1,1,2,2,4,4, & ! Band 12
3,3,4,6, & ! Band 13
8,8, & ! Band 14
8,8, & ! Band 15
8,8/ ! Band 16
DATA NGB /8*1, & ! Band 1
14*2, & ! Band 2
16*3, & ! Band 3
14*4, & ! Band 4
16*5, & ! Band 5
8*6, & ! Band 6
12*7, & ! Band 7
8*8, & ! Band 8
12*9, & ! Band 9
6*10, & ! Band 10
8*11, & ! Band 11
8*12, & ! Band 12
4*13, & ! Band 13
2*14, & ! Band 14
2*15, & ! Band 15
2*16/ ! Band 16
DATA WT/ &
0.1527534276,0.1491729617,0.1420961469,0.1316886544, &
0.1181945205,0.1019300893,0.0832767040,0.0626720116, &
0.0424925,0.0046269894,0.0038279891,0.0030260086, &
0.0022199750,0.0014140010,0.000533,0.000075/
!
! end of data 2
!
!-----------------------------------------------------------------------
! start data 3
! Data
DATA FRACREFA1/ &
0.08452097,0.17952873,0.16214369,0.13602182, &
0.12760490,0.10302561,0.08392423,0.06337652, &
0.04206551,0.00487497,0.00410743,0.00344421, &
0.00285731,0.00157327,0.00080648,0.00012406/
DATA FRACREFB1/ &
0.15492001,0.17384727,0.15165100,0.12675308, &
0.10986247,0.09006091,0.07584465,0.05990077, &
0.04113461,0.00438638,0.00374754,0.00313924, &
0.00234381,0.00167167,0.00062744,0.00010889/
DATA FORREF1/ &
-4.50470E-02,-1.18908E-01,-7.21730E-02,-2.83862E-02, &
-3.01961E-02,-1.56877E-02,-1.53684E-02,-1.29135E-02, &
-1.27963E-02,-1.81742E-03, 4.40008E-05, 1.05260E-02, &
2.17290E-02, 1.65571E-02, 7.60751E-02, 1.47405E-01/
! Data
! The ith set of reference fractions are from the ith reference
! pressure level.
DATA FRACREFA2/ &
0.18068060,0.16803175,0.15140158,0.12221480, 0.10240850,0.09330297,0.07518960,0.05611294, &
0.03781487,0.00387192,0.00321285,0.00244440, 0.00179546,0.00107704,0.00038798,0.00005060, &
0.17927621,0.16731168,0.15129538,0.12328085, 0.10243484,0.09354796,0.07538418,0.05633071, &
0.03810832,0.00398347,0.00320262,0.00250029, 0.00178666,0.00111127,0.00039438,0.00005169, &
0.17762886,0.16638555,0.15115446,0.12470623, 0.10253213,0.09383459,0.07560240,0.05646568, &
0.03844077,0.00409142,0.00322521,0.00254918, 0.00179296,0.00113652,0.00040169,0.00005259, &
0.17566043,0.16539773,0.15092199,0.12571971, 0.10340609,0.09426189,0.07559051,0.05678188, &
0.03881499,0.00414102,0.00328551,0.00258795, 0.00181648,0.00115145,0.00040969,0.00005357, &
0.17335825,0.16442548,0.15070701,0.12667464, 0.10452303,0.09450833,0.07599410,0.05706393, &
0.03910370,0.00417880,0.00335256,0.00261708, 0.00185491,0.00116627,0.00041759,0.00005464, &
0.17082544,0.16321516,0.15044247,0.12797612, 0.10574646,0.09470057,0.07647423,0.05738756, &
0.03935621,0.00423789,0.00342651,0.00264549, 0.00190188,0.00118281,0.00042592,0.00005583, &
0.16809277,0.16193336,0.15013184,0.12937409, 0.10720784,0.09485368,0.07692636,0.05771774, &
0.03966988,0.00427754,0.00349696,0.00268946, 0.00193536,0.00120222,0.00043462,0.00005712, &
0.16517997,0.16059248,0.14984852,0.13079269, 0.10865030,0.09492947,0.07759736,0.05812201, &
0.03997169,0.00432356,0.00355308,0.00274031, 0.00197243,0.00122401,0.00044359,0.00005849, &
0.16209179,0.15912023,0.14938223,0.13198245, 0.11077233,0.09487948,0.07831636,0.05863440, &
0.04028239,0.00436804,0.00360407,0.00279885, 0.00200364,0.00124861,0.00045521,0.00005996, &
0.15962425,0.15789343,0.14898103,0.13275230, 0.11253940,0.09503502,0.07884382,0.05908009, &
0.04053524,0.00439971,0.00364269,0.00284965, 0.00202758,0.00127076,0.00046408,0.00006114, &
0.15926200,0.15770932,0.14891729,0.13283882, 0.11276010,0.09507311,0.07892222,0.05919230, &
0.04054824,0.00440833,0.00365575,0.00286459, 0.00203786,0.00128405,0.00046504,0.00006146, &
0.15926351,0.15770483,0.14891177,0.13279966, 0.11268171,0.09515216,0.07890341,0.05924807, &
0.04052851,0.00440870,0.00365425,0.00286878, 0.00205747,0.00128916,0.00046589,0.00006221, &
0.15937765,0.15775780,0.14892603,0.13273248, 0.11252731,0.09521657,0.07885858,0.05927679, &
0.04050184,0.00440285,0.00365748,0.00286791, 0.00207507,0.00129193,0.00046679,0.00006308/
! From P = 0.432 mb.
DATA FRACREFB2/ &
0.17444289,0.16467269,0.15021490,0.12460902, &
0.10400643,0.09481928,0.07590704,0.05752856, &
0.03931715,0.00428572,0.00349352,0.00278938, &
0.00203448,0.00130037,0.00051560,0.00006255/
DATA FORREF2/ &
-2.34550E-03,-8.42698E-03,-2.01816E-02,-5.66701E-02, &
-8.93189E-02,-6.37487E-02,-4.56455E-02,-4.41417E-02, &
-4.48605E-02,-4.74696E-02,-5.16648E-02,-5.63099E-02, &
-4.74781E-02,-3.84704E-02,-2.49905E-02, 2.02114E-03/
! Data
DATA FRACREFA3/ &
! From P = 1053.6 mb.
0.15116400,0.14875700,0.14232300,0.13234501, 0.11881600,0.10224100,0.08345580,0.06267490, &
0.04250650,0.00462650,0.00382259,0.00302600, 0.00222004,0.00141397,0.00053379,0.00007421, &
0.15266000,0.14888400,0.14195900,0.13179500, 0.11842700,0.10209000,0.08336130,0.06264370, &
0.04247660,0.00461946,0.00381536,0.00302601, 0.00222004,0.00141397,0.00053302,0.00007498, &
0.15282799,0.14903000,0.14192399,0.13174300, 0.11835300,0.10202700,0.08329830,0.06264830, &
0.04246910,0.00460242,0.00381904,0.00301573, 0.00222004,0.00141397,0.00053379,0.00007421, &
0.15298399,0.14902800,0.14193401,0.13173500, 0.11833300,0.10195800,0.08324730,0.06264770, &
0.04246490,0.00460489,0.00381123,0.00301893, 0.00221093,0.00141397,0.00053379,0.00007421, &
0.15307599,0.14907201,0.14198899,0.13169800, 0.11827300,0.10192300,0.08321600,0.06263490, &
0.04245600,0.00460846,0.00380836,0.00301663, 0.00221402,0.00141167,0.00052807,0.00007376, &
0.15311401,0.14915401,0.14207301,0.13167299, 0.11819300,0.10188900,0.08318760,0.06261960, &
0.04243890,0.00461584,0.00380929,0.00300815, 0.00221736,0.00140588,0.00052776,0.00007376, &
0.15316001,0.14925499,0.14213000,0.13170999, 0.11807700,0.10181400,0.08317400,0.06260300, &
0.04242720,0.00461520,0.00381381,0.00301285, 0.00220275,0.00140371,0.00052776,0.00007376, &
0.15321200,0.14940999,0.14222500,0.13164200, 0.11798200,0.10174500,0.08317500,0.06253640, &
0.04243130,0.00461724,0.00381534,0.00300320, 0.00220091,0.00140364,0.00052852,0.00007300, &
0.15312800,0.14973100,0.14234400,0.13168900, 0.11795200,0.10156100,0.08302990,0.06252240, &
0.04240980,0.00461035,0.00381381,0.00300176, 0.00220160,0.00140284,0.00052774,0.00007376, &
0.15292500,0.14978001,0.14242400,0.13172600, 0.11798800,0.10156400,0.08303050,0.06251670, &
0.04240970,0.00461302,0.00381452,0.00300250, 0.00220126,0.00140324,0.00052850,0.00007300/
DATA FRACREFB3/ &
! From P = 64.1 mb.
0.16340201,0.15607700,0.14601400,0.13182700, &
0.11524700,0.09666570,0.07825360,0.05849780, &
0.03949650,0.00427980,0.00353719,0.00279303, &
0.00204788,0.00130139,0.00049055,0.00006904, &
0.15762900,0.15494700,0.14659800,0.13267800, &
0.11562700,0.09838360,0.07930420,0.05962700, &
0.04036360,0.00438053,0.00361463,0.00285723, &
0.00208345,0.00132135,0.00050528,0.00008003, &
0.15641500,0.15394500,0.14633600,0.13180400, &
0.11617100,0.09924170,0.08000510,0.06021420, &
0.04082730,0.00441694,0.00365364,0.00287723, &
0.00210914,0.00135784,0.00054651,0.00008003, &
0.15482700,0.15286300,0.14392500,0.13244100, &
0.11712000,0.09994920,0.08119200,0.06104360, &
0.04135600,0.00446685,0.00368377,0.00290767, &
0.00215445,0.00142865,0.00056142,0.00008003, &
0.15975100,0.15653500,0.14214399,0.12892200, &
0.11508400,0.09906020,0.08087940,0.06078190, &
0.04140530,0.00452724,0.00374558,0.00295328, &
0.00218509,0.00138644,0.00056018,0.00008003/
DATA ABSN2OA3/ &
1.50387E-01,2.91407E-01,6.28803E-01,9.65619E-01, &
1.15054E-00,2.23424E-00,1.83392E-00,1.39033E-00, &
4.28457E-01,2.73502E-01,1.84307E-01,1.61325E-01, &
7.66314E-02,1.33862E-01,6.71196E-07,1.59293E-06/
DATA ABSN2OB3/ &
9.37044E-05,1.23318E-03,7.91720E-03,5.33005E-02, &
1.72343E-01,4.29571E-01,1.01288E+00,3.83863E+00, &
1.15312E+01,1.08383E+00,2.24847E+00,1.51268E+00, &
3.33177E-01,7.82102E-01,3.44631E-01,1.61039E-03/
DATA FORREF3/ &
1.76842E-04, 1.77913E-04, 1.25186E-04, 1.07912E-04, &
1.05217E-04, 7.48726E-05, 1.11701E-04, 7.68921E-05, &
9.87242E-05, 9.85711E-05, 6.16557E-05,-1.61291E-05, &
-1.26794E-04,-1.19011E-04,-2.67814E-04, 6.95005E-05/
! Data
DATA FRACREFA4/ &
! From P =
0.15579100,0.14918099,0.14113800,0.13127001, &
0.11796300,0.10174300,0.08282370,0.06238150, &
0.04213440,0.00458968,0.00377949,0.00298736, &
0.00220743,0.00140644,0.00053024,0.00007459, &
0.15292799,0.15004000,0.14211500,0.13176700, &
0.11821100,0.10186300,0.08288040,0.06241390, &
0.04220720,0.00459006,0.00377919,0.00298743, &
0.00220743,0.00140644,0.00053024,0.00007459, &
0.14386199,0.15125300,0.14650001,0.13377000, &
0.11895900,0.10229400,0.08312110,0.06239520, &
0.04225560,0.00459428,0.00378865,0.00298860, &
0.00220743,0.00140644,0.00053024,0.00007459, &
0.14359100,0.14561599,0.14479300,0.13740200, &
0.12150100,0.10315400,0.08355480,0.06247240, &
0.04230980,0.00459916,0.00378373,0.00300063, &
0.00221111,0.00140644,0.00053024,0.00007459, &
0.14337599,0.14451601,0.14238000,0.13520500, &
0.12354200,0.10581200,0.08451810,0.06262440, &
0.04239590,0.00460297,0.00378701,0.00300466, &
0.00221899,0.00141020,0.00053024,0.00007459, &
0.14322001,0.14397401,0.14117201,0.13401900, &
0.12255500,0.10774100,0.08617650,0.06296420, &
0.04249590,0.00463406,0.00378241,0.00302037, &
0.00221583,0.00141103,0.00053814,0.00007991, &
0.14309500,0.14364301,0.14043900,0.13348100, &
0.12211600,0.10684700,0.08820590,0.06374610, &
0.04264730,0.00464231,0.00384022,0.00303427, &
0.00221825,0.00140943,0.00055564,0.00007991, &
0.15579100,0.14918099,0.14113800,0.13127001, &
0.11796300,0.10174300,0.08282370,0.06238150, &
0.04213440,0.00458968,0.00377949,0.00298736, &
0.00220743,0.00140644,0.00053024,0.00007459, &
0.15937001,0.15159500,0.14242800,0.13078900, &
0.11671300,0.10035700,0.08143450,0.06093850, &
0.04105320,0.00446233,0.00369844,0.00293784, &
0.00216425,0.00143403,0.00054571,0.00007991/
DATA FRACREFB4/ &
! From P = 1.17 mb.
0.15558299,0.14930600,0.14104301,0.13124099, &
0.11792900,0.10159200,0.08314130,0.06240450, &
0.04217020,0.00459313,0.00379798,0.00299835, &
0.00218950,0.00140615,0.00053010,0.00007457, &
0.15592700,0.14918999,0.14095700,0.13115700, &
0.11788900,0.10158000,0.08313780,0.06240240, &
0.04217000,0.00459313,0.00379798,0.00299835, &
0.00218950,0.00140615,0.00053010,0.00007457, &
0.15949000,0.15014900,0.14162201,0.13080800, &
0.11713500,0.10057100,0.08170080,0.06128110, &
0.04165600,0.00459202,0.00379835,0.00299717, &
0.00218958,0.00140616,0.00053010,0.00007457, &
0.15967900,0.15038200,0.14196999,0.13074800, &
0.11701700,0.10053000,0.08160790,0.06122690, &
0.04128310,0.00456598,0.00379486,0.00299457, &
0.00219016,0.00140619,0.00053011,0.00007456, &
0.15989800,0.15057300,0.14207700,0.13068600, &
0.11682900,0.10053900,0.08163610,0.06121870, &
0.04121690,0.00449061,0.00371235,0.00294207, &
0.00217778,0.00139877,0.00053011,0.00007455, &
0.15950100,0.15112500,0.14199100,0.13071300, &
0.11680800,0.10054600,0.08179050,0.06120910, &
0.04126050,0.00444324,0.00366843,0.00289369, &
0.00211550,0.00134746,0.00050874,0.00007863/
! Data
DATA FRACREFA5/ &
! From P = 387.6 mb.
0.13966499,0.14138900,0.13763399,0.13076700, &
0.12299100,0.10747700,0.08942000,0.06769200, &
0.04587610,0.00501173,0.00415809,0.00328398, &
0.00240015,0.00156222,0.00059104,0.00008323, &
0.13958199,0.14332899,0.13785399,0.13205400, &
0.12199700,0.10679600,0.08861080,0.06712320, &
0.04556030,0.00500863,0.00416315,0.00328629, &
0.00240023,0.00156220,0.00059104,0.00008323, &
0.13907100,0.14250501,0.13889600,0.13297300, &
0.12218700,0.10683800,0.08839260,0.06677310, &
0.04538570,0.00495402,0.00409863,0.00328219, &
0.00240805,0.00156266,0.00059104,0.00008323, &
0.13867700,0.14190100,0.13932300,0.13327099, &
0.12280800,0.10692500,0.08844510,0.06658510, &
0.04519340,0.00492276,0.00408832,0.00323856, &
0.00239289,0.00155698,0.00059104,0.00008323, &
0.13845000,0.14158800,0.13929300,0.13295600, &
0.12348300,0.10736700,0.08859480,0.06650610, &
0.04498230,0.00491335,0.00406968,0.00322901, &
0.00234666,0.00155235,0.00058813,0.00008323, &
0.13837101,0.14113200,0.13930500,0.13283101, &
0.12349200,0.10796400,0.08890490,0.06646480, &
0.04485990,0.00489554,0.00405264,0.00320313, &
0.00234742,0.00151159,0.00058438,0.00008253, &
0.13834500,0.14093500,0.13896500,0.13262001, &
0.12326900,0.10828900,0.08950050,0.06674610, &
0.04476560,0.00489624,0.00400962,0.00317423, &
0.00233479,0.00148249,0.00058590,0.00008253, &
0.13831300,0.14069000,0.13871400,0.13247600, &
0.12251400,0.10831300,0.08977090,0.06776920, &
0.04498390,0.00484111,0.00398948,0.00316069, &
0.00229741,0.00150104,0.00058608,0.00008253, &
0.14027201,0.14420401,0.14215700,0.13446601, &
0.12303700,0.10596100,0.08650370,0.06409570, &
0.04312310,0.00471110,0.00393954,0.00310850, &
0.00229588,0.00146366,0.00058194,0.00008253/
DATA FRACREFB5/ &
! From P = 1.17 mb.
0.14339100,0.14358699,0.13935301,0.13306700, &
0.12135700,0.10590600,0.08688240,0.06553220, &
0.04446740,0.00483580,0.00399413,0.00316225, &
0.00233007,0.00149135,0.00056246,0.00008059, &
0.14330500,0.14430299,0.14053699,0.13355300, &
0.12151200,0.10529100,0.08627630,0.06505230, &
0.04385850,0.00476555,0.00395010,0.00313878, &
0.00232273,0.00149354,0.00056246,0.00008059, &
0.14328399,0.14442700,0.14078601,0.13390100, &
0.12132600,0.10510600,0.08613660,0.06494630, &
0.04381310,0.00475378,0.00394166,0.00313076, &
0.00231235,0.00149159,0.00056301,0.00008059, &
0.14326900,0.14453100,0.14114200,0.13397101, &
0.12127200,0.10493400,0.08601380,0.06483360, &
0.04378900,0.00474655,0.00393549,0.00312583, &
0.00230686,0.00148433,0.00056502,0.00008059, &
0.14328900,0.14532700,0.14179000,0.13384600, &
0.12093700,0.10461500,0.08573010,0.06461340, &
0.04366570,0.00473087,0.00392539,0.00311238, &
0.00229865,0.00147572,0.00056517,0.00007939/
DATA CCL45/ &
26.1407, 53.9776, 63.8085, 36.1701, &
15.4099, 10.23116, 4.82948, 5.03836, &
1.75558,0.,0.,0., &
0.,0.,0.,0./
! Data
DATA FRACREFA6/ &
! From P = 706 mb.
0.13739009,0.14259538,0.14033118,0.13547136, &
0.12569460,0.11028396,0.08626066,0.06245148, &
0.04309394,0.00473551,0.00403920,0.00321695, &
0.00232470,0.00147662,0.00056095,0.00007373/
DATA CFC11ADJ6/ &
0., 0., 36.7627, 150.757, &
81.4109, 74.9112, 56.9325, 49.3226, &
57.1074, 66.1202, 109.557, 89.0562, &
149.865, 196.140, 258.393, 80.9923/
DATA CFC126/ &
62.8368, 43.2626, 26.7549, 22.2487, &
23.5029, 34.8323, 26.2335, 23.2306, &
18.4062, 13.9534, 22.6268, 24.2604, &
30.0088, 26.3634, 15.8237, 57.5050/
DATA ABSCO26/ &
7.44852E-05, 6.29208E-05, 7.34031E-05, 6.65218E-05, &
7.87511E-05, 1.22489E-04, 3.39785E-04, 9.33040E-04, &
1.54323E-03, 4.07220E-04, 4.34332E-04, 8.76418E-05, &
9.80381E-05, 3.51680E-05, 5.31766E-05, 1.01542E-05/
! Data
DATA FRACREFA7/ &
0.16461779, 0.14889984, 0.14233345, 0.13156526, &
0.11679733, 0.09988949, 0.08078653, 0.06006384, &
0.04028391, 0.00435899, 0.00359173, 0.00281707, &
0.00206767, 0.00135012, 0.00050720, 0.00007146, &
0.16442357, 0.14944240, 0.14245804, 0.13111183, &
0.11688625, 0.09983791, 0.08085148, 0.05993948, &
0.04028057, 0.00435939, 0.00358708, 0.00284036, &
0.00208869, 0.00133256, 0.00049260, 0.00006931, &
0.16368519, 0.15018989, 0.14262174, 0.13084342, &
0.11682195, 0.09996257, 0.08074036, 0.05985692, &
0.04045362, 0.00436208, 0.00358257, 0.00287122, &
0.00211004, 0.00133804, 0.00049260, 0.00006931, &
0.16274056, 0.15133780, 0.14228874, 0.13081114, &
0.11688486, 0.09979610, 0.08073687, 0.05996741, &
0.04040616, 0.00439869, 0.00368910, 0.00293041, &
0.00211604, 0.00133536, 0.00049260, 0.00006931, &
0.16176532, 0.15207882, 0.14226955, 0.13079646, &
0.11688191, 0.09966998, 0.08066384, 0.06020275, &
0.04047901, 0.00446696, 0.00377456, 0.00294410, &
0.00211082, 0.00133536, 0.00049260, 0.00006931, &
0.15993737, 0.15305527, 0.14259829, 0.13078023, &
0.11686983, 0.09980131, 0.08058286, 0.06031430, &
0.04082833, 0.00450509, 0.00377574, 0.00294823, &
0.00210977, 0.00133302, 0.00049260, 0.00006931, &
0.15371189, 0.15592396, 0.14430280, 0.13076764, &
0.11720382, 0.10023471, 0.08066396, 0.06073554, &
0.04121581, 0.00451202, 0.00377832, 0.00294609, &
0.00210943, 0.00133336, 0.00049260, 0.00006931, &
0.14262275, 0.14572631, 0.14560597, 0.13736825, &
0.12271351, 0.10419556, 0.08294533, 0.06199794, &
0.04157615, 0.00452842, 0.00377704, 0.00293852, &
0.00211034, 0.00133278, 0.00049259, 0.00006931, &
0.14500433, 0.14590444, 0.14430299, 0.13770708, &
0.12288283, 0.10350952, 0.08269450, 0.06130579, &
0.04144571, 0.00452096, 0.00377382, 0.00294532, &
0.00210943, 0.00133228, 0.00049260, 0.00006931/
DATA FRACREFB7/ &
0.15355594,0.15310939,0.14274909,0.13129812, &
0.11736792,0.10118213,0.08215259,0.06165591, &
0.04164486,0.00451141,0.00372837,0.00294095, &
0.00215259,0.00136792,0.00051233,0.00007075/
DATA ABSCO27/ &
9.30038E-05, 1.74061E-04, 2.09293E-04, 2.52360E-04, &
3.13404E-04, 4.16619E-04, 6.27394E-04, 1.29386E-03, &
4.05192E-03, 3.97050E-03, 7.00634E-04, 6.06617E-04, &
7.66978E-04, 6.70661E-04, 7.89971E-04, 7.55709E-04/
! Data
DATA FRACREFA8/ &
! From P = 1053.6 mb.
0.15309700,0.15450300,0.14458799,0.13098200, &
0.11817900,0.09953490,0.08132080,0.06139960, &
0.04132010,0.00446788,0.00372533,0.00294053, &
0.00211371,0.00128122,0.00048050,0.00006759/
DATA FRACREFB8/ &
! From P = 28.9 mb.
0.14105400,0.14728899,0.14264800,0.13331699, &
0.12034100,0.10467000,0.08574980,0.06469390, &
0.04394640,0.00481284,0.00397375,0.00315006, &
0.00228636,0.00144606,0.00054604,0.00007697/
DATA CFC128/ &
85.4027, 89.4696, 74.0959, 67.7480, &
61.2444, 59.9073, 60.8296, 63.0998, &
59.6110, 64.0735, 57.2622, 58.9721, &
43.5505, 26.1192, 32.7023, 32.8667/
DATA CFC22ADJ8/ &
! Original CFC22 is multiplied by 1.485 to account for the 780-850 cm-1
! and 1290-1335 cm-1 bands.
135.335, 89.6642, 76.2375, 65.9748, &
63.1164, 60.2935, 64.0299, 75.4264, &
51.3018, 7.07911, 5.86928, 0.398693, &
2.82885, 9.12751, 6.28271, 0./
DATA ABSCO2A8/ &
1.11233E-05, 3.92400E-05, 6.62059E-05, 8.51687E-05, &
7.79035E-05, 1.34058E-04, 2.82553E-04, 5.41741E-04, &
1.47029E-05, 2.34982E-05, 6.91094E-08, 8.48917E-08, &
6.58783E-08, 4.64849E-08, 3.62742E-08, 3.62742E-08/
DATA ABSCO2B8/ &
4.10977E-09, 5.65200E-08, 1.70800E-07, 4.16840E-07, &
9.53684E-07, 2.36468E-06, 7.29502E-06, 4.93883E-05, &
5.10440E-04, 9.75248E-04, 1.36495E-03, 2.40451E-03, &
4.50277E-03, 2.24486E-02, 4.06756E-02, 2.17447E-10/
DATA ABSN2OA8/ &
1.28527E-02,5.28651E-02,1.01668E-01,1.57224E-01, &
2.76947E-01,4.93048E-01,6.71387E-01,3.48809E-01, &
4.19840E-01,3.13558E-01,2.44432E-01,2.05108E-01, &
1.21423E-01,1.22158E-01,1.49702E-01,1.47799E-01/
DATA ABSN2OB8/ &
3.15864E-03,4.87347E-03,8.63235E-03,2.16053E-02, &
3.63699E-02,7.89149E-02,3.53807E-01,1.27140E-00, &
2.31464E-00,7.75834E-02,5.15063E-02,4.07059E-02, &
5.91947E-02,5.83546E-02,3.12716E-01,1.47456E-01/
! Data
DATA FRACREFA9/ &
! From P = 1053.6 mb.
0.16898900,0.15898301,0.13575301,0.12600900, &
0.11545800,0.09879170,0.08106830,0.06063440, &
0.03988780,0.00421760,0.00346635,0.00278779, &
0.00206225,0.00132324,0.00050033,0.00007038, &
0.18209399,0.15315101,0.13571000,0.12504999, &
0.11379100,0.09680810,0.08008570,0.05970280, &
0.03942860,0.00413383,0.00343186,0.00275558, &
0.00204657,0.00130219,0.00045454,0.00005664, &
0.18459500,0.15512000,0.13395500,0.12576801, &
0.11276800,0.09645190,0.07956650,0.05903340, &
0.03887050,0.00412226,0.00339453,0.00273518, &
0.00196922,0.00119411,0.00040263,0.00005664, &
0.18458800,0.15859900,0.13278100,0.12589300, &
0.11272700,0.09599660,0.07903030,0.05843600, &
0.03843400,0.00405181,0.00337980,0.00263818, &
0.00186869,0.00111807,0.00040263,0.00005664, &
0.18459301,0.16176100,0.13235000,0.12528200, &
0.11237100,0.09618840,0.07833760,0.05800770, &
0.03787610,0.00408253,0.00330363,0.00250445, &
0.00176725,0.00111753,0.00040263,0.00005664, &
0.18454400,0.16505300,0.13221300,0.12476600, &
0.11158300,0.09618120,0.07797340,0.05740380, &
0.03742820,0.00392691,0.00312208,0.00246306, &
0.00176735,0.00111721,0.00040263,0.00005664, &
0.18452001,0.16697501,0.13445500,0.12391300, &
0.11059100,0.09596890,0.07761050,0.05643200, &
0.03686520,0.00377086,0.00309351,0.00246297, &
0.00176765,0.00111700,0.00040263,0.00005664, &
0.18460999,0.16854499,0.13922299,0.12266400, &
0.10962200,0.09452030,0.07653800,0.05551340, &
0.03609660,0.00377043,0.00309367,0.00246304, &
0.00176749,0.00111689,0.00040263,0.00005664, &
0.18312500,0.16787501,0.14720701,0.12766500, &
0.10890900,0.08935530,0.07310870,0.05443140, &
0.03566380,0.00376446,0.00309521,0.00246510, &
0.00176139,0.00111543,0.00040263,0.00005664/
DATA FRACREFB9/ &
! From P = 0.071 mb.
0.20148601,0.15252700,0.13376500,0.12184600, &
0.10767800,0.09307410,0.07674570,0.05876940, &
0.04001480,0.00424612,0.00346896,0.00269954, &
0.00196864,0.00122562,0.00043628,0.00004892/
DATA ABSN2O9/ &
! From P = 952 mb.
3.26267E-01,2.42869E-00,1.15455E+01,7.39478E-00, &
5.16550E-00,2.54474E-00,3.53082E-00,3.82278E-00, &
1.81297E-00,6.65313E-01,1.23652E-01,1.83895E-03, &
1.70592E-03,2.68434E-09,0.,0., &
! From P = 620 mb.
2.08632E-01,1.11865E+00,4.95975E+00,8.10907E+00, &
1.10408E+01,5.45460E+00,4.18611E+00,3.53422E+00, &
2.54164E+00,3.65093E-01,5.84480E-01,2.26918E-01, &
1.36230E-03,5.54400E-10,6.83703E-10,0., &
! From P = 313 mb.
6.20022E-02,2.69521E-01,9.81928E-01,1.65004E-00, &
3.08089E-00,5.38696E-00,1.14600E+01,2.41211E+01, &
1.69655E+01,1.37556E-00,5.43254E-01,3.52079E-01, &
4.31888E-01,4.82523E-06,5.74747E-11,0./
! Data
DATA FRACREFA10/ &
! From P = 473 mb.
0.16271301,0.15141940,0.14065412,0.12899506, &
0.11607002,0.10142808,0.08116794,0.06104711, &
0.04146209,0.00447386,0.00372902,0.00287258, &
0.00206028,0.00134634,0.00049232,0.00006927/
DATA FRACREFB10/ &
! From P = 1.17 mb.
0.16571465,0.15262246,0.14036226,0.12620729, &
0.11477834,0.09967982,0.08155201,0.06159503, &
0.04196607,0.00453940,0.00376881,0.00300437, &
0.00223034,0.00139432,0.00051516,0.00007095/
! Data
DATA FRACREFA11/ &
! From P = 473 mb.
0.14152819,0.13811260,0.14312185,0.13705885, &
0.11944738,0.10570189,0.08866373,0.06565409, &
0.04428961,0.00481540,0.00387058,0.00329187, &
0.00238294,0.00150971,0.00049287,0.00005980/
DATA FRACREFB11/ &
! From P = 1.17 mb.
0.10874039,0.15164889,0.15149839,0.14515044, &
0.12486220,0.10725017,0.08715712,0.06463144, &
0.04332319,0.00441193,0.00393819,0.00305960, &
0.00224221,0.00145100,0.00055586,0.00007934/
! Data
DATA FRACREFA12/ &
! From P = 706.3 mb.
0.21245100,0.15164700,0.14486700,0.13075501, &
0.11629600,0.09266050,0.06579930,0.04524000, &
0.03072870,0.00284297,0.00234660,0.00185208, &
0.00133978,0.00082214,0.00031016,0.00004363, &
0.14703900,0.16937999,0.15605700,0.14159000, &
0.12088500,0.10058500,0.06809110,0.05131470, &
0.03487040,0.00327281,0.00250183,0.00190024, &
0.00133978,0.00082214,0.00031016,0.00004363, &
0.13689300,0.16610400,0.15723500,0.14299500, &
0.12399400,0.09907820,0.07169690,0.05367370, &
0.03671630,0.00378148,0.00290510,0.00221076, &
0.00142810,0.00093527,0.00031016,0.00004363, &
0.13054299,0.16273800,0.15874299,0.14279599, &
0.12674300,0.09664900,0.07462200,0.05620080, &
0.03789090,0.00411690,0.00322920,0.00245036, &
0.00178303,0.00098595,0.00040802,0.00010150, &
0.12828299,0.15824600,0.15688400,0.14449100, &
0.12787800,0.09517830,0.07679350,0.05890820, &
0.03883570,0.00442304,0.00346796,0.00255333, &
0.00212519,0.00116168,0.00067065,0.00010150, &
0.12649800,0.15195100,0.15646499,0.14569700, &
0.12669300,0.09653520,0.07887920,0.06106920, &
0.04043910,0.00430390,0.00364453,0.00314360, &
0.00203206,0.00187787,0.00067075,0.00010150, &
0.12500300,0.14460599,0.15672199,0.14724600, &
0.11978900,0.10190200,0.08196710,0.06315770, &
0.04240100,0.00433645,0.00404097,0.00329466, &
0.00288491,0.00187803,0.00067093,0.00010150, &
0.12317200,0.14118700,0.15242000,0.13794300, &
0.12119200,0.10655400,0.08808350,0.06521370, &
0.04505680,0.00485949,0.00477105,0.00401468, &
0.00288491,0.00187786,0.00067110,0.00010150, &
0.10193600,0.11693000,0.13236099,0.14053200, &
0.13749801,0.12193100,0.10221000,0.07448910, &
0.05205320,0.00572312,0.00476882,0.00403380, &
0.00288871,0.00187396,0.00067218,0.00010150/
! Data
DATA FRACREFA13/ &
! From P = 706.3 mb.
0.17683899,0.17319500,0.15712699,0.13604601, &
0.10776200,0.08750010,0.06808820,0.04905150, &
0.03280360,0.00350836,0.00281864,0.00219862, &
0.00160943,0.00101885,0.00038147,0.00005348, &
0.17535400,0.16999300,0.15610200,0.13589200, &
0.10842100,0.08988550,0.06943920,0.04974900, &
0.03323400,0.00352752,0.00289402,0.00231003, &
0.00174659,0.00101884,0.00038147,0.00005348, &
0.17409500,0.16846400,0.15641899,0.13503000, &
0.10838600,0.08985800,0.07092720,0.05075710, &
0.03364180,0.00354241,0.00303507,0.00243391, &
0.00177502,0.00114638,0.00043585,0.00005348, &
0.17248300,0.16778600,0.15543500,0.13496999, &
0.10826300,0.09028740,0.07156720,0.05187120, &
0.03424890,0.00363933,0.00324715,0.00255030, &
0.00187380,0.00116978,0.00051229,0.00009768, &
0.17061099,0.16715799,0.15405200,0.13471501, &
0.10896400,0.09069460,0.07229760,0.05218280, &
0.03555340,0.00379576,0.00330240,0.00274693, &
0.00201587,0.00119598,0.00061885,0.00009768, &
0.16789700,0.16629100,0.15270300,0.13360199, &
0.11047200,0.09151080,0.07325000,0.05261450, &
0.03657990,0.00450092,0.00349537,0.00283321, &
0.00208396,0.00140354,0.00066587,0.00009768, &
0.16412200,0.16387400,0.15211500,0.13062200, &
0.11325100,0.09348130,0.07381380,0.05434740, &
0.03803160,0.00481346,0.00393592,0.00296633, &
0.00222532,0.00163762,0.00066648,0.00009768, &
0.15513401,0.15768200,0.14850400,0.13330200, &
0.11446500,0.09868230,0.07642050,0.05624170, &
0.04197810,0.00502288,0.00429452,0.00315347, &
0.00263559,0.00171772,0.00066860,0.00009768, &
0.15732600,0.15223300,0.14271900,0.13563600, &
0.11859600,0.10274200,0.07934560,0.05763410, &
0.03921740,0.00437741,0.00337921,0.00280212, &
0.00200156,0.00124812,0.00064664,0.00009768/
! Data
DATA FRACREFA14/ &
! From P = 1053.6 mb.
0.18446200,0.16795200,0.14949700,0.12036000, &
0.10440100,0.09024280,0.07435880,0.05629380, &
0.03825420,0.00417276,0.00345278,0.00272949, &
0.00200378,0.00127404,0.00050721,0.00004141/
DATA FRACREFB14/ &
! From P = 0.64 mb.
0.19128500,0.16495700,0.14146100,0.11904500, &
0.10350200,0.09151190,0.07604270,0.05806020, &
0.03979950,0.00423959,0.00357439,0.00287559, &
0.00198860,0.00116529,0.00043616,0.00005987/
! Data
DATA FRACREFA15/ &
! From P = 1053.6 mb.
0.11287100,0.12070200,0.12729000,0.12858100, &
0.12743001,0.11961800,0.10290400,0.07888980, &
0.05900120,0.00667979,0.00552926,0.00436993, &
0.00320611,0.00204765,0.00077371,0.00010894, &
0.13918801,0.16353001,0.16155800,0.14090499, &
0.11322300,0.08757720,0.07225720,0.05173390, &
0.04731360,0.00667979,0.00552926,0.00436993, &
0.00320611,0.00204765,0.00077371,0.00010894, &
0.14687300,0.17853101,0.15664500,0.13351700, &
0.10791200,0.08684320,0.07158090,0.05198410, &
0.04340110,0.00667979,0.00552926,0.00436993, &
0.00320611,0.00204765,0.00077371,0.00010894, &
0.15760700,0.17759100,0.15158001,0.13193300, &
0.10742800,0.08693760,0.07159490,0.05196250, &
0.04065270,0.00667979,0.00552926,0.00436993, &
0.00320611,0.00204765,0.00077371,0.00010894, &
0.16646700,0.17299300,0.15018500,0.13138700, &
0.10735900,0.08713110,0.07130330,0.05279420, &
0.03766730,0.00667979,0.00552926,0.00436993, &
0.00320611,0.00204765,0.00077371,0.00010894, &
0.17546000,0.16666500,0.14969499,0.13105400, &
0.10782500,0.08718610,0.07156770,0.05308320, &
0.03753960,0.00432465,0.00509623,0.00436993, &
0.00320611,0.00204765,0.00077371,0.00010894, &
0.18378501,0.16064601,0.14940400,0.13146400, &
0.10810300,0.08775740,0.07115360,0.05400040, &
0.03689970,0.00388333,0.00323610,0.00353414, &
0.00320611,0.00204765,0.00077371,0.00010894, &
0.18966800,0.15744300,0.14993000,0.13152599, &
0.10899200,0.08858690,0.07142920,0.05399600, &
0.03433460,0.00374886,0.00302066,0.00240653, &
0.00199205,0.00204765,0.00077371,0.00010894, &
0.11887100,0.12479600,0.12569501,0.12839900, &
0.12473500,0.12012800,0.11086700,0.08493590, &
0.05063770,0.00328723,0.00266849,0.00210232, &
0.00152114,0.00095635,0.00035374,0.00004980/
! Data
DATA FRACREFA16/ &
! From P = 862.6 mb.
0.17356300,0.18880001,0.17704099,0.13661300, &
0.10691600,0.08222480,0.05939860,0.04230810, &
0.02526330,0.00244532,0.00193541,0.00150415, &
0.00103528,0.00067068,0.00024951,0.00003348, &
0.17779499,0.19837400,0.16557600,0.13470000, &
0.11013600,0.08342720,0.05987030,0.03938700, &
0.02293650,0.00238849,0.00192400,0.00149921, &
0.00103539,0.00067150,0.00024822,0.00003348, &
0.18535601,0.19407199,0.16053200,0.13300700, &
0.10779000,0.08408500,0.06480450,0.04070160, &
0.02203590,0.00227779,0.00189074,0.00146888, &
0.00103147,0.00066770,0.00024751,0.00003348, &
0.19139200,0.18917400,0.15748601,0.13240699, &
0.10557300,0.08383260,0.06724060,0.04364450, &
0.02175820,0.00225436,0.00184421,0.00143153, &
0.00103027,0.00066066,0.00024222,0.00003148, &
0.19547801,0.18539500,0.15442000,0.13114899, &
0.10515600,0.08350350,0.06909780,0.04671630, &
0.02168820,0.00224400,0.00182009,0.00139098, &
0.00102582,0.00065367,0.00023202,0.00003148, &
0.19757500,0.18266800,0.15208900,0.12897800, &
0.10637200,0.08391220,0.06989830,0.04964120, &
0.02155800,0.00224310,0.00177358,0.00138184, &
0.00101538,0.00063370,0.00023227,0.00003148, &
0.20145500,0.17692900,0.14940600,0.12690400, &
0.10828800,0.08553720,0.07004940,0.05153430, &
0.02268740,0.00216943,0.00178603,0.00137754, &
0.00098344,0.00063165,0.00023218,0.00003148, &
0.20383500,0.17047501,0.14570600,0.12679300, &
0.11043100,0.08719150,0.07045440,0.05345420, &
0.02448340,0.00215839,0.00175893,0.00138296, &
0.00098318,0.00063188,0.00023199,0.00003148, &
0.18680701,0.15961801,0.15092900,0.13049100, &
0.11418400,0.09380540,0.07093450,0.05664280, &
0.02938410,0.00217751,0.00176766,0.00138275, &
0.00098377,0.00063181,0.00023193,0.00003148/
!
! end of data 3
!
!-----------------------------------------------------------------------
! start data 4
DATA NXMOL /2/
DATA IXINDX /0,2,3,0,31*0/
!
! end of data 4
!
!-----------------------------------------------------------------------
! start data 5
!
! Longwave spectral band data
DATA WAVENUM1(1) /10./, WAVENUM2(1) /250./, DELWAVE(1) /240./
DATA WAVENUM1(2) /250./, WAVENUM2(2) /500./, DELWAVE(2) /250./
DATA WAVENUM1(3) /500./, WAVENUM2(3) /630./, DELWAVE(3) /130./
DATA WAVENUM1(4) /630./, WAVENUM2(4) /700./, DELWAVE(4) /70./
DATA WAVENUM1(5) /700./, WAVENUM2(5) /820./, DELWAVE(5) /120./
DATA WAVENUM1(6) /820./, WAVENUM2(6) /980./, DELWAVE(6) /160./
DATA WAVENUM1(7) /980./, WAVENUM2(7) /1080./, DELWAVE(7) /100./
DATA WAVENUM1(8) /1080./, WAVENUM2(8) /1180./, DELWAVE(8) /100./
DATA WAVENUM1(9) /1180./, WAVENUM2(9) /1390./, DELWAVE(9) /210./
DATA WAVENUM1(10) /1390./,WAVENUM2(10) /1480./,DELWAVE(10) /90./
DATA WAVENUM1(11) /1480./,WAVENUM2(11) /1800./,DELWAVE(11) /320./
DATA WAVENUM1(12) /1800./,WAVENUM2(12) /2080./,DELWAVE(12) /280./
DATA WAVENUM1(13) /2080./,WAVENUM2(13) /2250./,DELWAVE(13) /170./
DATA WAVENUM1(14) /2250./,WAVENUM2(14) /2380./,DELWAVE(14) /130./
DATA WAVENUM1(15) /2380./,WAVENUM2(15) /2600./,DELWAVE(15) /220./
DATA WAVENUM1(16) /2600./,WAVENUM2(16) /3000./,DELWAVE(16) /400./
!
! end of data 5
!
!-----------------------------------------------------------------------
! start data 6
DATA NG /16,16,16,16,16,16,16,16,16,16,16,16,16,16,16,16/
DATA NSPA /1, 1,10, 9, 9, 1, 9, 1,11, 1, 1, 9, 9, 1, 9, 9/
DATA NSPB /1, 1, 5, 6, 5, 0, 1, 1, 1, 1, 1, 0, 0, 1, 0, 0/
! HEATFAC is the factor by which one must multiply delta-flux/
! delta-pressure, with flux in w/m-2 and pressure in mbar, to get
! the heating rate in units of degrees/day. It is equal to
! (g)x(#sec/day)x(1e-5)/(specific heat of air at const. p)
! = (9.8066)(3600)(1e-5)/(1.004)
DATA HEATFAC /8.4391/
! These pressures are chosen such that the ln of the first pressure
! has only a few non-zero digits (i.e. ln(PREF(1)) = 6.96000) and
! each subsequent ln(pressure) differs from the previous one by 0.2.
DATA PREF / &
1.05363E+03,8.62642E+02,7.06272E+02,5.78246E+02,4.73428E+02, &
3.87610E+02,3.17348E+02,2.59823E+02,2.12725E+02,1.74164E+02, &
1.42594E+02,1.16746E+02,9.55835E+01,7.82571E+01,6.40715E+01, &
5.24573E+01,4.29484E+01,3.51632E+01,2.87892E+01,2.35706E+01, &
1.92980E+01,1.57998E+01,1.29358E+01,1.05910E+01,8.67114E+00, &
7.09933E+00,5.81244E+00,4.75882E+00,3.89619E+00,3.18993E+00, &
2.61170E+00,2.13828E+00,1.75067E+00,1.43333E+00,1.17351E+00, &
9.60789E-01,7.86628E-01,6.44036E-01,5.27292E-01,4.31710E-01, &
3.53455E-01,2.89384E-01,2.36928E-01,1.93980E-01,1.58817E-01, &
1.30029E-01,1.06458E-01,8.71608E-02,7.13612E-02,5.84256E-02, &
4.78349E-02,3.91639E-02,3.20647E-02,2.62523E-02,2.14936E-02, &
1.75975E-02,1.44076E-02,1.17959E-02,9.65769E-03/
DATA PREFLOG / &
6.9600E+00, 6.7600E+00, 6.5600E+00, 6.3600E+00, 6.1600E+00, &
5.9600E+00, 5.7600E+00, 5.5600E+00, 5.3600E+00, 5.1600E+00, &
4.9600E+00, 4.7600E+00, 4.5600E+00, 4.3600E+00, 4.1600E+00, &
3.9600E+00, 3.7600E+00, 3.5600E+00, 3.3600E+00, 3.1600E+00, &
2.9600E+00, 2.7600E+00, 2.5600E+00, 2.3600E+00, 2.1600E+00, &
1.9600E+00, 1.7600E+00, 1.5600E+00, 1.3600E+00, 1.1600E+00, &
9.6000E-01, 7.6000E-01, 5.6000E-01, 3.6000E-01, 1.6000E-01, &
-4.0000E-02,-2.4000E-01,-4.4000E-01,-6.4000E-01,-8.4000E-01, &
-1.0400E+00,-1.2400E+00,-1.4400E+00,-1.6400E+00,-1.8400E+00, &
-2.0400E+00,-2.2400E+00,-2.4400E+00,-2.6400E+00,-2.8400E+00, &
-3.0400E+00,-3.2400E+00,-3.4400E+00,-3.6400E+00,-3.8400E+00, &
-4.0400E+00,-4.2400E+00,-4.4400E+00,-4.6400E+00/
! These are the temperatures associated with the respective
! pressures for the MLS standard atmosphere.
DATA TREF / &
2.9420E+02, 2.8799E+02, 2.7894E+02, 2.6925E+02, 2.5983E+02, &
2.5017E+02, 2.4077E+02, 2.3179E+02, 2.2306E+02, 2.1578E+02, &
2.1570E+02, 2.1570E+02, 2.1570E+02, 2.1706E+02, 2.1858E+02, &
2.2018E+02, 2.2174E+02, 2.2328E+02, 2.2479E+02, 2.2655E+02, &
2.2834E+02, 2.3113E+02, 2.3401E+02, 2.3703E+02, 2.4022E+02, &
2.4371E+02, 2.4726E+02, 2.5085E+02, 2.5457E+02, 2.5832E+02, &
2.6216E+02, 2.6606E+02, 2.6999E+02, 2.7340E+02, 2.7536E+02, &
2.7568E+02, 2.7372E+02, 2.7163E+02, 2.6955E+02, 2.6593E+02, &
2.6211E+02, 2.5828E+02, 2.5360E+02, 2.4854E+02, 2.4348E+02, &
2.3809E+02, 2.3206E+02, 2.2603E+02, 2.2000E+02, 2.1435E+02, &
2.0887E+02, 2.0340E+02, 1.9792E+02, 1.9290E+02, 1.8809E+02, &
1.8329E+02, 1.7849E+02, 1.7394E+02, 1.7212E+02/
!
! end of data 6
!
!-----------------------------------------------------------------------
! start data 7
DATA (TOTPLNK(IDATA, 1),IDATA=1,50)/ &
1.13735E-06,1.15150E-06,1.16569E-06,1.17992E-06,1.19419E-06, &
1.20850E-06,1.22285E-06,1.23723E-06,1.25164E-06,1.26610E-06, &
1.28059E-06,1.29511E-06,1.30967E-06,1.32426E-06,1.33889E-06, &
1.35355E-06,1.36824E-06,1.38296E-06,1.39772E-06,1.41250E-06, &
1.42732E-06,1.44217E-06,1.45704E-06,1.47195E-06,1.48689E-06, &
1.50185E-06,1.51684E-06,1.53186E-06,1.54691E-06,1.56198E-06, &
1.57709E-06,1.59222E-06,1.60737E-06,1.62255E-06,1.63776E-06, &
1.65299E-06,1.66825E-06,1.68352E-06,1.69883E-06,1.71416E-06, &
1.72951E-06,1.74488E-06,1.76028E-06,1.77570E-06,1.79114E-06, &
1.80661E-06,1.82210E-06,1.83760E-06,1.85313E-06,1.86868E-06/
DATA (TOTPLNK(IDATA, 1),IDATA=51,100)/ &
1.88425E-06,1.89985E-06,1.91546E-06,1.93109E-06,1.94674E-06, &
1.96241E-06,1.97811E-06,1.99381E-06,2.00954E-06,2.02529E-06, &
2.04105E-06,2.05684E-06,2.07264E-06,2.08846E-06,2.10429E-06, &
2.12015E-06,2.13602E-06,2.15190E-06,2.16781E-06,2.18373E-06, &
2.19966E-06,2.21562E-06,2.23159E-06,2.24758E-06,2.26358E-06, &
2.27959E-06,2.29562E-06,2.31167E-06,2.32773E-06,2.34381E-06, &
2.35990E-06,2.37601E-06,2.39212E-06,2.40825E-06,2.42440E-06, &
2.44056E-06,2.45673E-06,2.47292E-06,2.48912E-06,2.50533E-06, &
2.52157E-06,2.53781E-06,2.55406E-06,2.57032E-06,2.58660E-06, &
2.60289E-06,2.61919E-06,2.63550E-06,2.65183E-06,2.66817E-06/
DATA (TOTPLNK(IDATA, 1),IDATA=101,150)/ &
2.68452E-06,2.70088E-06,2.71726E-06,2.73364E-06,2.75003E-06, &
2.76644E-06,2.78286E-06,2.79929E-06,2.81572E-06,2.83218E-06, &
2.84864E-06,2.86510E-06,2.88159E-06,2.89807E-06,2.91458E-06, &
2.93109E-06,2.94762E-06,2.96415E-06,2.98068E-06,2.99724E-06, &
3.01379E-06,3.03036E-06,3.04693E-06,3.06353E-06,3.08013E-06, &
3.09674E-06,3.11335E-06,3.12998E-06,3.14661E-06,3.16324E-06, &
3.17989E-06,3.19656E-06,3.21323E-06,3.22991E-06,3.24658E-06, &
3.26328E-06,3.27998E-06,3.29669E-06,3.31341E-06,3.33013E-06, &
3.34686E-06,3.36360E-06,3.38034E-06,3.39709E-06,3.41387E-06, &
3.43063E-06,3.44742E-06,3.46420E-06,3.48099E-06,3.49779E-06/
DATA (TOTPLNK(IDATA, 1),IDATA=151,181)/ &
3.51461E-06,3.53141E-06,3.54824E-06,3.56506E-06,3.58191E-06, &
3.59875E-06,3.61559E-06,3.63244E-06,3.64931E-06,3.66617E-06, &
3.68305E-06,3.69992E-06,3.71682E-06,3.73372E-06,3.75061E-06, &
3.76753E-06,3.78443E-06,3.80136E-06,3.81829E-06,3.83522E-06, &
3.85215E-06,3.86910E-06,3.88605E-06,3.90301E-06,3.91997E-06, &
3.93694E-06,3.95390E-06,3.97087E-06,3.98788E-06,4.00485E-06, &
4.02187E-06/
DATA (TOTPLNK(IDATA, 2),IDATA=1,50)/ &
2.13441E-06,2.18076E-06,2.22758E-06,2.27489E-06,2.32268E-06, &
2.37093E-06,2.41966E-06,2.46886E-06,2.51852E-06,2.56864E-06, &
2.61922E-06,2.67026E-06,2.72175E-06,2.77370E-06,2.82609E-06, &
2.87893E-06,2.93221E-06,2.98593E-06,3.04008E-06,3.09468E-06, &
3.14970E-06,3.20515E-06,3.26103E-06,3.31732E-06,3.37404E-06, &
3.43118E-06,3.48873E-06,3.54669E-06,3.60506E-06,3.66383E-06, &
3.72301E-06,3.78259E-06,3.84256E-06,3.90293E-06,3.96368E-06, &
4.02483E-06,4.08636E-06,4.14828E-06,4.21057E-06,4.27324E-06, &
4.33629E-06,4.39971E-06,4.46350E-06,4.52765E-06,4.59217E-06, &
4.65705E-06,4.72228E-06,4.78787E-06,4.85382E-06,4.92011E-06/
DATA (TOTPLNK(IDATA, 2),IDATA=51,100)/ &
4.98675E-06,5.05374E-06,5.12106E-06,5.18873E-06,5.25674E-06, &
5.32507E-06,5.39374E-06,5.46274E-06,5.53207E-06,5.60172E-06, &
5.67169E-06,5.74198E-06,5.81259E-06,5.88352E-06,5.95475E-06, &
6.02629E-06,6.09815E-06,6.17030E-06,6.24276E-06,6.31552E-06, &
6.38858E-06,6.46192E-06,6.53557E-06,6.60950E-06,6.68373E-06, &
6.75824E-06,6.83303E-06,6.90810E-06,6.98346E-06,7.05909E-06, &
7.13500E-06,7.21117E-06,7.28763E-06,7.36435E-06,7.44134E-06, &
7.51859E-06,7.59611E-06,7.67388E-06,7.75192E-06,7.83021E-06, &
7.90875E-06,7.98755E-06,8.06660E-06,8.14589E-06,8.22544E-06, &
8.30522E-06,8.38526E-06,8.46553E-06,8.54604E-06,8.62679E-06/
DATA (TOTPLNK(IDATA, 2),IDATA=101,150)/ &
8.70777E-06,8.78899E-06,8.87043E-06,8.95211E-06,9.03402E-06, &
9.11616E-06,9.19852E-06,9.28109E-06,9.36390E-06,9.44692E-06, &
9.53015E-06,9.61361E-06,9.69729E-06,9.78117E-06,9.86526E-06, &
9.94957E-06,1.00341E-05,1.01188E-05,1.02037E-05,1.02888E-05, &
1.03742E-05,1.04597E-05,1.05454E-05,1.06313E-05,1.07175E-05, &
1.08038E-05,1.08903E-05,1.09770E-05,1.10639E-05,1.11509E-05, &
1.12382E-05,1.13257E-05,1.14133E-05,1.15011E-05,1.15891E-05, &
1.16773E-05,1.17656E-05,1.18542E-05,1.19429E-05,1.20317E-05, &
1.21208E-05,1.22100E-05,1.22994E-05,1.23890E-05,1.24787E-05, &
1.25686E-05,1.26587E-05,1.27489E-05,1.28393E-05,1.29299E-05/
DATA (TOTPLNK(IDATA, 2),IDATA=151,181)/ &
1.30206E-05,1.31115E-05,1.32025E-05,1.32937E-05,1.33850E-05, &
1.34765E-05,1.35682E-05,1.36600E-05,1.37520E-05,1.38441E-05, &
1.39364E-05,1.40288E-05,1.41213E-05,1.42140E-05,1.43069E-05, &
1.43999E-05,1.44930E-05,1.45863E-05,1.46797E-05,1.47733E-05, &
1.48670E-05,1.49608E-05,1.50548E-05,1.51489E-05,1.52431E-05, &
1.53375E-05,1.54320E-05,1.55267E-05,1.56214E-05,1.57164E-05, &
1.58114E-05/
DATA (TOTPLNK(IDATA, 3),IDATA=1,50)/ &
1.34822E-06,1.39134E-06,1.43530E-06,1.48010E-06,1.52574E-06, &
1.57222E-06,1.61956E-06,1.66774E-06,1.71678E-06,1.76666E-06, &
1.81741E-06,1.86901E-06,1.92147E-06,1.97479E-06,2.02898E-06, &
2.08402E-06,2.13993E-06,2.19671E-06,2.25435E-06,2.31285E-06, &
2.37222E-06,2.43246E-06,2.49356E-06,2.55553E-06,2.61837E-06, &
2.68207E-06,2.74664E-06,2.81207E-06,2.87837E-06,2.94554E-06, &
3.01356E-06,3.08245E-06,3.15221E-06,3.22282E-06,3.29429E-06, &
3.36662E-06,3.43982E-06,3.51386E-06,3.58876E-06,3.66451E-06, &
3.74112E-06,3.81857E-06,3.89688E-06,3.97602E-06,4.05601E-06, &
4.13685E-06,4.21852E-06,4.30104E-06,4.38438E-06,4.46857E-06/
DATA (TOTPLNK(IDATA, 3),IDATA=51,100)/ &
4.55358E-06,4.63943E-06,4.72610E-06,4.81359E-06,4.90191E-06, &
4.99105E-06,5.08100E-06,5.17176E-06,5.26335E-06,5.35573E-06, &
5.44892E-06,5.54292E-06,5.63772E-06,5.73331E-06,5.82970E-06, &
5.92688E-06,6.02485E-06,6.12360E-06,6.22314E-06,6.32346E-06, &
6.42455E-06,6.52641E-06,6.62906E-06,6.73247E-06,6.83664E-06, &
6.94156E-06,7.04725E-06,7.15370E-06,7.26089E-06,7.36883E-06, &
7.47752E-06,7.58695E-06,7.69712E-06,7.80801E-06,7.91965E-06, &
8.03201E-06,8.14510E-06,8.25891E-06,8.37343E-06,8.48867E-06, &
8.60463E-06,8.72128E-06,8.83865E-06,8.95672E-06,9.07548E-06, &
9.19495E-06,9.31510E-06,9.43594E-06,9.55745E-06,9.67966E-06/
DATA (TOTPLNK(IDATA, 3),IDATA=101,150)/ &
9.80254E-06,9.92609E-06,1.00503E-05,1.01752E-05,1.03008E-05, &
1.04270E-05,1.05539E-05,1.06814E-05,1.08096E-05,1.09384E-05, &
1.10679E-05,1.11980E-05,1.13288E-05,1.14601E-05,1.15922E-05, &
1.17248E-05,1.18581E-05,1.19920E-05,1.21265E-05,1.22616E-05, &
1.23973E-05,1.25337E-05,1.26706E-05,1.28081E-05,1.29463E-05, &
1.30850E-05,1.32243E-05,1.33642E-05,1.35047E-05,1.36458E-05, &
1.37875E-05,1.39297E-05,1.40725E-05,1.42159E-05,1.43598E-05, &
1.45044E-05,1.46494E-05,1.47950E-05,1.49412E-05,1.50879E-05, &
1.52352E-05,1.53830E-05,1.55314E-05,1.56803E-05,1.58297E-05, &
1.59797E-05,1.61302E-05,1.62812E-05,1.64327E-05,1.65848E-05/
DATA (TOTPLNK(IDATA, 3),IDATA=151,181)/ &
1.67374E-05,1.68904E-05,1.70441E-05,1.71982E-05,1.73528E-05, &
1.75079E-05,1.76635E-05,1.78197E-05,1.79763E-05,1.81334E-05, &
1.82910E-05,1.84491E-05,1.86076E-05,1.87667E-05,1.89262E-05, &
1.90862E-05,1.92467E-05,1.94076E-05,1.95690E-05,1.97309E-05, &
1.98932E-05,2.00560E-05,2.02193E-05,2.03830E-05,2.05472E-05, &
2.07118E-05,2.08768E-05,2.10423E-05,2.12083E-05,2.13747E-05, &
2.15414E-05/
DATA (TOTPLNK(IDATA, 4),IDATA=1,50)/ &
8.90528E-07,9.24222E-07,9.58757E-07,9.94141E-07,1.03038E-06, &
1.06748E-06,1.10545E-06,1.14430E-06,1.18403E-06,1.22465E-06, &
1.26618E-06,1.30860E-06,1.35193E-06,1.39619E-06,1.44136E-06, &
1.48746E-06,1.53449E-06,1.58246E-06,1.63138E-06,1.68124E-06, &
1.73206E-06,1.78383E-06,1.83657E-06,1.89028E-06,1.94495E-06, &
2.00060E-06,2.05724E-06,2.11485E-06,2.17344E-06,2.23303E-06, &
2.29361E-06,2.35519E-06,2.41777E-06,2.48134E-06,2.54592E-06, &
2.61151E-06,2.67810E-06,2.74571E-06,2.81433E-06,2.88396E-06, &
2.95461E-06,3.02628E-06,3.09896E-06,3.17267E-06,3.24741E-06, &
3.32316E-06,3.39994E-06,3.47774E-06,3.55657E-06,3.63642E-06/
DATA (TOTPLNK(IDATA, 4),IDATA=51,100)/ &
3.71731E-06,3.79922E-06,3.88216E-06,3.96612E-06,4.05112E-06, &
4.13714E-06,4.22419E-06,4.31227E-06,4.40137E-06,4.49151E-06, &
4.58266E-06,4.67485E-06,4.76806E-06,4.86229E-06,4.95754E-06, &
5.05383E-06,5.15113E-06,5.24946E-06,5.34879E-06,5.44916E-06, &
5.55053E-06,5.65292E-06,5.75632E-06,5.86073E-06,5.96616E-06, &
6.07260E-06,6.18003E-06,6.28848E-06,6.39794E-06,6.50838E-06, &
6.61983E-06,6.73229E-06,6.84573E-06,6.96016E-06,7.07559E-06, &
7.19200E-06,7.30940E-06,7.42779E-06,7.54715E-06,7.66749E-06, &
7.78882E-06,7.91110E-06,8.03436E-06,8.15859E-06,8.28379E-06, &
8.40994E-06,8.53706E-06,8.66515E-06,8.79418E-06,8.92416E-06/
DATA (TOTPLNK(IDATA, 4),IDATA=101,150)/ &
9.05510E-06,9.18697E-06,9.31979E-06,9.45356E-06,9.58826E-06, &
9.72389E-06,9.86046E-06,9.99793E-06,1.01364E-05,1.02757E-05, &
1.04159E-05,1.05571E-05,1.06992E-05,1.08422E-05,1.09861E-05, &
1.11309E-05,1.12766E-05,1.14232E-05,1.15707E-05,1.17190E-05, &
1.18683E-05,1.20184E-05,1.21695E-05,1.23214E-05,1.24741E-05, &
1.26277E-05,1.27822E-05,1.29376E-05,1.30939E-05,1.32509E-05, &
1.34088E-05,1.35676E-05,1.37273E-05,1.38877E-05,1.40490E-05, &
1.42112E-05,1.43742E-05,1.45380E-05,1.47026E-05,1.48680E-05, &
1.50343E-05,1.52014E-05,1.53692E-05,1.55379E-05,1.57074E-05, &
1.58778E-05,1.60488E-05,1.62207E-05,1.63934E-05,1.65669E-05/
DATA (TOTPLNK(IDATA, 4),IDATA=151,181)/ &
1.67411E-05,1.69162E-05,1.70920E-05,1.72685E-05,1.74459E-05, &
1.76240E-05,1.78029E-05,1.79825E-05,1.81629E-05,1.83440E-05, &
1.85259E-05,1.87086E-05,1.88919E-05,1.90760E-05,1.92609E-05, &
1.94465E-05,1.96327E-05,1.98199E-05,2.00076E-05,2.01961E-05, &
2.03853E-05,2.05752E-05,2.07658E-05,2.09571E-05,2.11491E-05, &
2.13418E-05,2.15352E-05,2.17294E-05,2.19241E-05,2.21196E-05, &
2.23158E-05/
DATA (TOTPLNK(IDATA, 5),IDATA=1,50)/ &
5.70230E-07,5.94788E-07,6.20085E-07,6.46130E-07,6.72936E-07, &
7.00512E-07,7.28869E-07,7.58019E-07,7.87971E-07,8.18734E-07, &
8.50320E-07,8.82738E-07,9.15999E-07,9.50110E-07,9.85084E-07, &
1.02093E-06,1.05765E-06,1.09527E-06,1.13378E-06,1.17320E-06, &
1.21353E-06,1.25479E-06,1.29698E-06,1.34011E-06,1.38419E-06, &
1.42923E-06,1.47523E-06,1.52221E-06,1.57016E-06,1.61910E-06, &
1.66904E-06,1.71997E-06,1.77192E-06,1.82488E-06,1.87886E-06, &
1.93387E-06,1.98991E-06,2.04699E-06,2.10512E-06,2.16430E-06, &
2.22454E-06,2.28584E-06,2.34821E-06,2.41166E-06,2.47618E-06, &
2.54178E-06,2.60847E-06,2.67626E-06,2.74514E-06,2.81512E-06/
DATA (TOTPLNK(IDATA, 5),IDATA=51,100)/ &
2.88621E-06,2.95841E-06,3.03172E-06,3.10615E-06,3.18170E-06, &
3.25838E-06,3.33618E-06,3.41511E-06,3.49518E-06,3.57639E-06, &
3.65873E-06,3.74221E-06,3.82684E-06,3.91262E-06,3.99955E-06, &
4.08763E-06,4.17686E-06,4.26725E-06,4.35880E-06,4.45150E-06, &
4.54537E-06,4.64039E-06,4.73659E-06,4.83394E-06,4.93246E-06, &
5.03215E-06,5.13301E-06,5.23504E-06,5.33823E-06,5.44260E-06, &
5.54814E-06,5.65484E-06,5.76272E-06,5.87177E-06,5.98199E-06, &
6.09339E-06,6.20596E-06,6.31969E-06,6.43460E-06,6.55068E-06, &
6.66793E-06,6.78636E-06,6.90595E-06,7.02670E-06,7.14863E-06, &
7.27173E-06,7.39599E-06,7.52142E-06,7.64802E-06,7.77577E-06/
DATA (TOTPLNK(IDATA, 5),IDATA=101,150)/ &
7.90469E-06,8.03477E-06,8.16601E-06,8.29841E-06,8.43198E-06, &
8.56669E-06,8.70256E-06,8.83957E-06,8.97775E-06,9.11706E-06, &
9.25753E-06,9.39915E-06,9.54190E-06,9.68580E-06,9.83085E-06, &
9.97704E-06,1.01243E-05,1.02728E-05,1.04224E-05,1.05731E-05, &
1.07249E-05,1.08779E-05,1.10320E-05,1.11872E-05,1.13435E-05, &
1.15009E-05,1.16595E-05,1.18191E-05,1.19799E-05,1.21418E-05, &
1.23048E-05,1.24688E-05,1.26340E-05,1.28003E-05,1.29676E-05, &
1.31361E-05,1.33056E-05,1.34762E-05,1.36479E-05,1.38207E-05, &
1.39945E-05,1.41694E-05,1.43454E-05,1.45225E-05,1.47006E-05, &
1.48797E-05,1.50600E-05,1.52413E-05,1.54236E-05,1.56070E-05/
DATA (TOTPLNK(IDATA, 5),IDATA=151,181)/ &
1.57914E-05,1.59768E-05,1.61633E-05,1.63509E-05,1.65394E-05, &
1.67290E-05,1.69197E-05,1.71113E-05,1.73040E-05,1.74976E-05, &
1.76923E-05,1.78880E-05,1.80847E-05,1.82824E-05,1.84811E-05, &
1.86808E-05,1.88814E-05,1.90831E-05,1.92857E-05,1.94894E-05, &
1.96940E-05,1.98996E-05,2.01061E-05,2.03136E-05,2.05221E-05, &
2.07316E-05,2.09420E-05,2.11533E-05,2.13657E-05,2.15789E-05, &
2.17931E-05/
DATA (TOTPLNK(IDATA, 6),IDATA=1,50)/ &
2.73493E-07,2.87408E-07,3.01848E-07,3.16825E-07,3.32352E-07, &
3.48439E-07,3.65100E-07,3.82346E-07,4.00189E-07,4.18641E-07, &
4.37715E-07,4.57422E-07,4.77774E-07,4.98784E-07,5.20464E-07, &
5.42824E-07,5.65879E-07,5.89638E-07,6.14115E-07,6.39320E-07, &
6.65266E-07,6.91965E-07,7.19427E-07,7.47666E-07,7.76691E-07, &
8.06516E-07,8.37151E-07,8.68607E-07,9.00896E-07,9.34029E-07, &
9.68018E-07,1.00287E-06,1.03860E-06,1.07522E-06,1.11274E-06, &
1.15117E-06,1.19052E-06,1.23079E-06,1.27201E-06,1.31418E-06, &
1.35731E-06,1.40141E-06,1.44650E-06,1.49257E-06,1.53965E-06, &
1.58773E-06,1.63684E-06,1.68697E-06,1.73815E-06,1.79037E-06/
DATA (TOTPLNK(IDATA, 6),IDATA=51,100)/ &
1.84365E-06,1.89799E-06,1.95341E-06,2.00991E-06,2.06750E-06, &
2.12619E-06,2.18599E-06,2.24691E-06,2.30895E-06,2.37212E-06, &
2.43643E-06,2.50189E-06,2.56851E-06,2.63628E-06,2.70523E-06, &
2.77536E-06,2.84666E-06,2.91916E-06,2.99286E-06,3.06776E-06, &
3.14387E-06,3.22120E-06,3.29975E-06,3.37953E-06,3.46054E-06, &
3.54280E-06,3.62630E-06,3.71105E-06,3.79707E-06,3.88434E-06, &
3.97288E-06,4.06270E-06,4.15380E-06,4.24617E-06,4.33984E-06, &
4.43479E-06,4.53104E-06,4.62860E-06,4.72746E-06,4.82763E-06, &
4.92911E-06,5.03191E-06,5.13603E-06,5.24147E-06,5.34824E-06, &
5.45634E-06,5.56578E-06,5.67656E-06,5.78867E-06,5.90213E-06/
DATA (TOTPLNK(IDATA, 6),IDATA=101,150)/ &
6.01694E-06,6.13309E-06,6.25060E-06,6.36947E-06,6.48968E-06, &
6.61126E-06,6.73420E-06,6.85850E-06,6.98417E-06,7.11120E-06, &
7.23961E-06,7.36938E-06,7.50053E-06,7.63305E-06,7.76694E-06, &
7.90221E-06,8.03887E-06,8.17690E-06,8.31632E-06,8.45710E-06, &
8.59928E-06,8.74282E-06,8.88776E-06,9.03409E-06,9.18179E-06, &
9.33088E-06,9.48136E-06,9.63323E-06,9.78648E-06,9.94111E-06, &
1.00971E-05,1.02545E-05,1.04133E-05,1.05735E-05,1.07351E-05, &
1.08980E-05,1.10624E-05,1.12281E-05,1.13952E-05,1.15637E-05, &
1.17335E-05,1.19048E-05,1.20774E-05,1.22514E-05,1.24268E-05, &
1.26036E-05,1.27817E-05,1.29612E-05,1.31421E-05,1.33244E-05/
DATA (TOTPLNK(IDATA, 6),IDATA=151,181)/ &
1.35080E-05,1.36930E-05,1.38794E-05,1.40672E-05,1.42563E-05, &
1.44468E-05,1.46386E-05,1.48318E-05,1.50264E-05,1.52223E-05, &
1.54196E-05,1.56182E-05,1.58182E-05,1.60196E-05,1.62223E-05, &
1.64263E-05,1.66317E-05,1.68384E-05,1.70465E-05,1.72559E-05, &
1.74666E-05,1.76787E-05,1.78921E-05,1.81069E-05,1.83230E-05, &
1.85404E-05,1.87591E-05,1.89791E-05,1.92005E-05,1.94232E-05, &
1.96471E-05/
DATA (TOTPLNK(IDATA, 7),IDATA=1,50)/ &
1.25349E-07,1.32735E-07,1.40458E-07,1.48527E-07,1.56954E-07, &
1.65748E-07,1.74920E-07,1.84481E-07,1.94443E-07,2.04814E-07, &
2.15608E-07,2.26835E-07,2.38507E-07,2.50634E-07,2.63229E-07, &
2.76301E-07,2.89864E-07,3.03930E-07,3.18508E-07,3.33612E-07, &
3.49253E-07,3.65443E-07,3.82195E-07,3.99519E-07,4.17428E-07, &
4.35934E-07,4.55050E-07,4.74785E-07,4.95155E-07,5.16170E-07, &
5.37844E-07,5.60186E-07,5.83211E-07,6.06929E-07,6.31355E-07, &
6.56498E-07,6.82373E-07,7.08990E-07,7.36362E-07,7.64501E-07, &
7.93420E-07,8.23130E-07,8.53643E-07,8.84971E-07,9.17128E-07, &
9.50123E-07,9.83969E-07,1.01868E-06,1.05426E-06,1.09073E-06/
DATA (TOTPLNK(IDATA, 7),IDATA=51,100)/ &
1.12810E-06,1.16638E-06,1.20558E-06,1.24572E-06,1.28680E-06, &
1.32883E-06,1.37183E-06,1.41581E-06,1.46078E-06,1.50675E-06, &
1.55374E-06,1.60174E-06,1.65078E-06,1.70087E-06,1.75200E-06, &
1.80421E-06,1.85749E-06,1.91186E-06,1.96732E-06,2.02389E-06, &
2.08159E-06,2.14040E-06,2.20035E-06,2.26146E-06,2.32372E-06, &
2.38714E-06,2.45174E-06,2.51753E-06,2.58451E-06,2.65270E-06, &
2.72210E-06,2.79272E-06,2.86457E-06,2.93767E-06,3.01201E-06, &
3.08761E-06,3.16448E-06,3.24261E-06,3.32204E-06,3.40275E-06, &
3.48476E-06,3.56808E-06,3.65271E-06,3.73866E-06,3.82595E-06, &
3.91456E-06,4.00453E-06,4.09584E-06,4.18851E-06,4.28254E-06/
DATA (TOTPLNK(IDATA, 7),IDATA=101,150)/ &
4.37796E-06,4.47475E-06,4.57293E-06,4.67249E-06,4.77346E-06, &
4.87583E-06,4.97961E-06,5.08481E-06,5.19143E-06,5.29948E-06, &
5.40896E-06,5.51989E-06,5.63226E-06,5.74608E-06,5.86136E-06, &
5.97810E-06,6.09631E-06,6.21597E-06,6.33713E-06,6.45976E-06, &
6.58388E-06,6.70950E-06,6.83661E-06,6.96521E-06,7.09531E-06, &
7.22692E-06,7.36005E-06,7.49468E-06,7.63084E-06,7.76851E-06, &
7.90773E-06,8.04846E-06,8.19072E-06,8.33452E-06,8.47985E-06, &
8.62674E-06,8.77517E-06,8.92514E-06,9.07666E-06,9.22975E-06, &
9.38437E-06,9.54057E-06,9.69832E-06,9.85762E-06,1.00185E-05, &
1.01810E-05,1.03450E-05,1.05106E-05,1.06777E-05,1.08465E-05/
DATA (TOTPLNK(IDATA, 7),IDATA=151,181)/ &
1.10168E-05,1.11887E-05,1.13621E-05,1.15372E-05,1.17138E-05, &
1.18920E-05,1.20718E-05,1.22532E-05,1.24362E-05,1.26207E-05, &
1.28069E-05,1.29946E-05,1.31839E-05,1.33749E-05,1.35674E-05, &
1.37615E-05,1.39572E-05,1.41544E-05,1.43533E-05,1.45538E-05, &
1.47558E-05,1.49595E-05,1.51647E-05,1.53716E-05,1.55800E-05, &
1.57900E-05,1.60017E-05,1.62149E-05,1.64296E-05,1.66460E-05, &
1.68640E-05/
DATA (TOTPLNK(IDATA, 8),IDATA=1,50)/ &
6.74445E-08,7.18176E-08,7.64153E-08,8.12456E-08,8.63170E-08, &
9.16378E-08,9.72168E-08,1.03063E-07,1.09184E-07,1.15591E-07, &
1.22292E-07,1.29296E-07,1.36613E-07,1.44253E-07,1.52226E-07, &
1.60540E-07,1.69207E-07,1.78236E-07,1.87637E-07,1.97421E-07, &
2.07599E-07,2.18181E-07,2.29177E-07,2.40598E-07,2.52456E-07, &
2.64761E-07,2.77523E-07,2.90755E-07,3.04468E-07,3.18673E-07, &
3.33381E-07,3.48603E-07,3.64352E-07,3.80638E-07,3.97474E-07, &
4.14871E-07,4.32841E-07,4.51395E-07,4.70547E-07,4.90306E-07, &
5.10687E-07,5.31699E-07,5.53357E-07,5.75670E-07,5.98652E-07, &
6.22315E-07,6.46672E-07,6.71731E-07,6.97511E-07,7.24018E-07/
DATA (TOTPLNK(IDATA, 8),IDATA=51,100)/ &
7.51266E-07,7.79269E-07,8.08038E-07,8.37584E-07,8.67922E-07, &
8.99061E-07,9.31016E-07,9.63797E-07,9.97417E-07,1.03189E-06, &
1.06722E-06,1.10343E-06,1.14053E-06,1.17853E-06,1.21743E-06, &
1.25726E-06,1.29803E-06,1.33974E-06,1.38241E-06,1.42606E-06, &
1.47068E-06,1.51630E-06,1.56293E-06,1.61056E-06,1.65924E-06, &
1.70894E-06,1.75971E-06,1.81153E-06,1.86443E-06,1.91841E-06, &
1.97350E-06,2.02968E-06,2.08699E-06,2.14543E-06,2.20500E-06, &
2.26573E-06,2.32762E-06,2.39068E-06,2.45492E-06,2.52036E-06, &
2.58700E-06,2.65485E-06,2.72393E-06,2.79424E-06,2.86580E-06, &
2.93861E-06,3.01269E-06,3.08803E-06,3.16467E-06,3.24259E-06/
DATA (TOTPLNK(IDATA, 8),IDATA=101,150)/ &
3.32181E-06,3.40235E-06,3.48420E-06,3.56739E-06,3.65192E-06, &
3.73779E-06,3.82502E-06,3.91362E-06,4.00359E-06,4.09494E-06, &
4.18768E-06,4.28182E-06,4.37737E-06,4.47434E-06,4.57273E-06, &
4.67254E-06,4.77380E-06,4.87651E-06,4.98067E-06,5.08630E-06, &
5.19339E-06,5.30196E-06,5.41201E-06,5.52356E-06,5.63660E-06, &
5.75116E-06,5.86722E-06,5.98479E-06,6.10390E-06,6.22453E-06, &
6.34669E-06,6.47042E-06,6.59569E-06,6.72252E-06,6.85090E-06, &
6.98085E-06,7.11238E-06,7.24549E-06,7.38019E-06,7.51646E-06, &
7.65434E-06,7.79382E-06,7.93490E-06,8.07760E-06,8.22192E-06, &
8.36784E-06,8.51540E-06,8.66459E-06,8.81542E-06,8.96786E-06/
DATA (TOTPLNK(IDATA, 8),IDATA=151,181)/ &
9.12197E-06,9.27772E-06,9.43513E-06,9.59419E-06,9.75490E-06, &
9.91728E-06,1.00813E-05,1.02471E-05,1.04144E-05,1.05835E-05, &
1.07543E-05,1.09267E-05,1.11008E-05,1.12766E-05,1.14541E-05, &
1.16333E-05,1.18142E-05,1.19969E-05,1.21812E-05,1.23672E-05, &
1.25549E-05,1.27443E-05,1.29355E-05,1.31284E-05,1.33229E-05, &
1.35193E-05,1.37173E-05,1.39170E-05,1.41185E-05,1.43217E-05, &
1.45267E-05/
DATA (TOTPLNK(IDATA, 9),IDATA=1,50)/ &
2.61522E-08,2.80613E-08,3.00838E-08,3.22250E-08,3.44899E-08, &
3.68841E-08,3.94129E-08,4.20820E-08,4.48973E-08,4.78646E-08, &
5.09901E-08,5.42799E-08,5.77405E-08,6.13784E-08,6.52001E-08, &
6.92126E-08,7.34227E-08,7.78375E-08,8.24643E-08,8.73103E-08, &
9.23832E-08,9.76905E-08,1.03240E-07,1.09039E-07,1.15097E-07, &
1.21421E-07,1.28020E-07,1.34902E-07,1.42075E-07,1.49548E-07, &
1.57331E-07,1.65432E-07,1.73860E-07,1.82624E-07,1.91734E-07, &
2.01198E-07,2.11028E-07,2.21231E-07,2.31818E-07,2.42799E-07, &
2.54184E-07,2.65983E-07,2.78205E-07,2.90862E-07,3.03963E-07, &
3.17519E-07,3.31541E-07,3.46039E-07,3.61024E-07,3.76507E-07/
DATA (TOTPLNK(IDATA, 9),IDATA=51,100)/ &
3.92498E-07,4.09008E-07,4.26050E-07,4.43633E-07,4.61769E-07, &
4.80469E-07,4.99744E-07,5.19606E-07,5.40067E-07,5.61136E-07, &
5.82828E-07,6.05152E-07,6.28120E-07,6.51745E-07,6.76038E-07, &
7.01010E-07,7.26674E-07,7.53041E-07,7.80124E-07,8.07933E-07, &
8.36482E-07,8.65781E-07,8.95845E-07,9.26683E-07,9.58308E-07, &
9.90732E-07,1.02397E-06,1.05803E-06,1.09292E-06,1.12866E-06, &
1.16526E-06,1.20274E-06,1.24109E-06,1.28034E-06,1.32050E-06, &
1.36158E-06,1.40359E-06,1.44655E-06,1.49046E-06,1.53534E-06, &
1.58120E-06,1.62805E-06,1.67591E-06,1.72478E-06,1.77468E-06, &
1.82561E-06,1.87760E-06,1.93066E-06,1.98479E-06,2.04000E-06/
DATA (TOTPLNK(IDATA, 9),IDATA=101,150)/ &
2.09631E-06,2.15373E-06,2.21228E-06,2.27196E-06,2.33278E-06, &
2.39475E-06,2.45790E-06,2.52222E-06,2.58773E-06,2.65445E-06, &
2.72238E-06,2.79152E-06,2.86191E-06,2.93354E-06,3.00643E-06, &
3.08058E-06,3.15601E-06,3.23273E-06,3.31075E-06,3.39009E-06, &
3.47074E-06,3.55272E-06,3.63605E-06,3.72072E-06,3.80676E-06, &
3.89417E-06,3.98297E-06,4.07315E-06,4.16474E-06,4.25774E-06, &
4.35217E-06,4.44802E-06,4.54532E-06,4.64406E-06,4.74428E-06, &
4.84595E-06,4.94911E-06,5.05376E-06,5.15990E-06,5.26755E-06, &
5.37671E-06,5.48741E-06,5.59963E-06,5.71340E-06,5.82871E-06, &
5.94559E-06,6.06403E-06,6.18404E-06,6.30565E-06,6.42885E-06/
DATA (TOTPLNK(IDATA, 9),IDATA=151,181)/ &
6.55364E-06,6.68004E-06,6.80806E-06,6.93771E-06,7.06898E-06, &
7.20190E-06,7.33646E-06,7.47267E-06,7.61056E-06,7.75010E-06, &
7.89133E-06,8.03423E-06,8.17884E-06,8.32514E-06,8.47314E-06, &
8.62284E-06,8.77427E-06,8.92743E-06,9.08231E-06,9.23893E-06, &
9.39729E-06,9.55741E-06,9.71927E-06,9.88291E-06,1.00483E-05, &
1.02155E-05,1.03844E-05,1.05552E-05,1.07277E-05,1.09020E-05, &
1.10781E-05/
DATA (TOTPLNK(IDATA,10),IDATA=1,50)/ &
8.89300E-09,9.63263E-09,1.04235E-08,1.12685E-08,1.21703E-08, &
1.31321E-08,1.41570E-08,1.52482E-08,1.64090E-08,1.76428E-08, &
1.89533E-08,2.03441E-08,2.18190E-08,2.33820E-08,2.50370E-08, &
2.67884E-08,2.86402E-08,3.05969E-08,3.26632E-08,3.48436E-08, &
3.71429E-08,3.95660E-08,4.21179E-08,4.48040E-08,4.76294E-08, &
5.05996E-08,5.37201E-08,5.69966E-08,6.04349E-08,6.40411E-08, &
6.78211E-08,7.17812E-08,7.59276E-08,8.02670E-08,8.48059E-08, &
8.95508E-08,9.45090E-08,9.96873E-08,1.05093E-07,1.10733E-07, &
1.16614E-07,1.22745E-07,1.29133E-07,1.35786E-07,1.42711E-07, &
1.49916E-07,1.57410E-07,1.65202E-07,1.73298E-07,1.81709E-07/
DATA (TOTPLNK(IDATA,10),IDATA=51,100)/ &
1.90441E-07,1.99505E-07,2.08908E-07,2.18660E-07,2.28770E-07, &
2.39247E-07,2.50101E-07,2.61340E-07,2.72974E-07,2.85013E-07, &
2.97467E-07,3.10345E-07,3.23657E-07,3.37413E-07,3.51623E-07, &
3.66298E-07,3.81448E-07,3.97082E-07,4.13212E-07,4.29848E-07, &
4.47000E-07,4.64680E-07,4.82898E-07,5.01664E-07,5.20991E-07, &
5.40888E-07,5.61369E-07,5.82440E-07,6.04118E-07,6.26410E-07, &
6.49329E-07,6.72887E-07,6.97095E-07,7.21964E-07,7.47506E-07, &
7.73732E-07,8.00655E-07,8.28287E-07,8.56635E-07,8.85717E-07, &
9.15542E-07,9.46122E-07,9.77469E-07,1.00960E-06,1.04251E-06, &
1.07623E-06,1.11077E-06,1.14613E-06,1.18233E-06,1.21939E-06/
DATA (TOTPLNK(IDATA,10),IDATA=101,150)/ &
1.25730E-06,1.29610E-06,1.33578E-06,1.37636E-06,1.41785E-06, &
1.46027E-06,1.50362E-06,1.54792E-06,1.59319E-06,1.63942E-06, &
1.68665E-06,1.73487E-06,1.78410E-06,1.83435E-06,1.88564E-06, &
1.93797E-06,1.99136E-06,2.04582E-06,2.10137E-06,2.15801E-06, &
2.21576E-06,2.27463E-06,2.33462E-06,2.39577E-06,2.45806E-06, &
2.52153E-06,2.58617E-06,2.65201E-06,2.71905E-06,2.78730E-06, &
2.85678E-06,2.92749E-06,2.99946E-06,3.07269E-06,3.14720E-06, &
3.22299E-06,3.30007E-06,3.37847E-06,3.45818E-06,3.53923E-06, &
3.62161E-06,3.70535E-06,3.79046E-06,3.87695E-06,3.96481E-06, &
4.05409E-06,4.14477E-06,4.23687E-06,4.33040E-06,4.42538E-06/
DATA (TOTPLNK(IDATA,10),IDATA=151,181)/ &
4.52180E-06,4.61969E-06,4.71905E-06,4.81991E-06,4.92226E-06, &
5.02611E-06,5.13148E-06,5.23839E-06,5.34681E-06,5.45681E-06, &
5.56835E-06,5.68146E-06,5.79614E-06,5.91242E-06,6.03030E-06, &
6.14978E-06,6.27088E-06,6.39360E-06,6.51798E-06,6.64398E-06, &
6.77165E-06,6.90099E-06,7.03198E-06,7.16468E-06,7.29906E-06, &
7.43514E-06,7.57294E-06,7.71244E-06,7.85369E-06,7.99666E-06, &
8.14138E-06/
DATA (TOTPLNK(IDATA,11),IDATA=1,50)/ &
2.53767E-09,2.77242E-09,3.02564E-09,3.29851E-09,3.59228E-09, &
3.90825E-09,4.24777E-09,4.61227E-09,5.00322E-09,5.42219E-09, &
5.87080E-09,6.35072E-09,6.86370E-09,7.41159E-09,7.99628E-09, &
8.61974E-09,9.28404E-09,9.99130E-09,1.07437E-08,1.15436E-08, &
1.23933E-08,1.32953E-08,1.42522E-08,1.52665E-08,1.63410E-08, &
1.74786E-08,1.86820E-08,1.99542E-08,2.12985E-08,2.27179E-08, &
2.42158E-08,2.57954E-08,2.74604E-08,2.92141E-08,3.10604E-08, &
3.30029E-08,3.50457E-08,3.71925E-08,3.94476E-08,4.18149E-08, &
4.42991E-08,4.69043E-08,4.96352E-08,5.24961E-08,5.54921E-08, &
5.86277E-08,6.19081E-08,6.53381E-08,6.89231E-08,7.26681E-08/
DATA (TOTPLNK(IDATA,11),IDATA=51,100)/ &
7.65788E-08,8.06604E-08,8.49187E-08,8.93591E-08,9.39879E-08, &
9.88106E-08,1.03834E-07,1.09063E-07,1.14504E-07,1.20165E-07, &
1.26051E-07,1.32169E-07,1.38525E-07,1.45128E-07,1.51982E-07, &
1.59096E-07,1.66477E-07,1.74132E-07,1.82068E-07,1.90292E-07, &
1.98813E-07,2.07638E-07,2.16775E-07,2.26231E-07,2.36015E-07, &
2.46135E-07,2.56599E-07,2.67415E-07,2.78592E-07,2.90137E-07, &
3.02061E-07,3.14371E-07,3.27077E-07,3.40186E-07,3.53710E-07, &
3.67655E-07,3.82031E-07,3.96848E-07,4.12116E-07,4.27842E-07, &
4.44039E-07,4.60713E-07,4.77876E-07,4.95537E-07,5.13706E-07, &
5.32392E-07,5.51608E-07,5.71360E-07,5.91662E-07,6.12521E-07/
DATA (TOTPLNK(IDATA,11),IDATA=101,150)/ &
6.33950E-07,6.55958E-07,6.78556E-07,7.01753E-07,7.25562E-07, &
7.49992E-07,7.75055E-07,8.00760E-07,8.27120E-07,8.54145E-07, &
8.81845E-07,9.10233E-07,9.39318E-07,9.69113E-07,9.99627E-07, &
1.03087E-06,1.06286E-06,1.09561E-06,1.12912E-06,1.16340E-06, &
1.19848E-06,1.23435E-06,1.27104E-06,1.30855E-06,1.34690E-06, &
1.38609E-06,1.42614E-06,1.46706E-06,1.50886E-06,1.55155E-06, &
1.59515E-06,1.63967E-06,1.68512E-06,1.73150E-06,1.77884E-06, &
1.82715E-06,1.87643E-06,1.92670E-06,1.97797E-06,2.03026E-06, &
2.08356E-06,2.13791E-06,2.19330E-06,2.24975E-06,2.30728E-06, &
2.36589E-06,2.42560E-06,2.48641E-06,2.54835E-06,2.61142E-06/
DATA (TOTPLNK(IDATA,11),IDATA=151,181)/ &
2.67563E-06,2.74100E-06,2.80754E-06,2.87526E-06,2.94417E-06, &
3.01429E-06,3.08562E-06,3.15819E-06,3.23199E-06,3.30704E-06, &
3.38336E-06,3.46096E-06,3.53984E-06,3.62002E-06,3.70151E-06, &
3.78433E-06,3.86848E-06,3.95399E-06,4.04084E-06,4.12907E-06, &
4.21868E-06,4.30968E-06,4.40209E-06,4.49592E-06,4.59117E-06, &
4.68786E-06,4.78600E-06,4.88561E-06,4.98669E-06,5.08926E-06, &
5.19332E-06/
DATA (TOTPLNK(IDATA,12),IDATA=1,50)/ &
2.73921E-10,3.04500E-10,3.38056E-10,3.74835E-10,4.15099E-10, &
4.59126E-10,5.07214E-10,5.59679E-10,6.16857E-10,6.79103E-10, &
7.46796E-10,8.20335E-10,9.00144E-10,9.86671E-10,1.08039E-09, &
1.18180E-09,1.29142E-09,1.40982E-09,1.53757E-09,1.67529E-09, &
1.82363E-09,1.98327E-09,2.15492E-09,2.33932E-09,2.53726E-09, &
2.74957E-09,2.97710E-09,3.22075E-09,3.48145E-09,3.76020E-09, &
4.05801E-09,4.37595E-09,4.71513E-09,5.07672E-09,5.46193E-09, &
5.87201E-09,6.30827E-09,6.77205E-09,7.26480E-09,7.78794E-09, &
8.34304E-09,8.93163E-09,9.55537E-09,1.02159E-08,1.09151E-08, &
1.16547E-08,1.24365E-08,1.32625E-08,1.41348E-08,1.50554E-08/
DATA (TOTPLNK(IDATA,12),IDATA=51,100)/ &
1.60264E-08,1.70500E-08,1.81285E-08,1.92642E-08,2.04596E-08, &
2.17171E-08,2.30394E-08,2.44289E-08,2.58885E-08,2.74209E-08, &
2.90290E-08,3.07157E-08,3.24841E-08,3.43371E-08,3.62782E-08, &
3.83103E-08,4.04371E-08,4.26617E-08,4.49878E-08,4.74190E-08, &
4.99589E-08,5.26113E-08,5.53801E-08,5.82692E-08,6.12826E-08, &
6.44245E-08,6.76991E-08,7.11105E-08,7.46634E-08,7.83621E-08, &
8.22112E-08,8.62154E-08,9.03795E-08,9.47081E-08,9.92066E-08, &
1.03879E-07,1.08732E-07,1.13770E-07,1.18998E-07,1.24422E-07, &
1.30048E-07,1.35880E-07,1.41924E-07,1.48187E-07,1.54675E-07, &
1.61392E-07,1.68346E-07,1.75543E-07,1.82988E-07,1.90688E-07/
DATA (TOTPLNK(IDATA,12),IDATA=101,150)/ &
1.98650E-07,2.06880E-07,2.15385E-07,2.24172E-07,2.33247E-07, &
2.42617E-07,2.52289E-07,2.62272E-07,2.72571E-07,2.83193E-07, &
2.94147E-07,3.05440E-07,3.17080E-07,3.29074E-07,3.41430E-07, &
3.54155E-07,3.67259E-07,3.80747E-07,3.94631E-07,4.08916E-07, &
4.23611E-07,4.38725E-07,4.54267E-07,4.70245E-07,4.86666E-07, &
5.03541E-07,5.20879E-07,5.38687E-07,5.56975E-07,5.75751E-07, &
5.95026E-07,6.14808E-07,6.35107E-07,6.55932E-07,6.77293E-07, &
6.99197E-07,7.21656E-07,7.44681E-07,7.68278E-07,7.92460E-07, &
8.17235E-07,8.42614E-07,8.68606E-07,8.95223E-07,9.22473E-07, &
9.50366E-07,9.78915E-07,1.00813E-06,1.03802E-06,1.06859E-06/
DATA (TOTPLNK(IDATA,12),IDATA=151,181)/ &
1.09986E-06,1.13184E-06,1.16453E-06,1.19796E-06,1.23212E-06, &
1.26703E-06,1.30270E-06,1.33915E-06,1.37637E-06,1.41440E-06, &
1.45322E-06,1.49286E-06,1.53333E-06,1.57464E-06,1.61679E-06, &
1.65981E-06,1.70370E-06,1.74847E-06,1.79414E-06,1.84071E-06, &
1.88821E-06,1.93663E-06,1.98599E-06,2.03631E-06,2.08759E-06, &
2.13985E-06,2.19310E-06,2.24734E-06,2.30260E-06,2.35888E-06, &
2.41619E-06/
DATA (TOTPLNK(IDATA,13),IDATA=1,50)/ &
4.53634E-11,5.11435E-11,5.75754E-11,6.47222E-11,7.26531E-11, &
8.14420E-11,9.11690E-11,1.01921E-10,1.13790E-10,1.26877E-10, &
1.41288E-10,1.57140E-10,1.74555E-10,1.93665E-10,2.14613E-10, &
2.37548E-10,2.62633E-10,2.90039E-10,3.19948E-10,3.52558E-10, &
3.88073E-10,4.26716E-10,4.68719E-10,5.14331E-10,5.63815E-10, &
6.17448E-10,6.75526E-10,7.38358E-10,8.06277E-10,8.79625E-10, &
9.58770E-10,1.04410E-09,1.13602E-09,1.23495E-09,1.34135E-09, &
1.45568E-09,1.57845E-09,1.71017E-09,1.85139E-09,2.00268E-09, &
2.16464E-09,2.33789E-09,2.52309E-09,2.72093E-09,2.93212E-09, &
3.15740E-09,3.39757E-09,3.65341E-09,3.92579E-09,4.21559E-09/
DATA (TOTPLNK(IDATA,13),IDATA=51,100)/ &
4.52372E-09,4.85115E-09,5.19886E-09,5.56788E-09,5.95928E-09, &
6.37419E-09,6.81375E-09,7.27917E-09,7.77168E-09,8.29256E-09, &
8.84317E-09,9.42487E-09,1.00391E-08,1.06873E-08,1.13710E-08, &
1.20919E-08,1.28515E-08,1.36514E-08,1.44935E-08,1.53796E-08, &
1.63114E-08,1.72909E-08,1.83201E-08,1.94008E-08,2.05354E-08, &
2.17258E-08,2.29742E-08,2.42830E-08,2.56545E-08,2.70910E-08, &
2.85950E-08,3.01689E-08,3.18155E-08,3.35373E-08,3.53372E-08, &
3.72177E-08,3.91818E-08,4.12325E-08,4.33727E-08,4.56056E-08, &
4.79342E-08,5.03617E-08,5.28915E-08,5.55270E-08,5.82715E-08, &
6.11286E-08,6.41019E-08,6.71951E-08,7.04119E-08,7.37560E-08/
DATA (TOTPLNK(IDATA,13),IDATA=101,150)/ &
7.72315E-08,8.08424E-08,8.45927E-08,8.84866E-08,9.25281E-08, &
9.67218E-08,1.01072E-07,1.05583E-07,1.10260E-07,1.15107E-07, &
1.20128E-07,1.25330E-07,1.30716E-07,1.36291E-07,1.42061E-07, &
1.48031E-07,1.54206E-07,1.60592E-07,1.67192E-07,1.74015E-07, &
1.81064E-07,1.88345E-07,1.95865E-07,2.03628E-07,2.11643E-07, &
2.19912E-07,2.28443E-07,2.37244E-07,2.46318E-07,2.55673E-07, &
2.65316E-07,2.75252E-07,2.85489E-07,2.96033E-07,3.06891E-07, &
3.18070E-07,3.29576E-07,3.41417E-07,3.53600E-07,3.66133E-07, &
3.79021E-07,3.92274E-07,4.05897E-07,4.19899E-07,4.34288E-07, &
4.49071E-07,4.64255E-07,4.79850E-07,4.95863E-07,5.12300E-07/
DATA (TOTPLNK(IDATA,13),IDATA=151,181)/ &
5.29172E-07,5.46486E-07,5.64250E-07,5.82473E-07,6.01164E-07, &
6.20329E-07,6.39979E-07,6.60122E-07,6.80767E-07,7.01922E-07, &
7.23596E-07,7.45800E-07,7.68539E-07,7.91826E-07,8.15669E-07, &
8.40076E-07,8.65058E-07,8.90623E-07,9.16783E-07,9.43544E-07, &
9.70917E-07,9.98912E-07,1.02754E-06,1.05681E-06,1.08673E-06, &
1.11731E-06,1.14856E-06,1.18050E-06,1.21312E-06,1.24645E-06, &
1.28049E-06/
DATA (TOTPLNK(IDATA,14),IDATA=1,50)/ &
1.40113E-11,1.59358E-11,1.80960E-11,2.05171E-11,2.32266E-11, &
2.62546E-11,2.96335E-11,3.33990E-11,3.75896E-11,4.22469E-11, &
4.74164E-11,5.31466E-11,5.94905E-11,6.65054E-11,7.42522E-11, &
8.27975E-11,9.22122E-11,1.02573E-10,1.13961E-10,1.26466E-10, &
1.40181E-10,1.55206E-10,1.71651E-10,1.89630E-10,2.09265E-10, &
2.30689E-10,2.54040E-10,2.79467E-10,3.07128E-10,3.37190E-10, &
3.69833E-10,4.05243E-10,4.43623E-10,4.85183E-10,5.30149E-10, &
5.78755E-10,6.31255E-10,6.87910E-10,7.49002E-10,8.14824E-10, &
8.85687E-10,9.61914E-10,1.04385E-09,1.13186E-09,1.22631E-09, &
1.32761E-09,1.43617E-09,1.55243E-09,1.67686E-09,1.80992E-09/
DATA (TOTPLNK(IDATA,14),IDATA=51,100)/ &
1.95212E-09,2.10399E-09,2.26607E-09,2.43895E-09,2.62321E-09, &
2.81949E-09,3.02844E-09,3.25073E-09,3.48707E-09,3.73820E-09, &
4.00490E-09,4.28794E-09,4.58819E-09,4.90647E-09,5.24371E-09, &
5.60081E-09,5.97875E-09,6.37854E-09,6.80120E-09,7.24782E-09, &
7.71950E-09,8.21740E-09,8.74271E-09,9.29666E-09,9.88054E-09, &
1.04956E-08,1.11434E-08,1.18251E-08,1.25422E-08,1.32964E-08, &
1.40890E-08,1.49217E-08,1.57961E-08,1.67140E-08,1.76771E-08, &
1.86870E-08,1.97458E-08,2.08553E-08,2.20175E-08,2.32342E-08, &
2.45077E-08,2.58401E-08,2.72334E-08,2.86900E-08,3.02122E-08, &
3.18021E-08,3.34624E-08,3.51954E-08,3.70037E-08,3.88899E-08/
DATA (TOTPLNK(IDATA,14),IDATA=101,150)/ &
4.08568E-08,4.29068E-08,4.50429E-08,4.72678E-08,4.95847E-08, &
5.19963E-08,5.45058E-08,5.71161E-08,5.98309E-08,6.26529E-08, &
6.55857E-08,6.86327E-08,7.17971E-08,7.50829E-08,7.84933E-08, &
8.20323E-08,8.57035E-08,8.95105E-08,9.34579E-08,9.75488E-08, &
1.01788E-07,1.06179E-07,1.10727E-07,1.15434E-07,1.20307E-07, &
1.25350E-07,1.30566E-07,1.35961E-07,1.41539E-07,1.47304E-07, &
1.53263E-07,1.59419E-07,1.65778E-07,1.72345E-07,1.79124E-07, &
1.86122E-07,1.93343E-07,2.00792E-07,2.08476E-07,2.16400E-07, &
2.24568E-07,2.32988E-07,2.41666E-07,2.50605E-07,2.59813E-07, &
2.69297E-07,2.79060E-07,2.89111E-07,2.99455E-07,3.10099E-07/
DATA (TOTPLNK(IDATA,14),IDATA=151,181)/ &
3.21049E-07,3.32311E-07,3.43893E-07,3.55801E-07,3.68041E-07, &
3.80621E-07,3.93547E-07,4.06826E-07,4.20465E-07,4.34473E-07, &
4.48856E-07,4.63620E-07,4.78774E-07,4.94325E-07,5.10280E-07, &
5.26648E-07,5.43436E-07,5.60652E-07,5.78302E-07,5.96397E-07, &
6.14943E-07,6.33949E-07,6.53421E-07,6.73370E-07,6.93803E-07, &
7.14731E-07,7.36157E-07,7.58095E-07,7.80549E-07,8.03533E-07, &
8.27050E-07/
DATA (TOTPLNK(IDATA,15),IDATA=1,50)/ &
3.90483E-12,4.47999E-12,5.13122E-12,5.86739E-12,6.69829E-12, &
7.63467E-12,8.68833E-12,9.87221E-12,1.12005E-11,1.26885E-11, &
1.43534E-11,1.62134E-11,1.82888E-11,2.06012E-11,2.31745E-11, &
2.60343E-11,2.92087E-11,3.27277E-11,3.66242E-11,4.09334E-11, &
4.56935E-11,5.09455E-11,5.67338E-11,6.31057E-11,7.01127E-11, &
7.78096E-11,8.62554E-11,9.55130E-11,1.05651E-10,1.16740E-10, &
1.28858E-10,1.42089E-10,1.56519E-10,1.72243E-10,1.89361E-10, &
2.07978E-10,2.28209E-10,2.50173E-10,2.73999E-10,2.99820E-10, &
3.27782E-10,3.58034E-10,3.90739E-10,4.26067E-10,4.64196E-10, &
5.05317E-10,5.49631E-10,5.97347E-10,6.48689E-10,7.03891E-10/
DATA (TOTPLNK(IDATA,15),IDATA=51,100)/ &
7.63201E-10,8.26876E-10,8.95192E-10,9.68430E-10,1.04690E-09, &
1.13091E-09,1.22079E-09,1.31689E-09,1.41957E-09,1.52922E-09, &
1.64623E-09,1.77101E-09,1.90401E-09,2.04567E-09,2.19647E-09, &
2.35690E-09,2.52749E-09,2.70875E-09,2.90127E-09,3.10560E-09, &
3.32238E-09,3.55222E-09,3.79578E-09,4.05375E-09,4.32682E-09, &
4.61574E-09,4.92128E-09,5.24420E-09,5.58536E-09,5.94558E-09, &
6.32575E-09,6.72678E-09,7.14964E-09,7.59526E-09,8.06470E-09, &
8.55897E-09,9.07916E-09,9.62638E-09,1.02018E-08,1.08066E-08, &
1.14420E-08,1.21092E-08,1.28097E-08,1.35446E-08,1.43155E-08, &
1.51237E-08,1.59708E-08,1.68581E-08,1.77873E-08,1.87599E-08/
DATA (TOTPLNK(IDATA,15),IDATA=101,150)/ &
1.97777E-08,2.08423E-08,2.19555E-08,2.31190E-08,2.43348E-08, &
2.56045E-08,2.69302E-08,2.83140E-08,2.97578E-08,3.12636E-08, &
3.28337E-08,3.44702E-08,3.61755E-08,3.79516E-08,3.98012E-08, &
4.17265E-08,4.37300E-08,4.58143E-08,4.79819E-08,5.02355E-08, &
5.25777E-08,5.50114E-08,5.75393E-08,6.01644E-08,6.28896E-08, &
6.57177E-08,6.86521E-08,7.16959E-08,7.48520E-08,7.81239E-08, &
8.15148E-08,8.50282E-08,8.86675E-08,9.24362E-08,9.63380E-08, &
1.00376E-07,1.04555E-07,1.08878E-07,1.13349E-07,1.17972E-07, &
1.22751E-07,1.27690E-07,1.32793E-07,1.38064E-07,1.43508E-07, &
1.49129E-07,1.54931E-07,1.60920E-07,1.67099E-07,1.73473E-07/
DATA (TOTPLNK(IDATA,15),IDATA=151,181)/ &
1.80046E-07,1.86825E-07,1.93812E-07,2.01014E-07,2.08436E-07, &
2.16082E-07,2.23957E-07,2.32067E-07,2.40418E-07,2.49013E-07, &
2.57860E-07,2.66963E-07,2.76328E-07,2.85961E-07,2.95868E-07, &
3.06053E-07,3.16524E-07,3.27286E-07,3.38345E-07,3.49707E-07, &
3.61379E-07,3.73367E-07,3.85676E-07,3.98315E-07,4.11287E-07, &
4.24602E-07,4.38265E-07,4.52283E-07,4.66662E-07,4.81410E-07, &
4.96535E-07/
DATA (TOTPLNK(IDATA,16),IDATA=1,50)/ &
4.65378E-13,5.41927E-13,6.29913E-13,7.30869E-13,8.46510E-13, &
9.78750E-13,1.12972E-12,1.30181E-12,1.49764E-12,1.72016E-12, &
1.97260E-12,2.25858E-12,2.58206E-12,2.94744E-12,3.35955E-12, &
3.82372E-12,4.34581E-12,4.93225E-12,5.59010E-12,6.32711E-12, &
7.15171E-12,8.07317E-12,9.10159E-12,1.02480E-11,1.15244E-11, &
1.29438E-11,1.45204E-11,1.62697E-11,1.82084E-11,2.03545E-11, &
2.27278E-11,2.53494E-11,2.82424E-11,3.14313E-11,3.49431E-11, &
3.88064E-11,4.30522E-11,4.77139E-11,5.28273E-11,5.84308E-11, &
6.45658E-11,7.12764E-11,7.86103E-11,8.66176E-11,9.53534E-11, &
1.04875E-10,1.15245E-10,1.26528E-10,1.38796E-10,1.52123E-10/
DATA (TOTPLNK(IDATA,16),IDATA=51,100)/ &
1.66590E-10,1.82281E-10,1.99287E-10,2.17704E-10,2.37632E-10, &
2.59182E-10,2.82468E-10,3.07610E-10,3.34738E-10,3.63988E-10, &
3.95504E-10,4.29438E-10,4.65951E-10,5.05212E-10,5.47402E-10, &
5.92707E-10,6.41329E-10,6.93477E-10,7.49371E-10,8.09242E-10, &
8.73338E-10,9.41911E-10,1.01524E-09,1.09359E-09,1.17728E-09, &
1.26660E-09,1.36190E-09,1.46350E-09,1.57177E-09,1.68709E-09, &
1.80984E-09,1.94044E-09,2.07932E-09,2.22693E-09,2.38373E-09, &
2.55021E-09,2.72689E-09,2.91429E-09,3.11298E-09,3.32353E-09, &
3.54655E-09,3.78265E-09,4.03251E-09,4.29679E-09,4.57620E-09, &
4.87148E-09,5.18341E-09,5.51276E-09,5.86037E-09,6.22708E-09/
DATA (TOTPLNK(IDATA,16),IDATA=101,150)/ &
6.61381E-09,7.02145E-09,7.45097E-09,7.90336E-09,8.37967E-09, &
8.88092E-09,9.40827E-09,9.96280E-09,1.05457E-08,1.11583E-08, &
1.18017E-08,1.24773E-08,1.31865E-08,1.39306E-08,1.47111E-08, &
1.55295E-08,1.63872E-08,1.72860E-08,1.82274E-08,1.92132E-08, &
2.02450E-08,2.13247E-08,2.24541E-08,2.36352E-08,2.48699E-08, &
2.61602E-08,2.75082E-08,2.89161E-08,3.03860E-08,3.19203E-08, &
3.35213E-08,3.51913E-08,3.69330E-08,3.87486E-08,4.06411E-08, &
4.26129E-08,4.46668E-08,4.68058E-08,4.90325E-08,5.13502E-08, &
5.37617E-08,5.62703E-08,5.88791E-08,6.15915E-08,6.44107E-08, &
6.73404E-08,7.03841E-08,7.35453E-08,7.68278E-08,8.02355E-08/
DATA (TOTPLNK(IDATA,16),IDATA=151,181)/ &
8.37721E-08,8.74419E-08,9.12486E-08,9.51968E-08,9.92905E-08, &
1.03534E-07,1.07932E-07,1.12490E-07,1.17211E-07,1.22100E-07, &
1.27163E-07,1.32404E-07,1.37829E-07,1.43443E-07,1.49250E-07, &
1.55257E-07,1.61470E-07,1.67893E-07,1.74532E-07,1.81394E-07, &
1.88485E-07,1.95810E-07,2.03375E-07,2.11189E-07,2.19256E-07, &
2.27583E-07,2.36177E-07,2.45046E-07,2.54196E-07,2.63634E-07, &
2.73367E-07/
DATA (TOTPLK16(IDATA),IDATA=1,50)/ &
4.46128E-13,5.19008E-13,6.02681E-13,6.98580E-13,8.08302E-13, &
9.33629E-13,1.07654E-12,1.23925E-12,1.42419E-12,1.63407E-12, &
1.87190E-12,2.14099E-12,2.44498E-12,2.78793E-12,3.17424E-12, &
3.60881E-12,4.09698E-12,4.64461E-12,5.25813E-12,5.94456E-12, &
6.71156E-12,7.56752E-12,8.52154E-12,9.58357E-12,1.07644E-11, &
1.20758E-11,1.35304E-11,1.51420E-11,1.69256E-11,1.88973E-11, &
2.10746E-11,2.34762E-11,2.61227E-11,2.90356E-11,3.22388E-11, &
3.57574E-11,3.96187E-11,4.38519E-11,4.84883E-11,5.35616E-11, &
5.91075E-11,6.51647E-11,7.17743E-11,7.89797E-11,8.68284E-11, &
9.53697E-11,1.04658E-10,1.14748E-10,1.25701E-10,1.37582E-10/
DATA (TOTPLK16(IDATA),IDATA=51,100)/ &
1.50457E-10,1.64400E-10,1.79487E-10,1.95799E-10,2.13422E-10, &
2.32446E-10,2.52970E-10,2.75094E-10,2.98925E-10,3.24578E-10, &
3.52172E-10,3.81833E-10,4.13695E-10,4.47897E-10,4.84588E-10, &
5.23922E-10,5.66063E-10,6.11182E-10,6.59459E-10,7.11081E-10, &
7.66251E-10,8.25172E-10,8.88065E-10,9.55155E-10,1.02668E-09, &
1.10290E-09,1.18406E-09,1.27044E-09,1.36233E-09,1.46002E-09, &
1.56382E-09,1.67406E-09,1.79108E-09,1.91522E-09,2.04686E-09, &
2.18637E-09,2.33416E-09,2.49063E-09,2.65622E-09,2.83136E-09, &
3.01653E-09,3.21221E-09,3.41890E-09,3.63712E-09,3.86740E-09, &
4.11030E-09,4.36641E-09,4.63631E-09,4.92064E-09,5.22003E-09/
DATA (TOTPLK16(IDATA),IDATA=101,150)/ &
5.53516E-09,5.86670E-09,6.21538E-09,6.58191E-09,6.96708E-09, &
7.37165E-09,7.79645E-09,8.24229E-09,8.71007E-09,9.20066E-09, &
9.71498E-09,1.02540E-08,1.08186E-08,1.14100E-08,1.20290E-08, &
1.26767E-08,1.33544E-08,1.40630E-08,1.48038E-08,1.55780E-08, &
1.63867E-08,1.72313E-08,1.81130E-08,1.90332E-08,1.99932E-08, &
2.09945E-08,2.20385E-08,2.31267E-08,2.42605E-08,2.54416E-08, &
2.66716E-08,2.79520E-08,2.92846E-08,3.06711E-08,3.21133E-08, &
3.36128E-08,3.51717E-08,3.67918E-08,3.84749E-08,4.02232E-08, &
4.20386E-08,4.39231E-08,4.58790E-08,4.79083E-08,5.00132E-08, &
5.21961E-08,5.44592E-08,5.68049E-08,5.92356E-08,6.17537E-08/
DATA (TOTPLK16(IDATA),IDATA=151,181)/ &
6.43617E-08,6.70622E-08,6.98578E-08,7.27511E-08,7.57449E-08, &
7.88419E-08,8.20449E-08,8.53568E-08,8.87805E-08,9.23190E-08, &
9.59753E-08,9.97526E-08,1.03654E-07,1.07682E-07,1.11841E-07, &
1.16134E-07,1.20564E-07,1.25135E-07,1.29850E-07,1.34712E-07, &
1.39726E-07,1.44894E-07,1.50221E-07,1.55711E-07,1.61367E-07, &
1.67193E-07,1.73193E-07,1.79371E-07,1.85732E-07,1.92279E-07, &
1.99016E-07/
CONTAINS
!------------------------------------------------------------------
SUBROUTINE RRTMLWRAD(rthraten,glw,olr,emiss & 1,5
,p8w,p3d,pi3d &
,dz8w,tsk,t3d,t8w,rho3d,r,g &
,icloud, warm_rain &
,ids,ide, jds,jde, kds,kde &
,ims,ime, jms,jme, kms,kme &
,its,ite, jts,jte, kts,kte &
,qv3d,qc3d,qr3d &
,qi3d,qs3d,qg3d,cldfra3d &
,f_qv,f_qc,f_qr,f_qi,f_qs,f_qg &
!ccc Added for time-varying trace gases.
,yr, julian )
!ccc
!------------------------------------------------------------------
!ccc
USE MODULE_RA_CLWRF_SUPPORT
, ONLY : read_CAMgases
!ccc
IMPLICIT NONE
!------------------------------------------------------------------
LOGICAL, INTENT(IN ) :: warm_rain
!
INTEGER, INTENT(IN ) :: ids,ide, jds,jde, kds,kde, &
ims,ime, jms,jme, kms,kme, &
its,ite, jts,jte, kts,kte
INTEGER, INTENT(IN ) :: ICLOUD
!
REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , &
INTENT(IN ) :: dz8w, &
T3D, &
t8w, &
p8w, &
P3D, &
pi3D, &
rho3D
!
REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , &
INTENT(INOUT) :: RTHRATEN
!
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(IN ) :: EMISS, &
TSK
!
REAL, DIMENSION( ims:ime, jms:jme ) , &
INTENT(INOUT) :: GLW, &
OLR
!
REAL, INTENT(IN ) :: R,G
!ccc Added for time-varying trace gases.
INTEGER, INTENT(IN ) :: yr
REAL, INTENT(IN ) :: julian
!ccc
!
! Optional
!
REAL, DIMENSION( ims:ime, kms:kme, jms:jme ) , &
OPTIONAL , &
INTENT(IN ) :: &
CLDFRA3D, &
QV3D, &
QC3D, &
QR3D, &
QI3D, &
QS3D, &
QG3D
LOGICAL, OPTIONAL, INTENT(IN ) :: F_QV,F_QC,F_QR,F_QI,F_QS,F_QG
! LOCAL VARS
REAL, DIMENSION( kts:kte+1 ) :: Pw1D, &
Tw1D
REAL, DIMENSION( kts:kte ) :: TTEN1D, &
CLDFRA1D, &
DZ1D, &
P1D, &
T1D, &
QV1D, &
QC1D, &
QR1D, &
QI1D, &
QS1D, &
QG1D
!
REAL :: TSFC,GLW0,OLR0,EMISS0
!
INTEGER:: i,j,K,NK
LOGICAL :: predicate
! Add variables for variable trace gas concentrations (ccc)
REAL(8) :: co2vmr, n2ovmr, ch4vmr
LOGICAL, EXTERNAL :: wrf_dm_on_monitor
CHARACTER(LEN=256) :: message
!------------------------------------------------------------------
!----- Calculate the trace gas concentrations from file.
!ccc
#ifdef CLWRFGHG
CALL read_CAMgases(yr,julian,"RRTM",co2vmr,n2ovmr,ch4vmr)
#else
! values used in pre-V3.5
! co2vmr = 330.e-6
! n2ovmr = 0.
! ch4vmr = 0.
! values updated to RRTMG in V3.5
co2vmr = 379.e-6
n2ovmr = 319.e-9
ch4vmr = 1774.e-9
#endif
IF ( wrf_dm_on_monitor() ) THEN
WRITE(message,*)'CAM-CLWRF interpolated values______ year:',yr,' julian day:',julian
call wrf_debug( 1, message)
WRITE(message,*)' CAM-CLWRF co2vmr: ',co2vmr,' n2ovmr:',n2ovmr,' ch4vmr:',ch4vmr
call wrf_debug( 1, message)
ENDIF
!-----CALCULATE LONG WAVE RADIATION
!
j_loop: DO J=jts,jte
i_loop: DO I=its,ite
! reverse vars
! p1D pw1D are in mb
do k=kts,kte+1
NK=kme-k+kms
Pw1D(K) = p8w(I,NK,J)/100.
Tw1D(K) = t8w(I,NK,J)
enddo
DO K=kts,kte
QV1D(K)=0.
QC1D(K)=0.
QR1D(K)=0.
QI1D(K)=0.
QS1D(K)=0.
CLDFRA1D(k)=0.
ENDDO
DO K=kts,kte
NK=kme-1-K+kms
QV1D(K)=QV3D(I,NK,J)
QV1D(K)=max(0.,QV1D(K))
ENDDO
DO K=kts,kte
NK=kme-1-K+kms
TTEN1D(K)=0.
T1D(K)=T3D(I,NK,J)
P1D(K)=P3D(I,NK,J)/100.
DZ1D(K)=dz8w(I,NK,J)
ENDDO
IF (ICLOUD .ne. 0) THEN
IF ( PRESENT( CLDFRA3D ) ) THEN
DO K=kts,kte
NK=kme-1-K+kms
CLDFRA1D(k)=CLDFRA3D(I,NK,J)
ENDDO
ENDIF
IF (PRESENT(F_QC) .AND. PRESENT(QC3D)) THEN
IF ( F_QC) THEN
DO K=kts,kte
NK=kme-1-K+kms
QC1D(K)=QC3D(I,NK,J)
QC1D(K)=max(0.,QC1D(K))
ENDDO
ENDIF
ENDIF
IF (PRESENT(F_QR) .AND. PRESENT(QR3D)) THEN
IF ( F_QR) THEN
DO K=kts,kte
NK=kme-1-K+kms
QR1D(K)=QR3D(I,NK,J)
QR1D(K)=max(0.,QR1D(K))
ENDDO
ENDIF
ENDIF
! This logic is tortured because cannot test F_QI unless
! it is present, and order of evaluation of expressions
! is not specified in Fortran
IF ( PRESENT ( F_QI ) ) THEN
predicate = F_QI
ELSE
predicate = .FALSE.
ENDIF
IF (.NOT. predicate .and. .not. warm_rain) THEN
DO K=kts,kte
IF (T1D(K) .lt. 273.15) THEN
QI1D(K)=QC1D(K)
QS1D(K)=QR1D(K)
QC1D(K)=0.
QR1D(K)=0.
ENDIF
ENDDO
ENDIF
IF (PRESENT(F_QI) .AND. PRESENT(QI3D)) THEN
DO K=kts,kte
NK=kme-1-K+kms
QI1D(K)=QI3D(I,NK,J)
QI1D(K)=max(0.,QI1D(K))
ENDDO
ENDIF
IF (PRESENT(F_QS) .AND. PRESENT(QS3D)) THEN
IF (F_QS) THEN
DO K=kts,kte
NK=kme-1-K+kms
QS1D(K)=QS3D(I,NK,J)
QS1D(K)=max(0.,QS1D(K))
ENDDO
ENDIF
ENDIF
IF (PRESENT(F_QG) .AND. PRESENT(QG3D)) THEN
IF (F_QG) THEN
DO K=kts,kte
NK=kme-1-K+kms
QG1D(K)=QG3D(I,NK,J)
QG1D(K)=max(0.,QG1D(K))
ENDDO
ENDIF
ENDIF
ENDIF
EMISS0=EMISS(I,J)
GLW0=0.
OLR0=0.
TSFC=TSK(I,J)
CALL RRTM(tten1d,glw0,olr0,tsfc,cldfra1d,t1d,tw1d,qv1d,qc1d, &
qr1d,qi1d,qs1d,qg1d,p1d,pW1d,dz1d, &
emiss0,r,g, &
!ccc Added for time-varying trace gases.
co2vmr, n2ovmr, ch4vmr, &
!ccc
kts,kte )
GLW(I,J)=GLW0
OLR(I,J)=OLR0
DO K=kts,kte
nk=kme-1-k+kms
rthraten(i,k,j)=rthraten(i,k,j)+tten1d(nk)/pi3d(i,k,j)
ENDDO
END DO i_loop
END DO j_loop
!-------------------------------------------------------------------
END SUBROUTINE RRTMLWRAD
!****************************************************************************
!* *
!* RRTM *
!* *
!* *
!* *
!* RAPID RADIATIVE TRANSFER MODEL *
!* *
!* *
!* ATMOSPHERIC AND ENVIRONMENTAL RESEARCH, INC. *
!* 840 MEMORIAL DRIVE *
!* CAMBRIDGE, MA 02139 *
!* *
!* *
!* ELI J. MLAWER *
!* STEVEN J. TAUBMAN~ *
!* SHEPARD A. CLOUGH *
!* *
!* *
!* ~currently at GFDL *
!* *
!* *
!* *
!* email: mlawer@aer.com *
!* *
!* The authors wish to acknowledge the contributions of the *
!* following people: Patrick D. Brown, Michael J. Iacono, *
!* Ronald E. Farren, Luke Chen, Robert Bergstrom. *
!* *
!****************************************************************************
! *** This version of RRTM has been altered to interface with the
! *** NCAR MM5 mesoscale model for the calculation of longwave radiative
! *** transfer (based on a code for interface with CCM model by M. J. Iacono)
! *** J. Dudhia ; March, 1999
!---------------------------------------------------------------------
SUBROUTINE RRTM(TTEN,GLW,OLR,TSFC,CLDFRA,T,Tw,QV,QC, & 1,5
QR,QI,QS,QG,P,Pw,DZ, &
EMISS,R,G, &
!ccc Added for time-varying trace gases.
CO2VMR, N2OVMR, CH4VMR, &
!ccc
kts,kte )
!---------------------------------------------------------------------
! *** This program is the driver for RRTM, the AER LW radiation model.
! This routine:
! Calls MM5ATM to provide atmosphere in column and boundary values
! a) calls GASABS to calculate gaseous optical depths
! b) calls SETCOEF to calculate various quantities needed for
! the radiative transfer algorithm
! c) calls RTRN (for both clear and cloudy columns) to do the
! radiative transfer calculation
! d) passes the necessary flux and cooling rate back to MM5
!---------------------------------------------------------------------
IMPLICIT NONE
!---------------------------------------------------------------------
INTEGER, INTENT(IN ) :: kts, kte
!
REAL, DIMENSION( kts:kte+1 ), INTENT(IN ) :: Pw, &
Tw
REAL, DIMENSION( kts:kte ), INTENT(IN ) :: CLDFRA, &
T, &
P, &
DZ
!
REAL, DIMENSION( kts:kte ), INTENT(INOUT) :: &
QV
REAL, DIMENSION( kts:kte ), INTENT(IN ) :: &
QC, &
QR, &
QI, &
QS, &
QG
!
REAL, DIMENSION( kts:kte ), INTENT(INOUT):: TTEN
!
REAL, INTENT(IN ) :: R, G, EMISS
!ccc Added for time-varying trace gases.
! Trace gases variables
REAL(8), INTENT(IN ) :: co2vmr, n2ovmr, ch4vmr
!ccc
!
REAL, INTENT(INOUT) :: TSFC,GLW,OLR
! LOCAL VAR
INTEGER, DIMENSION( NGPT,kts:NLAYERS ) :: ITR
REAL, DIMENSION( NGPT,kts:NLAYERS ) :: PFRAC, &
TAUG
REAL, DIMENSION( 35,kts:NLAYERS ) :: WKL
REAL, DIMENSION( MAXXSEC,kts:NLAYERS ) :: WX
REAL, DIMENSION( kts:kte ) :: O3PROF
REAL, DIMENSION( kts:NLAYERS ) :: PAVEL, &
TAVEL, &
CLDFRAC, &
TAUCLOUD, &
COLDRY, &
COLH2O, &
COLCO2, &
COLO3, &
COLN2O, &
COLCH4, &
COLO2, &
CO2MULT, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
FORFAC, &
SELFFAC, &
SELFFRAC
!
INTEGER, DIMENSION( kts:NLAYERS ) :: ICLDLYR, &
JP, &
JT, &
JT1, &
INDSELF
REAL, DIMENSION( 0:NLAYERS ) :: PZ, &
TZ, &
TOTDFLUX, &
TOTUFLUX, &
HTR
!
INTEGER :: I,K,ktep1
INTEGER :: LAYTROP,LAYSWTCH,LAYLOW
REAL :: TBOUND
REAL, DIMENSION(NBANDS) :: SEMISS
!---------------------------------------------------------------------------
! RRTM Definitions
! NGPT ! Total number of g-point subintervals
! MXLAY ! Maximum number of model layers
! NBANDS ! Number of longwave spectral bands
! PI ! Geometric constant
! FLUXFAC ! Radiance to flux conversion factor
! HEATFAC ! Heating rate conversion factor
! NG(NBANDS) ! Number of g-points per band for input
! absorption coefficient data
! NSPA(NBANDS),NSPB(NBANDS) ! Number of reference atmospheres per band
! WAVENUM1(NBANDS) ! Longwave band lower limit (wavenumbers)
! WAVENUM2(NBANDS) ! Longwave band upper limit (wavenumbers)
! DELWAVE ! Longwave band width (wavenumbers)
! NLAYERS ! Number of model layers (mkx+1)
! PAVEL(MXLAY) ! Layer pressures (mb)
! PZ(0:MXLAY) ! Level (interface) pressures (mb)
! TAVEL(MXLAY) ! Layer temperatures (K)
! TZ(0:MXLAY) ! Level (interface) temperatures(mb)
! TBOUND ! Surface temperature (K)
! CLDFRAC(MXLAY) ! Layer cloud fraction
! TAUCLOUD(MXLAY) ! Layer cloud optical depth
! ITR(NGPT,MXLAY) ! Integer look-up table index
! PFRAC(NGPT,MXLAY) ! Planck fractions
! ICLDLYR(MXLAY) ! Flag for cloudy layers
! TOTUFLUX(0:MXLAY) ! Upward longwave flux (W/m2)
! TOTDFLUX(0:MXLAY) ! Downward longwave flux (W/m2)
! FNET(0:MXLAY) ! Net longwave flux (W/m2)
! HTR(0:MXLAY) ! Longwave heating rate (K/day)
! CLRNTTOA ! Clear-sky TOA outgoing flux (W/m2)
! CLRNTSRF ! Clear-sky net surface flux (W/m2)
! TOTUCLFL(0:MXLAY) ! Clear-sky upward longwave flux (W/m2)
! TOTDCLFL(0:MXLAY) ! Clear-sky downward longwave flux (W/m2)
! FNETC(0:MXLAY) ! Clear-sky net longwave flux (W/m2)
! HTRC(0:MXLAY) ! Clear-sky longwave heating rate (K/day)
!
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
!---------------------------------------------------------------------------
! ktep1=kte+1
ktep1=NLAYERS
!
! CLOUD EMISSIVITIES (M^2/G)
! THESE ARE CONSISTENT WITH LWRAD (ABCW=0.5*(ABUP+ABDOWN))
!
! ONEMINUS = 1. - 1.E-6
! PI = 2.*ASIN(1.)
! FLUXFAC = PI * 2.D4
!
CALL INIRAD (O3PROF,Pw,kts,kte)
! Prepare atmospheric profile from CCM for use in RRTM, and define
! other RRTM input parameters. Arrays are passed back through the
! existing RRTM commons and arrays.
CALL MM5ATM(CLDFRA,O3PROF,T,Tw,TSFC,QV,QC,QR,QI,QS,QG, &
P,Pw,DZ,EMISS,R,G, &
PAVEL,TAVEL,PZ,TZ,CLDFRAC,TAUCLOUD,COLDRY, &
WKL,WX,TBOUND,SEMISS, &
!ccc Added for time-varying trace gases.
CO2VMR, N2OVMR, CH4VMR, &
!ccc
kts,kte )
! Calculate information needed by the radiative transfer routine
! that is specific to this atmosphere, especially some of the
! coefficients and indices needed to compute the optical depths
! by interpolating data from stored reference atmospheres.
CALL SETCOEF(kts,ktep1, &
PAVEL,TAVEL,COLDRY,COLH2O,COLCO2,COLO3, &
COLN2O,COLCH4,COLO2,CO2MULT, &
FAC00,FAC01,FAC10,FAC11, &
FORFAC,SELFFAC,SELFFRAC, &
JP,JT,JT1,INDSELF,WKL,LAYTROP,LAYSWTCH,LAYLOW)
CALL GASABS(kts,ktep1, &
COLDRY,COLH2O,COLCO2,COLO3,COLN2O,COLCH4, &
COLO2,CO2MULT, &
FAC00,FAC01,FAC10,FAC11, &
FORFAC,SELFFAC,SELFFRAC, &
JP,JT,JT1,INDSELF,ITR,WX,PFRAC,TAUG, &
LAYTROP,LAYSWTCH,LAYLOW )
! Check for cloud in column. Use original CCM LW threshold: if total
! clear sky fraction < 0.999, then column is cloudy, otherwise consider
! it clear. Also, set up flag array, icldlyr, for use in radiative
! transfer. Set icldlyr to one for each layer with cloud. If tclrsf
! is not available, icldlyr can be set from cldfrac alone.
do 1500 k = 1, nlayers
if (cldfrac(k).gt.0.) then
icldlyr(k) = 1
else
icldlyr(k) = 0
endif
1500 continue
! Call the radiative transfer routine.
CALL RTRN(kts,ktep1, &
TAVEL, PZ, TZ, CLDFRAC, TAUCLOUD, TOTDFLUX, &
TOTUFLUX, HTR, ICLDLYR, ITR, PFRAC, TBOUND,SEMISS )
! Pass total sky up and down flux profiles to CCM output arrays and
! convert from mks to cgs units for CCM. Pass clear sky TOA and surface
! net fluxes to CCM fields for diagnostics. Pass total sky heating rate
! profile to CCM output arrays and convert units to K/sec. The vertical
! array index (bottom to top in RRTM) is reversed for CCM fields.
! flntc(iiplon) = CLRNTTOA*1.e3
! flnsc(iiplon) = CLRNTSRF*1.e3
! do 2400 k = 0, NLAYERS-1
! fulc(k+1) = TOTUCLFL(NLAYERS-1-k)*1.e3
! fdlc(k+1) = TOTDCLFL(NLAYERS-1-k)*1.e3
! ful(k+1) = TOTUFLUX(NLAYERS-1-k)*1.e3
! fdl(k+1) = TOTDFLUX(NLAYERS-1-k)*1.e3
! 2400 continue
! do 2450 k = 1, NLAYERS-1
do 2450 k = 1, kte
! qrlc(k) = HTRC(NLAYERS-1-k)/86400.
! qrl(k) = HTR(NLAYERS-1-k)/86400.
! TTEN(K)=HTR(NLAYERS-1-k)/86400.
TTEN(K)=HTR(kte-k)/86400.
2450 continue
GLW = TOTDFLUX(0)
! OLR = TOTUFLUX(NLAYERS)
OLR = TOTUFLUX(kte)
END SUBROUTINE RRTM
!***************************************************************************
SUBROUTINE CMBGB1(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, FORREF, &
SELFREFC, FORREFC, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! Original version: Michael J. Iacono; July, 1998
! Revision for NCAR CCM: Michael J. Iacono; September, 1998
!
! The subroutines CMBGB1->CMBGB16 input the absorption coefficient
! data for each band, which are defined for 16 g-points and 16 spectral
! bands. The data are combined with appropriate weighting following the
! g-point mapping arrays specified in RRTMINIT. Plank fraction data
! in arrays FRACREFA and FRACREFB are combined without weighting. All
! g-point reduced data are put into new arrays for use in RRTM.
!
! BAND 1: 10-250 cm-1 (low - H2O; high - H2O)
!***************************************************************************
! Input
REAL abscoefL(5,13,MG),abscoefH(5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG), FRACREFB(MG), FORREF(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG1), FORREFC(NG1)
REAL FRACREFAC(NG1), FRACREFBC(NG1)
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(1)
SUMK = 0.
DO 2600 IPR = 1, NGN(IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JTJT,JPJP,IPRSM)*RWGT(IPRSM)
2600 CONTINUE
ABSA1(JTJT+(JPJP-1)*5,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(1)
SUMK = 0.
DO 3600 IPR = 1, NGN(IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM)
3600 CONTINUE
ABSB1(JTJT+(JPJP-13)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
2000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(1)
SUMK = 0.
DO 4600 IPR = 1, NGN(IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
IPRSM = 0
DO 5400 IGC = 1,NGC(1)
SUMK = 0.
SUMF1 = 0.
SUMF2 = 0.
DO 5600 IPR = 1, NGN(IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + FORREF(IPRSM)*RWGT(IPRSM)
SUMF1= SUMF1+ FRACREFA(IPRSM)
SUMF2= SUMF2+ FRACREFB(IPRSM)
5600 CONTINUE
FORREFC(IGC) = SUMK
FRACREFAC(IGC) = SUMF1
FRACREFBC(IGC) = SUMF2
5400 CONTINUE
END SUBROUTINE CMBGB1
!***************************************************************************
SUBROUTINE CMBGB2(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, FORREF, &
SELFREFC, FORREFC, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 2: 250-500 cm-1 (low - H2O; high - H2O)
!***************************************************************************
! Input
REAL abscoefL(5,13,MG),abscoefH(5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,13), FRACREFB(MG), FORREF(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG2), FORREFC(NG2)
REAL FRACREFAC(NG2,13), FRACREFBC(NG2)
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(2)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(1)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JTJT,JPJP,IPRSM)*RWGT(IPRSM+16)
2600 CONTINUE
ABSA2(JTJT+(JPJP-1)*5,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(2)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(1)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM+16)
3600 CONTINUE
ABSB2(JTJT+(JPJP-13)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
2000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(2)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(1)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+16)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 5000 JPJP = 1,13
IPRSM = 0
DO 5400 IGC = 1,NGC(2)
SUMF = 0.
DO 5600 IPR = 1, NGN(NGS(1)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
5600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
5400 CONTINUE
5000 CONTINUE
IPRSM = 0
DO 6400 IGC = 1,NGC(2)
SUMK = 0.
SUMF = 0.
DO 6600 IPR = 1, NGN(NGS(1)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + FORREF(IPRSM)*RWGT(IPRSM+16)
SUMF = SUMF + FRACREFB(IPRSM)
6600 CONTINUE
FORREFC(IGC) = SUMK
FRACREFBC(IGC) = SUMF
6400 CONTINUE
END SUBROUTINE CMBGB2
!***************************************************************************
SUBROUTINE CMBGB3(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, FORREF, ABSN2OA, ABSN2OB, &
SELFREFC, FORREFC, &
ABSN2OAC, ABSN2OBC, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 3: 500-630 cm-1 (low - H2O,CO2; high - H2O,CO2)
!***************************************************************************
! Input
REAL abscoefL(10,5,13,MG),abscoefH(5,5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,10), FRACREFB(MG,5)
REAL FORREF(MG), ABSN2OA(MG), ABSN2OB(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG3), FORREFC(NG3), &
ABSN2OAC(NG3), ABSN2OBC(NG3)
REAL FRACREFAC(NG3,10), FRACREFBC(NG3,5)
DO 2000 JN = 1,10
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(3)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(2)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)* RWGT(IPRSM+32)
2600 CONTINUE
ABSA3(JN+(JTJT-1)*10+(JPJP-1)*50,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JN = 1,5
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(3)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(2)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JN,JTJT,JPJP,IPRSM)* RWGT(IPRSM+32)
3600 CONTINUE
ABSB3(JN+(JTJT-1)*5+(JPJP-13)*25,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(3)
SUMK = 0.
SUMF = 0.
DO 4600 IPR = 1, NGN(NGS(2)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)* RWGT(IPRSM+32)
SUMF = SUMF + FRACREFA(IPRSM,JTJT)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
FRACREFAC(IGC,JTJT) = SUMF
4400 CONTINUE
4000 CONTINUE
DO 5000 JPJP = 1,5
IPRSM = 0
DO 5400 IGC = 1,NGC(3)
SUMF = 0.
DO 5600 IPR = 1, NGN(NGS(2)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFB(IPRSM,JPJP)
5600 CONTINUE
FRACREFBC(IGC,JPJP) = SUMF
5400 CONTINUE
5000 CONTINUE
IPRSM = 0
DO 6400 IGC = 1,NGC(3)
SUMK1= 0.
SUMK2= 0.
SUMK3= 0.
DO 6600 IPR = 1, NGN(NGS(2)+IGC)
IPRSM = IPRSM + 1
SUMK1= SUMK1+ FORREF(IPRSM)*RWGT(IPRSM+32)
SUMK2= SUMK2+ ABSN2OA(IPRSM)*RWGT(IPRSM+32)
SUMK3= SUMK3+ ABSN2OB(IPRSM)*RWGT(IPRSM+32)
6600 CONTINUE
FORREFC(IGC) = SUMK1
ABSN2OAC(IGC) = SUMK2
ABSN2OBC(IGC) = SUMK3
6400 CONTINUE
END SUBROUTINE CMBGB3
!***************************************************************************
SUBROUTINE CMBGB4(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, &
SELFREFC, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 4: 630-700 cm-1 (low - H2O,CO2; high - O3,CO2)
!***************************************************************************
! Input
REAL abscoefL(9,5,13,MG),abscoefH(6,5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9), FRACREFB(MG,6)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG4)
REAL FRACREFAC(NG4,9), FRACREFBC(NG4,6)
DO 2000 JN = 1,9
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(4)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(3)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+48)
2600 CONTINUE
ABSA4(JN+(JTJT-1)*9+(JPJP-1)*45,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JN = 1,6
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(4)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(3)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+48)
3600 CONTINUE
ABSB4(JN+(JTJT-1)*6+(JPJP-13)*30,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(4)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(3)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+48)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 5000 JPJP = 1,9
IPRSM = 0
DO 5400 IGC = 1,NGC(4)
SUMF = 0.
DO 5600 IPR = 1, NGN(NGS(3)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
5600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
5400 CONTINUE
5000 CONTINUE
DO 6000 JPJP = 1,6
IPRSM = 0
DO 6400 IGC = 1,NGC(4)
SUMF = 0.
DO 6600 IPR = 1, NGN(NGS(3)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFB(IPRSM,JPJP)
6600 CONTINUE
FRACREFBC(IGC,JPJP) = SUMF
6400 CONTINUE
6000 CONTINUE
END SUBROUTINE CMBGB4
!***************************************************************************
SUBROUTINE CMBGB5(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, CCL4, &
SELFREFC, CCL4C, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 5: 700-820 cm-1 (low - H2O,CO2; high - O3,CO2)
!***************************************************************************
! Input
REAL abscoefL(9,5,13,MG),abscoefH(5,5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9), FRACREFB(MG,5), CCL4(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG5), CCL4C(NG5)
REAL FRACREFAC(NG5,9), FRACREFBC(NG5,5)
DO 2000 JN = 1,9
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(5)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(4)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+64)
2600 CONTINUE
ABSA5(JN+(JTJT-1)*9+(JPJP-1)*45,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JN = 1,5
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(5)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(4)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+64)
3600 CONTINUE
ABSB5(JN+(JTJT-1)*5+(JPJP-13)*25,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(5)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(4)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+64)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 5000 JPJP = 1,9
IPRSM = 0
DO 5400 IGC = 1,NGC(5)
SUMF = 0.
DO 5600 IPR = 1, NGN(NGS(4)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
5600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
5400 CONTINUE
5000 CONTINUE
DO 6000 JPJP = 1,5
IPRSM = 0
DO 6400 IGC = 1,NGC(5)
SUMF = 0.
DO 6600 IPR = 1, NGN(NGS(4)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFB(IPRSM,JPJP)
6600 CONTINUE
FRACREFBC(IGC,JPJP) = SUMF
6400 CONTINUE
6000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(5)
SUMK = 0.
DO 7600 IPR = 1, NGN(NGS(4)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + CCL4(IPRSM)*RWGT(IPRSM+64)
7600 CONTINUE
CCL4C(IGC) = SUMK
7400 CONTINUE
END SUBROUTINE CMBGB5
!***************************************************************************
SUBROUTINE CMBGB6(abscoefL, SELFREF, & 2,2
FRACREFA, ABSCO2, CFC11ADJ, CFC12, &
SELFREFC, ABSCO2C, CFC11ADJC, CFC12C, &
FRACREFAC )
!***************************************************************************
!
! BAND 6: 820-980 cm-1 (low - H2O; high - nothing)
!***************************************************************************
! Input
REAL abscoefL(5,13,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG), ABSCO2(MG), CFC11ADJ(MG), CFC12(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG6), &
ABSCO2C(NG6), CFC11ADJC(NG6), CFC12C(NG6)
REAL FRACREFAC(NG6)
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(6)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(5)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JTJT,JPJP,IPRSM)*RWGT(IPRSM+80)
2600 CONTINUE
ABSA6(JTJT+(JPJP-1)*5,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(6)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(5)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+80)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(6)
SUMF = 0.
SUMK1= 0.
SUMK2= 0.
SUMK3= 0.
DO 7600 IPR = 1, NGN(NGS(5)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM)
SUMK1= SUMK1+ ABSCO2(IPRSM)*RWGT(IPRSM+80)
SUMK2= SUMK2+ CFC11ADJ(IPRSM)*RWGT(IPRSM+80)
SUMK3= SUMK3+ CFC12(IPRSM)*RWGT(IPRSM+80)
7600 CONTINUE
FRACREFAC(IGC) = SUMF
ABSCO2C(IGC) = SUMK1
CFC11ADJC(IGC) = SUMK2
CFC12C(IGC) = SUMK3
7400 CONTINUE
END SUBROUTINE CMBGB6
!***************************************************************************
SUBROUTINE CMBGB7(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, ABSCO2, &
SELFREFC, ABSCO2C, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 7: 980-1080 cm-1 (low - H2O,O3; high - O3)
!***************************************************************************
! Input
REAL abscoefL(9,5,13,MG),abscoefH(5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9), FRACREFB(MG), ABSCO2(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG7), ABSCO2C(NG7)
REAL FRACREFAC(NG7,9), FRACREFBC(NG7)
DO 2000 JN = 1,9
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(7)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(6)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+96)
2600 CONTINUE
ABSA7(JN+(JTJT-1)*9+(JPJP-1)*45,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(7)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(6)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM+96)
3600 CONTINUE
ABSB7(JTJT+(JPJP-13)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(7)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(6)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+96)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 5000 JPJP = 1,9
IPRSM = 0
DO 5400 IGC = 1,NGC(7)
SUMF = 0.
DO 5600 IPR = 1, NGN(NGS(6)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
5600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
5400 CONTINUE
5000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(7)
SUMF = 0.
SUMK = 0.
DO 7600 IPR = 1, NGN(NGS(6)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFB(IPRSM)
SUMK = SUMK + ABSCO2(IPRSM)*RWGT(IPRSM+96)
7600 CONTINUE
FRACREFBC(IGC) = SUMF
ABSCO2C(IGC) = SUMK
7400 CONTINUE
END SUBROUTINE CMBGB7
!***************************************************************************
SUBROUTINE CMBGB8(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, ABSCO2A, ABSCO2B, &
ABSN2OA, ABSN2OB, CFC12, CFC22ADJ, &
SELFREFC, ABSCO2AC, ABSCO2BC, &
ABSN2OAC, ABSN2OBC, CFC12C, CFC22ADJC, &
FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 8: 1080-1180 cm-1 (low (i.e.>~300mb) - H2O; high - O3)
!***************************************************************************
! Input
REAL abscoefL(5,7,MG),abscoefH(5,7:59,MG), SELFREF(10,MG)
REAL FRACREFA(MG), FRACREFB(MG), ABSCO2A(MG), ABSCO2B(MG)
REAL ABSN2OA(MG), ABSN2OB(MG), CFC12(MG), CFC22ADJ(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG8), &
ABSCO2AC(NG8), ABSCO2BC(NG8), &
ABSN2OAC(NG8), ABSN2OBC(NG8), &
CFC12C(NG8), CFC22ADJC(NG8)
REAL FRACREFAC(NG8), FRACREFBC(NG8)
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,7
IPRSM = 0
DO 2400 IGC = 1,NGC(8)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(7)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JTJT,JPJP,IPRSM)*RWGT(IPRSM+112)
2600 CONTINUE
ABSA8(JTJT+(JPJP-1)*5,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JTJT = 1,5
DO 3200 JPJP = 7,59
IPRSM = 0
DO 3400 IGC = 1,NGC(8)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(7)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM+112)
3600 CONTINUE
ABSB8(JTJT+(JPJP-7)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(8)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(7)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+112)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(8)
SUMF1= 0.
SUMF2= 0.
SUMK1= 0.
SUMK2= 0.
SUMK3= 0.
SUMK4= 0.
SUMK5= 0.
SUMK6= 0.
DO 7600 IPR = 1, NGN(NGS(7)+IGC)
IPRSM = IPRSM + 1
SUMF1= SUMF1+ FRACREFA(IPRSM)
SUMF2= SUMF2+ FRACREFB(IPRSM)
SUMK1= SUMK1+ ABSCO2A(IPRSM)*RWGT(IPRSM+112)
SUMK2= SUMK2+ ABSCO2B(IPRSM)*RWGT(IPRSM+112)
SUMK3= SUMK3+ ABSN2OA(IPRSM)*RWGT(IPRSM+112)
SUMK4= SUMK4+ ABSN2OB(IPRSM)*RWGT(IPRSM+112)
SUMK5= SUMK5+ CFC12(IPRSM)*RWGT(IPRSM+112)
SUMK6= SUMK6+ CFC22ADJ(IPRSM)*RWGT(IPRSM+112)
7600 CONTINUE
FRACREFAC(IGC) = SUMF1
FRACREFBC(IGC) = SUMF2
ABSCO2AC(IGC) = SUMK1
ABSCO2BC(IGC) = SUMK2
ABSN2OAC(IGC) = SUMK3
ABSN2OBC(IGC) = SUMK4
CFC12C(IGC) = SUMK5
CFC22ADJC(IGC) = SUMK6
7400 CONTINUE
END SUBROUTINE CMBGB8
!***************************************************************************
SUBROUTINE CMBGB9(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, ABSN2O, &
SELFREFC, ABSN2OC, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 9: 1180-1390 cm-1 (low - H2O,CH4; high - CH4)
!***************************************************************************
! Input
REAL abscoefL(11,5,13,MG), abscoefH(5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9), FRACREFB(MG), ABSN2O(3*MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG9), ABSN2OC(3*NG9)
REAL FRACREFAC(NG9,9), FRACREFBC(NG9)
DO 2000 JN = 1,11
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(9)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(8)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+128)
2600 CONTINUE
ABSA9(JN+(JTJT-1)*11+(JPJP-1)*55,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(9)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(8)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM+128)
3600 CONTINUE
ABSB9(JTJT+(JPJP-13)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(9)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(8)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+128)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 5000 JN = 1,3
IPRSM = 0
DO 5400 IGC = 1,NGC(9)
SUMK = 0.
DO 5600 IPR = 1, NGN(NGS(8)+IGC)
IPRSM = IPRSM + 1
JND = (JN-1)*16
SUMK = SUMK + ABSN2O(JND+IPRSM)*RWGT(IPRSM+128)
5600 CONTINUE
JNDC = (JN-1)*NGC(9)
ABSN2OC(JNDC+IGC) = SUMK
5400 CONTINUE
5000 CONTINUE
DO 6000 JPJP = 1,9
IPRSM = 0
DO 6400 IGC = 1,NGC(9)
SUMF = 0.
DO 6600 IPR = 1, NGN(NGS(8)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
6600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
6400 CONTINUE
6000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(9)
SUMF = 0.
DO 7600 IPR = 1, NGN(NGS(8)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFB(IPRSM)
7600 CONTINUE
FRACREFBC(IGC) = SUMF
7400 CONTINUE
END SUBROUTINE CMBGB9
!***************************************************************************
SUBROUTINE CMBGB10(abscoefL, abscoefH, & 2,2
FRACREFA, FRACREFB, &
FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 10: 1390-1480 cm-1 (low - H2O; high - H2O)
!***************************************************************************
! Input
REAL abscoefL(5,13,MG),abscoefH(5,13:59,MG)
REAL FRACREFA(MG), FRACREFB(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL FRACREFAC(NG10), FRACREFBC(NG10)
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(10)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(9)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JTJT,JPJP,IPRSM)*RWGT(IPRSM+144)
2600 CONTINUE
ABSA10(JTJT+(JPJP-1)*5,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(10)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(9)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM+144)
3600 CONTINUE
ABSB10(JTJT+(JPJP-13)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(10)
SUMF1= 0.
SUMF2= 0.
DO 7600 IPR = 1, NGN(NGS(9)+IGC)
IPRSM = IPRSM + 1
SUMF1= SUMF1+ FRACREFA(IPRSM)
SUMF2= SUMF2+ FRACREFB(IPRSM)
7600 CONTINUE
FRACREFAC(IGC) = SUMF1
FRACREFBC(IGC) = SUMF2
7400 CONTINUE
END SUBROUTINE CMBGB10
!***************************************************************************
SUBROUTINE CMBGB11(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, &
SELFREFC, &
FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 11: 1480-1800 cm-1 (low - H2O; high - H2O)
!***************************************************************************
! Input
REAL abscoefL(5,13,MG),abscoefH(5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG), FRACREFB(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG11)
REAL FRACREFAC(NG11), FRACREFBC(NG11)
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(11)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(10)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JTJT,JPJP,IPRSM)*RWGT(IPRSM+160)
2600 CONTINUE
ABSA11(JTJT+(JPJP-1)*5,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(11)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(10)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM+160)
3600 CONTINUE
ABSB11(JTJT+(JPJP-13)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(11)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(10)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+160)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(11)
SUMF1= 0.
SUMF2= 0.
DO 7600 IPR = 1, NGN(NGS(10)+IGC)
IPRSM = IPRSM + 1
SUMF1= SUMF1+ FRACREFA(IPRSM)
SUMF2= SUMF2+ FRACREFB(IPRSM)
7600 CONTINUE
FRACREFAC(IGC) = SUMF1
FRACREFBC(IGC) = SUMF2
7400 CONTINUE
END SUBROUTINE CMBGB11
!***************************************************************************
SUBROUTINE CMBGB12(abscoefL, SELFREF, & 2,2
FRACREFA, &
SELFREFC, FRACREFAC )
!***************************************************************************
!
! BAND 12: 1800-2080 cm-1 (low - H2O,CO2; high - nothing)
!***************************************************************************
! Input
REAL abscoefL(9,5,13,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG12)
REAL FRACREFAC(NG12,9)
DO 2000 JN = 1,9
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(12)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(11)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+176)
2600 CONTINUE
ABSA12(JN+(JTJT-1)*9+(JPJP-1)*45,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(12)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(11)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+176)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 7000 JPJP = 1,9
IPRSM = 0
DO 7400 IGC = 1,NGC(12)
SUMF = 0.
DO 7600 IPR = 1, NGN(NGS(11)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
7600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
7400 CONTINUE
7000 CONTINUE
END SUBROUTINE CMBGB12
!***************************************************************************
SUBROUTINE CMBGB13(abscoefL, SELFREF, FRACREFA, & 2,2
SELFREFC, FRACREFAC )
!***************************************************************************
!
! BAND 13: 2080-2250 cm-1 (low - H2O,N2O; high - nothing)
!***************************************************************************
! Input
REAL abscoefL(9,5,13,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG13)
REAL FRACREFAC(NG13,9)
DO 2000 JN = 1,9
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(13)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(12)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+192)
2600 CONTINUE
ABSA13(JN+(JTJT-1)*9+(JPJP-1)*45,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(13)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(12)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+192)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 7000 JPJP = 1,9
IPRSM = 0
DO 7400 IGC = 1,NGC(13)
SUMF = 0.
DO 7600 IPR = 1, NGN(NGS(12)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
7600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
7400 CONTINUE
7000 CONTINUE
END SUBROUTINE CMBGB13
!***************************************************************************
SUBROUTINE CMBGB14(abscoefL, abscoefH, SELFREF, & 2,2
FRACREFA, FRACREFB, &
SELFREFC, FRACREFAC, FRACREFBC )
!***************************************************************************
!
! BAND 14: 2250-2380 cm-1 (low - CO2; high - CO2)
!***************************************************************************
! Input
REAL abscoefL(5,13,MG),abscoefH(5,13:59,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG), FRACREFB(MG)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG14)
REAL FRACREFAC(NG14), FRACREFBC(NG14)
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(14)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(13)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JTJT,JPJP,IPRSM)*RWGT(IPRSM+208)
2600 CONTINUE
ABSA14(JTJT+(JPJP-1)*5,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 3000 JTJT = 1,5
DO 3200 JPJP = 13,59
IPRSM = 0
DO 3400 IGC = 1,NGC(14)
SUMK = 0.
DO 3600 IPR = 1, NGN(NGS(13)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefH(JTJT,JPJP,IPRSM)*RWGT(IPRSM+208)
3600 CONTINUE
ABSB14(JTJT+(JPJP-13)*5,IGC) = SUMK
3400 CONTINUE
3200 CONTINUE
3000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(14)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(13)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+208)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
IPRSM = 0
DO 7400 IGC = 1,NGC(14)
SUMF1= 0.
SUMF2= 0.
DO 7600 IPR = 1, NGN(NGS(13)+IGC)
IPRSM = IPRSM + 1
SUMF1= SUMF1+ FRACREFA(IPRSM)
SUMF2= SUMF2+ FRACREFB(IPRSM)
7600 CONTINUE
FRACREFAC(IGC) = SUMF1
FRACREFBC(IGC) = SUMF2
7400 CONTINUE
END SUBROUTINE CMBGB14
!***************************************************************************
SUBROUTINE CMBGB15(abscoefL, SELFREF, FRACREFA, & 2,2
SELFREFC, FRACREFAC )
!***************************************************************************
!
! BAND 15: 2380-2600 cm-1 (low - N2O,CO2; high - nothing)
!***************************************************************************
! Input
REAL abscoefL(9,5,13,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG15)
REAL FRACREFAC(NG15,9)
DO 2000 JN = 1,9
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(15)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(14)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+224)
2600 CONTINUE
ABSA15(JN+(JTJT-1)*9+(JPJP-1)*45,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(15)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(14)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+224)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 7000 JPJP = 1,9
IPRSM = 0
DO 7400 IGC = 1,NGC(15)
SUMF = 0.
DO 7600 IPR = 1, NGN(NGS(14)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
7600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
7400 CONTINUE
7000 CONTINUE
END SUBROUTINE CMBGB15
!***************************************************************************
SUBROUTINE CMBGB16(abscoefL, SELFREF, FRACREFA, & 2,2
SELFREFC, FRACREFAC )
!***************************************************************************
!
! BAND 16: 2600-3000 cm-1 (low - H2O,CH4; high - nothing)
!***************************************************************************
! Input
REAL abscoefL(9,5,13,MG)
REAL SELFREF(10,MG)
REAL FRACREFA(MG,9)
! REAL RWGT(MG*NBANDS)
! Output
REAL SELFREFC(10,NG16)
REAL FRACREFAC(NG16,9)
DO 2000 JN = 1,9
DO 2000 JTJT = 1,5
DO 2200 JPJP = 1,13
IPRSM = 0
DO 2400 IGC = 1,NGC(16)
SUMK = 0.
DO 2600 IPR = 1, NGN(NGS(15)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + abscoefL(JN,JTJT,JPJP,IPRSM)*RWGT(IPRSM+240)
2600 CONTINUE
ABSA16(JN+(JTJT-1)*9+(JPJP-1)*45,IGC) = SUMK
2400 CONTINUE
2200 CONTINUE
2000 CONTINUE
DO 4000 JTJT = 1,10
IPRSM = 0
DO 4400 IGC = 1,NGC(16)
SUMK = 0.
DO 4600 IPR = 1, NGN(NGS(15)+IGC)
IPRSM = IPRSM + 1
SUMK = SUMK + SELFREF(JTJT,IPRSM)*RWGT(IPRSM+240)
4600 CONTINUE
SELFREFC(JTJT,IGC) = SUMK
4400 CONTINUE
4000 CONTINUE
DO 7000 JPJP = 1,9
IPRSM = 0
DO 7400 IGC = 1,NGC(16)
SUMF = 0.
DO 7600 IPR = 1, NGN(NGS(15)+IGC)
IPRSM = IPRSM + 1
SUMF = SUMF + FRACREFA(IPRSM,JPJP)
7600 CONTINUE
FRACREFAC(IGC,JPJP) = SUMF
7400 CONTINUE
7000 CONTINUE
END SUBROUTINE CMBGB16
!-------------------------------------------------------------------------
SUBROUTINE INIRAD (O3PROF,Pw, kts, kte) 4,2
!-------------------------------------------------------------------------
IMPLICIT NONE
!-------------------------------------------------------------------------
INTEGER, INTENT(IN ) :: kts,kte
REAL, DIMENSION( kts:kte ),INTENT(INOUT) :: O3PROF
REAL, DIMENSION( kts:kte+1 ),INTENT(IN ) :: Pw
! LOCAL VAR
REAL, DIMENSION( kts:kte+1 ) :: PAVEL, TAVEL
REAL, DIMENSION( 0:kte+1 ) :: PZ, TZ
INTEGER :: k
!
! COMPUTE OZONE MIXING RATIO DISTRIBUTION
!
DO K=kts,kte
O3PROF(K)=0.
ENDDO
CALL O3DATA(O3PROF, Pw, kts, kte)
!
END SUBROUTINE INIRAD
!-------------------------------------------------------------------------
SUBROUTINE O3DATA (O3PROF, Pw, kts, kte) 2
!-------------------------------------------------------------------------
IMPLICIT NONE
!-------------------------------------------------------------------------
!
INTEGER, INTENT(IN ) :: kts, kte
!
REAL, DIMENSION( kts:kte ),INTENT(INOUT) :: O3PROF
REAL, DIMENSION( kts:kte+1 ),INTENT(IN ) :: Pw
! LOCAL VAR
INTEGER :: K, JJ, NK
REAL :: PRLEVH(kts:kte+1),PPWRKH(32), &
O3WRK(31),PPWRK(31),O3SUM(31),PPSUM(31), &
O3WIN(31),PPWIN(31),O3ANN(31),PPANN(31)
REAL :: PB1, PB2, PT1, PT2
DATA O3SUM /5.297E-8,5.852E-8,6.579E-8,7.505E-8, &
8.577E-8,9.895E-8,1.175E-7,1.399E-7,1.677E-7,2.003E-7, &
2.571E-7,3.325E-7,4.438E-7,6.255E-7,8.168E-7,1.036E-6, &
1.366E-6,1.855E-6,2.514E-6,3.240E-6,4.033E-6,4.854E-6, &
5.517E-6,6.089E-6,6.689E-6,1.106E-5,1.462E-5,1.321E-5, &
9.856E-6,5.960E-6,5.960E-6/
DATA PPSUM /955.890,850.532,754.599,667.742,589.841, &
519.421,455.480,398.085,347.171,301.735,261.310,225.360, &
193.419,165.490,141.032,120.125,102.689, 87.829, 75.123, &
64.306, 55.086, 47.209, 40.535, 34.795, 29.865, 19.122, &
9.277, 4.660, 2.421, 1.294, 0.647/
!
DATA O3WIN /4.629E-8,4.686E-8,5.017E-8,5.613E-8, &
6.871E-8,8.751E-8,1.138E-7,1.516E-7,2.161E-7,3.264E-7, &
4.968E-7,7.338E-7,1.017E-6,1.308E-6,1.625E-6,2.011E-6, &
2.516E-6,3.130E-6,3.840E-6,4.703E-6,5.486E-6,6.289E-6, &
6.993E-6,7.494E-6,8.197E-6,9.632E-6,1.113E-5,1.146E-5, &
9.389E-6,6.135E-6,6.135E-6/
DATA PPWIN /955.747,841.783,740.199,649.538,568.404, &
495.815,431.069,373.464,322.354,277.190,237.635,203.433, &
174.070,148.949,127.408,108.915, 93.114, 79.551, 67.940, &
58.072, 49.593, 42.318, 36.138, 30.907, 26.362, 16.423, &
7.583, 3.620, 1.807, 0.938, 0.469/
!
DO K=1,31
PPANN(K)=PPSUM(K)
ENDDO
!
O3ANN(1)=0.5*(O3SUM(1)+O3WIN(1))
!
DO K=2,31
O3ANN(K)=O3WIN(K-1)+(O3WIN(K)-O3WIN(K-1))/(PPWIN(K)-PPWIN(K-1))* &
(PPSUM(K)-PPWIN(K-1))
ENDDO
!
DO K=2,31
O3ANN(K)=0.5*(O3ANN(K)+O3SUM(K))
ENDDO
!
DO K=1,31
O3WRK(K)=O3ANN(K)
PPWRK(K)=PPANN(K)
ENDDO
!
! CALCULATE HALF PRESSURE LEVELS FOR MODEL AND DATA LEVELS
!
! Pw is total P at w level
! Pw is in mb
DO K=kts,kte+1
NK=kte+1-K+1
PRLEVH(K)=Pw(NK)
ENDDO
!
PPWRKH(1)=1100.
DO K=2,31
PPWRKH(K)=(PPWRK(K)+PPWRK(K-1))/2.
ENDDO
PPWRKH(32)=0.
DO K=kts,kte
DO 25 JJ=1,31
IF((-(PRLEVH(K)-PPWRKH(JJ))).GE.0.)THEN
PB1=0.
ELSE
PB1=PRLEVH(K)-PPWRKH(JJ)
ENDIF
IF((-(PRLEVH(K)-PPWRKH(JJ+1))).GE.0.)THEN
PB2=0.
ELSE
PB2=PRLEVH(K)-PPWRKH(JJ+1)
ENDIF
IF((-(PRLEVH(K+1)-PPWRKH(JJ))).GE.0.)THEN
PT1=0.
ELSE
PT1=PRLEVH(K+1)-PPWRKH(JJ)
ENDIF
IF((-(PRLEVH(K+1)-PPWRKH(JJ+1))).GE.0.)THEN
PT2=0.
ELSE
PT2=PRLEVH(K+1)-PPWRKH(JJ+1)
ENDIF
O3PROF(K)=O3PROF(K)+(PB2-PB1-PT2+PT1)*O3WRK(JJ)
25 CONTINUE
O3PROF(K)=O3PROF(K)/(PRLEVH(K)-PRLEVH(K+1))
ENDDO
!
END SUBROUTINE O3DATA
!---------------------------------------------------------------------------
SUBROUTINE MM5ATM(CLDFRA,O3PROF,T,Tw,TSFC,QV,QC,QR,QI,QS,QG, & 1,2
P,Pw,DELZ,EMISS,R,G, &
PAVEL,TAVEL,PZ,TZ,CLDFRAC,TAUCLOUD,COLDRY, &
WKL,WX,TBOUND,SEMISS, &
!ccc Added for time-varying trace gases.
co2vmr, n2ovmr, ch4vmr, &
!ccc
kts,kte )
!---------------------------------------------------------------------------
! RRTM Longwave Radiative Transfer Model
! Atmospheric and Environmental Research, Inc., Cambridge, MA
!
! Revision for NCAR MM5: J. Dudhia (converted from CCM code)
!
! Input atmospheric profile from NCAR MM5, and prepare it for use in RRTM.
! Set other RRTM input parameters. Values are passed back through existing
! RRTM arrays and commons.
!---------------------------------------------------------------------------
! RRTM Definitions
! MXLAY = kte+1 ! Maximum number of model layers
! MAXXSEC ! Maximum number of cross sections
! NLAYERS ! Number of model layers (kte+1)
! PAVEL(MXLAY) ! Layer pressures (mb)
! PZ(0:MXLAY) ! Level (interface) pressures (mb)
! TAVEL(MXLAY) ! Layer temperatures (K)
! TZ(0:MXLAY) ! Level (interface) temperatures(mb)
! TBOUND ! Surface temperature (K)
! COLDRY(MXLAY) ! Dry air column (molecules/cm2)
! WKL(35,MXLAY) ! Molecular amounts (molecules/cm2)
! WBRODL(MXLAY) ! Inactive in this version
! WX(MAXXSEC) ! Cross-section amounts (molecules/cm2)
! CLDFRAC(MXLAY) ! Layer cloud fraction
! TAUCLOUD(MXLAY) ! Layer cloud optical depth
! AMD ! Atomic weight of dry air
! AMW ! Atomic weight of water
! AMO ! Atomic weight of ozone
! AMCH4 ! Atomic weight of methane
! AMN2O ! Atomic weight of nitrous oxide
! AMC11 ! Atomic weight of CFC-11
! AMC12 ! Atomic weight of CFC-12
! NXMOL ! Number of cross-section molecules
! IXINDX ! Cross-section molecule index (see below)
! IXSECT ! On/off flag for cross-sections (inactive)
! IXMAX ! Maximum number of cross-sections (inactive)
!
!-----------------------------------------------------------------------------
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
!----------------------------------------------------------------------------
! Activate cross section molecules:
! NXMOL - number of cross-sections input by user
! IXINDX(I) - index of cross-section molecule corresponding to Ith
! cross-section specified by user
! = 0 -- not allowed in RRTM
! = 1 -- CCL4
! = 2 -- CFC11
! = 3 -- CFC12
! = 4 -- CFC22
! DATA NXMOL /2/
! DATA IXINDX /0,2,3,0,31*0/
!
! CLOUD EMISSIVITIES (M^2/G)
! THESE ARE CONSISTENT WITH LWRAD (ABCW=0.5*(ABUP+ABDOWN))
!----------------------------------------------------------------------------
INTEGER, INTENT(IN ) :: kts, kte
!
REAL, DIMENSION( 35,kts:NLAYERS ), &
INTENT(INOUT) :: WKL
REAL, DIMENSION( MAXXSEC,kts:NLAYERS ), &
INTENT(INOUT) :: WX
REAL, INTENT(INOUT) :: TBOUND
REAL, DIMENSION(NBANDS), INTENT(INOUT) :: SEMISS
REAL, DIMENSION( kts:kte+1 ), INTENT(IN ) :: &
Tw, &
Pw
REAL, DIMENSION( kts:kte ), INTENT(IN ) :: &
CLDFRA, &
O3PROF, &
DELZ, &
T, &
P
REAL, DIMENSION( kts:kte ), INTENT(INOUT) :: &
QV
REAL, DIMENSION( kts:kte ), INTENT(IN ) :: &
QC, &
QR, &
QI, &
QS, &
QG
REAL, DIMENSION( kts:NLAYERS ), INTENT(INOUT) :: &
PAVEL, &
TAVEL, &
CLDFRAC, &
TAUCLOUD, &
COLDRY
REAL, DIMENSION( 0:NLAYERS ), INTENT(INOUT) :: &
PZ, &
TZ
REAL, INTENT(IN ) :: R,G,EMISS,TSFC
!ccc Added for time-varying trace gases mixing ratios.
! Trace gase variables
REAL(8), INTENT(IN ) :: co2vmr, n2ovmr, ch4vmr
!ccc
REAL :: GRAVIT
!
! LOCAL
REAL, DIMENSION( kts:kte ) :: CLDFRC, &
PINT, &
TINT, &
O3, &
N2O, &
CH4, &
CLWP, &
CIWP, &
PLWP, &
PIWP
! New declarations for RRTM buffer patch.
! Steven Cavallo, NCAR/MMM 01/2010
INTEGER, PARAMETER :: nproflevs = 60 ! Constant, from the table
INTEGER :: L, LL, klev ! Loop indices
REAL, DIMENSION( kts:NLAYERS ) :: O3PROF2, PZR, varint
REAL :: wght,vark,vark1
REAL :: PPROF(nproflevs), TPROF(nproflevs)
! Mean pressure and temperature profiles from midlatitude
! summer (MLS),midlatitude winter (MLW), sub-Arctic
! winter (SAW),and tropical (TROP) standard atmospheres.
DATA PPROF /1000.00,855.47,731.82,626.05,535.57,458.16, &
391.94,335.29,286.83,245.38,209.91,179.57, &
153.62,131.41,112.42,96.17,82.27,70.38, &
60.21,51.51,44.06,37.69,32.25,27.59, &
23.60,20.19,17.27,14.77,12.64,10.81, &
9.25,7.91,6.77,5.79,4.95,4.24, &
3.63,3.10,2.65,2.27,1.94,1.66, &
1.42,1.22,1.04,0.89,0.76,0.65, &
0.56,0.48,0.41,0.35,0.30,0.26, &
0.22,0.19,0.16,0.14,0.12,0.10/
DATA TPROF /279.94,276.16,270.73,264.14,256.71,249.28, &
241.97,234.91,228.78,224.02,220.52,217.31, &
215.21,213.48,211.63,211.45,211.73,212.71, &
213.81,214.95,215.96,216.73,217.42,218.11, &
218.89,219.92,221.31,222.84,224.39,226.04, &
227.78,229.73,231.88,234.22,236.82,239.50, &
242.30,245.21,248.13,251.08,254.04,257.02, &
259.84,261.88,263.38,264.67,265.42,265.34, &
264.45,262.76,260.85,258.78,256.49,254.02, &
251.07,248.23,245.46,242.77,239.87,237.53/
! End new declarations for buffer layer edit
CHARACTER*80 errmess
real :: amd ! Effective molecular weight of dry air (g/mol)
real :: amw ! Molecular weight of water vapor (g/mol)
real :: amo ! Molecular weight of ozone (g/mol)
real :: amch4 ! Molecular weight of methane (g/mol)
real :: amn2o ! Molecular weight of nitrous oxide (g/mol)
real :: amc11 ! Molecular weight of CFC11 (g/mol) - CFCL3
real :: amc12 ! Molecular weight of CFC12 (g/mol) - CF2CL2
real :: avgdro ! Avogadro's number (molecules/mole)
! Atomic weights for conversion from mass to volume mixing ratios
data amd / 28.9644 /
data amw / 18.0154 /
data amo / 47.9998 /
data amch4 / 16.0430 /
data amn2o / 44.0128 /
data amc11 / 137.3684 /
data amc12 / 120.9138 /
data avgdro/ 6.022E23 /
! Set molecular weight ratios
real :: amdw, & ! Molecular weight of dry air / water vapor
amdo, & ! Molecular weight of dry air / ozone
amdc, & ! Molecular weight of dry air / methane
amdn, & ! Molecular weight of dry air / nitrous oxide
amdc1, & ! Molecular weight of dry air / CFC11
amdc2 ! Molecular weight of dry air / CFC12
data amdw / 1.607758 /
data amdo / 0.603461 /
data amdc / 1.805423 /
data amdn / 0.658090 /
data amdc1/ 0.210852 /
data amdc2/ 0.239546 /
! Put in CO2 volume mixing ratio here (330 ppmv)
! Added H2O volume mixing ratio from standard atmosphere
! above 150 mb (Steven Cavallo, 01/2010).
!ccc
!ccc Modified CO2 VMR declaration for time-varying case.
! real :: co2vmr, h2ovmr
! data co2vmr / 330.e-6 /
! data h2ovmr / 5.00e-6 /
real :: h2ovmr
data h2ovmr / 5.00e-6 /
REAL :: ABCW,ABICE,ABRN,ABSN
DATA ABCW /0.144/
DATA ABICE /0.0735/
DATA ABRN /0.330E-3/
DATA ABSN /2.34E-3/
GRAVIT = G*100.
!
! MID-LAYER VALUES
DO K=kts,kte
RO=P(K)/(R*T(K))*100.
DZ=DELZ(K)
QV(K)=AMAX1(QV(K),1.E-12)
CLDFRC(K)=CLDFRA(K)
! PATHS IN G/M^2
! QI=0 if no ice phase
! QS=0 if no ice phase
CLWP(K)=RO*QC(K)*DZ*1000.
CIWP(K)=RO*QI(K)*DZ*1000.
PLWP(K)=(RO*QR(K))**0.75*DZ*1000.
PIWP(K)=(RO*QS(K))**0.75*DZ*1000.
O3(K)=O3PROF(K)
N2O(K)=0.
CH4(K)=0.
ENDDO
!ccc Unit conversion
N2O(:) = n2ovmr / amdn
CH4(:) = ch4vmr / amdc
!ccc
! Initialize all molecular amounts to zero here, then pass MM5 amounts
! into RRTM arrays WKL and WX below.
! DO 1000 ILAY = kts,kte+1
DO 1000 ILAY = kts,NLAYERS
DO 1100 ISP = 1,35
1100 WKL(ISP,ILAY) = 0.0
DO 1200 ISP = 1,MAXXSEC
1200 WX(ISP,ILAY) = 0.0
1000 CONTINUE
! Set parameters needed for RRTM execution:
IXSECT = 1
IXMAX = 4
! Set surface temperature. The longwave upward surface flux is
! computed in the Land Surface Model based on the surface
! temperature and the emissivity of the surface type for each
! grid point. The bottom interface temperature, tint(kte+1), is
! ground temperature consistent with this LW upward flux, and
! TBOUND is set to this temperature here.
! TBOUND = TINT(kte+1)
! TBOUND = Tw(kte+1)
TBOUND = TSFC
IF(TBOUND .GT. 340.)THEN
WRITE( errmess , '(A,F10.3)' ) 'rrtm: TBOUND exceeds table limit: reset ',TBOUND
CALL wrf_message (errmess)
TBOUND = 339.99
ENDIF
! Install MM5 profiles into RRTM arrays for pressure, temperature,
! and molecular amounts. Pressures are converted from cb
! (CCM) to mb (RRTM). H2O and trace gas amounts are converted from
! mass mixing ratio to volume mixing ratio. CO2 vmr is constant at all
! levels. The dry air column COLDRY (in molec/cm2) is calculated
! from the level pressures PZ (in mb) based on the hydrostatic equation
! and includes a correction to account for H2O in the layer. The
! molecular weight of moist air (amm) is calculated for each layer.
! RRTM is executed for additional levels (L = kte + int(p_top/4) + 1)
! from the model top (p_top) to 0 mb, to estimate the downward
! fluxes between the model top interface and the top of the atmosphere
! where kte is the top WRF model level index and p_top is the pressure at
! the top model level. H2O, CO2, N2O, and CH4 vmrs for these extra layers are
! set to the values in the model's top layer, though the O3 value is
! interpolated based on the US Std Atm. For GCMs with a model top near 0 mb,
! these extra layers are not needed, and NLAYERS should be set to the number
! of model layers (kte in this case).
! Note: RRTM levels count from bottom to top, while MM5 levels count
! from the top down and must be reversed here.
! NMOL = 6
! PZ(0) = pint(kte+1)
! TZ(0) = tint(kte+1)
PZ(0) = Pw(kte+1)
TZ(0) = Tw(kte+1)
! DO 2000 L = 1, NLAYERS-1
DO 2000 L = 1, kte
PAVEL(L) = p(kte+1-L)
TAVEL(L) = t(kte+1-L)
! PZ(L) = pint(kte+1-L)
! TZ(L) = tint(kte+1-L)
PZ(L) = Pw(kte+1-L)
TZ(L) = Tw(kte+1-L)
WKL(1,L) = qv(kte+1-L)*amdw
! Set the water vapor mixing ratio constant above
! the typical level where global and reanalysis data
! does not provide it. Steven Cavallo 01/2010.
!IF (PAVEL(L).LE.100) THEN
! WKL(1,L) = h2ovmr
!ENDIF
WKL(2,L) = co2vmr
WKL(3,L) = o3(kte+1-L)
! ozone is already bottom to top array but convert mmr to vmr
WKL(3,L) = o3(L)*amdo
WKL(4,L) = n2o(kte+1-L)*amdn
WKL(6,L) = ch4(kte+1-L)*amdc
amm = (1-WKL(1,L))*amd + WKL(1,L)*amw
COLDRY(L) = (PZ(L-1)-PZ(L))*1.E3*avgdro/ &
(gravit*amm*(1+WKL(1,L)))
2000 CONTINUE
! Set cross section molecule amounts from CCM; convert to vmr
! DO 2100 L=1, NLAYERS-1
DO 2100 L=1, kte
! WX(2,L) = c11mmr(kte+1-L)*amdc1
! WX(3,L) = c12mmr(kte+1-L)*amdc2
WX(2,L) = 0.
WX(3,L) = 0.
2100 CONTINUE
! old section
IF ( 1 .EQ. 0 ) THEN
! *****
! Set up values for extra layer at top of the atmosphere.
! The top layer temperature for all gridpoints is set to the top layer-1
! temperature plus a constant (0 K) that represents an isothermal layer
! above ptop. Top layer interface temperatures are
! linearly interpolated from the layer temperatures.
! Note: The top layer temperature and ozone amount are based on a 0-3mb
! top layer and must be modified if the layering is changed.
! This section should be commented if the extra layer is not needed.
PAVEL(NLAYERS) = 0.5*PZ(NLAYERS-1)
TAVEL(NLAYERS) = TAVEL(NLAYERS-1) + 0.0
PZ(NLAYERS) = 0.00
TZ(NLAYERS-1) = 0.5*(TAVEL(NLAYERS)+TAVEL(NLAYERS-1))
TZ(NLAYERS) = TZ(NLAYERS-1)+0.0
WKL(1,NLAYERS) = WKL(1,NLAYERS-1)
WKL(2,NLAYERS) = co2vmr
WKL(3,NLAYERS) = 0.6*WKL(3,NLAYERS-1)
WKL(4,NLAYERS) = WKL(4,NLAYERS-1)
WKL(6,NLAYERS) = WKL(6,NLAYERS-1)
amm = (1-WKL(1,NLAYERS-1))*amd + WKL(1,NLAYERS-1)*amw
! COLDRY(NLAYERS) = (PZ(NLAYERS-1))*1.E3*avgdro/ &
COLDRY(NLAYERS) = ((PZ(NLAYERS-1)-PZ(NLAYERS)))*1.E3*avgdro/ &
(gravit*amm*(1+WKL(1,NLAYERS-1)))
WX(2,NLAYERS) = WX(2,NLAYERS-1)
WX(3,NLAYERS) = WX(3,NLAYERS-1)
! *****
ENDIF
! *****
! Set up values for extra layers to the top of the atmosphere.
! Temperature is calculated based on an average temperature profile given
! here in a table. The input table data is linearly interpolated to the
! column pressure. Mixing ratios are held constant except for ozone.
! Caution should be used if model top pressure is less than 5 hPa.
! Steven Cavallo, NCAR/MMM, January 2010
! Calculate the column pressure buffer levels above the
! model top
DO 3000 L=kte+1,NLAYERS-1,1
PZ(L) = PZ(L-1) - deltap
PAVEL(L) = 0.5*(PZ(L) + PZ(L-1))
3000 CONTINUE
! Add zero as top level. This gets the temperature max at the
! stratopause, reducing the downward flux errors in the top
! levels. If zero happened to be the top level already,
! this will add another level with zero, but will not affect
! the radiative transfer calculation.
PZ(NLAYERS) = 0.00
PAVEL(NLAYERS) = 0.5*(PZ(NLAYERS) + PZ(NLAYERS-1))
! Interpolate the table temperatures to column pressure levels
DO 3100 L=1,NLAYERS,1
IF ( PPROF(nproflevs) .LT. PZ(L) ) THEN
DO 3150 LL=2,nproflevs,1
IF ( PPROF(LL) .LT. PZ(L) ) THEN
klev = LL - 1
exit
ENDIF
3150 CONTINUE
ELSE
klev = nproflevs
ENDIF
IF (klev .NE. nproflevs ) THEN
vark = TPROF(klev)
vark1 = TPROF(klev+1)
wght=( PZ(L)-PPROF(klev) ) / ( PPROF(klev+1)-PPROF(klev))
ELSE
vark = TPROF(klev)
vark1 = TPROF(klev)
wght = 0.0
ENDIF
varint(L) = wght*(vark1-vark)+vark
3100 CONTINUE
! Match the interpolated table temperature profile to WRF column
DO 3200 L=kte+1,NLAYERS,1
TZ(L) = varint(L) + (TZ(kte) - varint(kte))
TAVEL(L) = 0.5*(TZ(L) + TZ(L-1))
3200 CONTINUE
! Get the new ozone profile. First need to reverse pressure
! array for the ozone interpolator subroutines.
DO 3225 L=kts,NLAYERS,1
klev=NLAYERS-L+1
PZR(L)=PZ(klev)
3225 CONTINUE
CALL INIRAD (O3PROF2(kts:NLAYERS-1),PZR,kts,NLAYERS-1)
! Pick the top level to be the closest to zero from the table
O3PROF2(NLAYERS) = 6.135E-6
! Keep all molecular mixing ratios constant in the buffer zone,
! except for ozone
IF ( kte .NE. NLAYERS ) THEN
DO 3250 L=1,NLAYERS,1
WKL(3,L) = O3PROF2(L)*amdo! O3
IF ( L .GT. kte ) THEN
! WKL(1,L) = WKL(1,kte) ! H2O
WKL(1,L) = h2ovmr ! H2O above model top set to constant value
WKL(2,L) = co2vmr ! CO2
WKL(4,L) = WKL(4,kte) ! N2O
WKL(6,L) = WKL(6,kte) ! CH4
amm = (1-WKL(1,L))*amd + WKL(1,L)*amw
COLDRY(L) = (PZ(L-1)-PZ(L))*1.E3*avgdro/ &
(gravit*amm*(1+WKL(1,L)))
WX(2,L) = WX(2,kte)
WX(3,L) = WX(3,kte)
ENDIF
3250 CONTINUE
ENDIF
!
! End of buffer layer edit.
!
! Here, all molecules in WKL and WX are in volume mixing ratio; convert to
! molec/cm2 based on COLDRY for use in RRTM
DO 5000 L = 1, NLAYERS
DO 4200 IMOL = 1, NMOL
WKL(IMOL,L) = COLDRY(L) * WKL(IMOL,L)
4200 CONTINUE
DO 4400 IX = 1,MAXXSEC
IF (IXINDX(IX) .NE. 0) THEN
WX(IXINDX(IX),L) = COLDRY(L) * WX(IX,L) * 1.E-20
ENDIF
4400 CONTINUE
5000 CONTINUE
! Set spectral surface emissivity for each longwave band. The default value
! is set here to emiss(i,j) based on land-use (taken to be constant across band
! Comment: if land-surface uses skin temperature, emissivity must match that
! used in its calculation (e.g. 1.0)
DO 5500 N=1,NBANDS
SEMISS(N) = EMISS
5500 CONTINUE
! Transfer cloud fraction to RRTM array; compute cloud optical depth, TAUCLOUD,
! as the product of clwp and cloud mass absorption coefficient in MM5, which is
! a combination of liquid and ice absorption coefficients.
! Note: RRTM levels count from bottom to top, while CCM levels count from the
! top down and must be reversed here. Values for the extra RRTM levels (above
! the model top) are set to zero.
! DO 7000 L = 1, NLAYERS-1
DO 7000 L = 1, kte
TAUCLOUD(L) = ABCW*CLWP(kte+1-L)+ABICE*CIWP(kte+1-L) &
+ABRN*PLWP(kte+1-L)+ABSN*PIWP(kte+1-L)
IF(TAUCLOUD(L).GT.0.01)CLDFRC(kte+1-L)=1.
CLDFRAC(L) = cldfrc(kte+1-L)
7000 CONTINUE
! CLDFRAC(NLAYERS) = 0.0
! TAUCLOUD(NLAYERS) = 0.0
DO 7500 L = kte+1,NLAYERS,1
CLDFRAC(L) = 0.0
TAUCLOUD(L) = 0.0
7500 CONTINUE
END SUBROUTINE MM5ATM
!---------------------------------------------------------------------------
SUBROUTINE SETCOEF(kts,ktep1, & 2
PAVEL,TAVEL,COLDRY,COLH2O,COLCO2,COLO3, &
COLN2O,COLCH4,COLO2,CO2MULT, &
FAC00,FAC01,FAC10,FAC11, &
FORFAC,SELFFAC,SELFFRAC, &
JP,JT,JT1,INDSELF,WKL,LAYTROP,LAYSWTCH,LAYLOW )
!---------------------------------------------------------------------------
IMPLICIT NONE
!---------------------------------------------------------------------------
! RRTM Longwave Radiative Transfer Model
! Atmospheric and Environmental Research, Inc., Cambridge, MA
!
! Original version: E. J. Mlawer, et al.
! Revision for NCAR CCM: Michael J. Iacono; September, 1998
!
! For a given atmosphere, calculate the indices and fractions related to the
! pressure and temperature interpolations. Also calculate the values of the
! integrated Planck functions for each band at the level and layer
! temperatures.
!---------------------------------------------------------------------------
INTEGER, INTENT(IN ) :: kts, ktep1
REAL, DIMENSION( 35,kts:ktep1), &
INTENT(IN ) :: WKL
INTEGER, INTENT(INOUT) :: LAYTROP,LAYSWTCH,LAYLOW
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
PAVEL, &
TAVEL, &
COLDRY
REAL, DIMENSION( kts:ktep1 ), INTENT(INOUT) :: &
COLH2O, &
COLCO2, &
COLO3, &
COLN2O, &
COLCH4, &
COLO2, &
CO2MULT, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
FORFAC, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(INOUT) :: &
JP, &
JT, &
JT1, &
INDSELF
! LOCAL
INTEGER :: LAY, JP1
REAL :: STPFAC, PLOG, FP, FT, FT1, WATERS, WATER, &
CALEFAC, FACTOR, CO2REG, COMPFP, SCALEFAC
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STPFAC = 296./1013.
LAYTROP = 0
LAYSWTCH = 0
LAYLOW = 0
DO 7000 LAY = 1, NLAYERS
! Find the two reference pressures on either side of the
! layer pressure. Store them in JP and JP1. Store in FP the
! fraction of the difference (in ln(pressure)) between these
! two values that the layer pressure lies.
PLOG = LOG(PAVEL(LAY))
JP(LAY) = INT(36. - 5*(PLOG+0.04))
IF (JP(LAY) .LT. 1) THEN
JP(LAY) = 1
ELSEIF (JP(LAY) .GT. 58) THEN
JP(LAY) = 58
ENDIF
JP1 = JP(LAY) + 1
FP = 5. * (PREFLOG(JP(LAY)) - PLOG)
! Determine, for each reference pressure (JP and JP1), which
! reference temperature (these are different for each
! reference pressure) is nearest the layer temperature but does
! not exceed it. Store these indices in JT and JT1, resp.
! Store in FT (resp. FT1) the fraction of the way between JT
! (JT1) and the next highest reference temperature that the
! layer temperature falls.
JT(LAY) = INT(3. + (TAVEL(LAY)-TREF(JP(LAY)))/15.)
IF (JT(LAY) .LT. 1) THEN
JT(LAY) = 1
ELSEIF (JT(LAY) .GT. 4) THEN
JT(LAY) = 4
ENDIF
FT = ((TAVEL(LAY)-TREF(JP(LAY)))/15.) - FLOAT(JT(LAY)-3)
JT1(LAY) = INT(3. + (TAVEL(LAY)-TREF(JP1))/15.)
IF (JT1(LAY) .LT. 1) THEN
JT1(LAY) = 1
ELSEIF (JT1(LAY) .GT. 4) THEN
JT1(LAY) = 4
ENDIF
FT1 = ((TAVEL(LAY)-TREF(JP1))/15.) - FLOAT(JT1(LAY)-3)
WATER = WKL(1,LAY)/COLDRY(LAY)
SCALEFAC = PAVEL(LAY) * STPFAC / TAVEL(LAY)
! If the pressure is less than ~100mb, perform a different
! set of species interpolations.
IF (PLOG .LE. 4.56) GO TO 5300
LAYTROP = LAYTROP + 1
! For one band, the "switch" occurs at ~300 mb.
! JD: changed from (PLOG .GE. 5.76) to avoid out-of-range
IF (PLOG .Gt. 5.76) LAYSWTCH = LAYSWTCH + 1
IF (PLOG .GE. 6.62) LAYLOW = LAYLOW + 1
!
FORFAC(LAY) = SCALEFAC / (1.+WATER)
! Set up factors needed to separately include the water vapor
! self-continuum in the calculation of absorption coefficient.
SELFFAC(LAY) = WATER * FORFAC(LAY)
FACTOR = (TAVEL(LAY)-188.0)/7.2
INDSELF(LAY) = MIN(9, MAX(1, INT(FACTOR)-7))
SELFFRAC(LAY) = FACTOR - FLOAT(INDSELF(LAY) + 7)
! Calculate needed column amounts.
COLH2O(LAY) = 1.E-20 * WKL(1,LAY)
COLCO2(LAY) = 1.E-20 * WKL(2,LAY)
COLO3(LAY) = 1.E-20 * WKL(3,LAY)
COLN2O(LAY) = 1.E-20 * WKL(4,LAY)
COLCH4(LAY) = 1.E-20 * WKL(6,LAY)
COLO2(LAY) = 1.E-20 * WKL(7,LAY)
IF (COLCO2(LAY) .EQ. 0.) COLCO2(LAY) = 1.E-32 * COLDRY(LAY)
IF (COLN2O(LAY) .EQ. 0.) COLN2O(LAY) = 1.E-32 * COLDRY(LAY)
IF (COLCH4(LAY) .EQ. 0.) COLCH4(LAY) = 1.E-32 * COLDRY(LAY)
! Using E = 1334.2 cm-1.
CO2REG = 3.55E-24 * COLDRY(LAY)
CO2MULT(LAY)= (COLCO2(LAY) - CO2REG) * &
272.63*EXP(-1919.4/TAVEL(LAY))/(8.7604E-4*TAVEL(LAY))
GO TO 5400
! Above LAYTROP.
5300 CONTINUE
FORFAC(LAY) = SCALEFAC / (1.+WATER)
! Calculate needed column amounts.
COLH2O(LAY) = 1.E-20 * WKL(1,LAY)
COLCO2(LAY) = 1.E-20 * WKL(2,LAY)
COLO3(LAY) = 1.E-20 * WKL(3,LAY)
COLN2O(LAY) = 1.E-20 * WKL(4,LAY)
COLCH4(LAY) = 1.E-20 * WKL(6,LAY)
COLO2(LAY) = 1.E-20 * WKL(7,LAY)
IF (COLCO2(LAY) .EQ. 0.) COLCO2(LAY) = 1.E-32 * COLDRY(LAY)
IF (COLN2O(LAY) .EQ. 0.) COLN2O(LAY) = 1.E-32 * COLDRY(LAY)
IF (COLCH4(LAY) .EQ. 0.) COLCH4(LAY) = 1.E-32 * COLDRY(LAY)
CO2REG = 3.55E-24 * COLDRY(LAY)
CO2MULT(LAY)= (COLCO2(LAY) - CO2REG) * &
272.63*EXP(-1919.4/TAVEL(LAY))/(8.7604E-4*TAVEL(LAY))
5400 CONTINUE
! We have now isolated the layer ln pressure and temperature,
! between two reference pressures and two reference temperatures
! (for each reference pressure). We multiply the pressure
! fraction FP with the appropriate temperature fractions to get
! the factors that will be needed for the interpolation that yields
! the optical depths (performed in routines TAUGBn for band n).
COMPFP = 1. - FP
FAC10(LAY) = COMPFP * FT
FAC00(LAY) = COMPFP * (1. - FT)
FAC11(LAY) = FP * FT1
FAC01(LAY) = FP * (1. - FT1)
7000 CONTINUE
! Set LAYLOW for profiles with surface pressure less than 750mb.
IF (LAYLOW.EQ.0) LAYLOW=1
! Sometimes round-off gives wrong LAYSWTCH therefore check here (JD)
IF (JP(LAYSWTCH+1).LE.6) THEN
LAYSWTCH=LAYSWTCH+1
ENDIF
END SUBROUTINE SETCOEF
!-------------------------------------------------------------------------------
!* *
!* Optical depths developed for the *
!* *
!* RAPID RADIATIVE TRANSFER MODEL (RRTM) *
!* *
!* *
!* ATMOSPHERIC AND ENVIRONMENTAL RESEARCH, INC. *
!* 840 MEMORIAL DRIVE *
!* CAMBRIDGE, MA 02139 *
!* *
!* *
!* ELI J. MLAWER *
!* STEVEN J. TAUBMAN *
!* SHEPARD A. CLOUGH *
!* *
!* *
!* *
!* *
!* email: mlawer@aer.com *
!* *
!* The authors wish to acknowledge the contributions of the *
!* following people: Patrick D. Brown, Michael J. Iacono, *
!* Ronald E. Farren, Luke Chen, Robert Bergstrom. *
!* *
!-------------------------------------------------------------------------------
!* *
!* Revision for NCAR CCM: Michael J. Iacono; September, 1998 *
!* *
!* TAUMOL *
!* *
!* This file contains the subroutines TAUGBn (where n goes from *
!* 1 to 16). TAUGBn calculates the optical depths and Planck fractions *
!* per g-value and layer for band n. *
!* *
!* Output: optical depths (unitless) *
!* fractions needed to compute Planck functions at every layer *
!* and g-value *
!* *
!* COMMON /TAUGCOM/ TAUG(MXLAY,MG) *
!* COMMON /PLANKG/ FRACS(MXLAY,MG) *
!* *
!* Input *
!* *
!* COMMON /FEATURES/ NG(NBANDS),NSPA(NBANDS),NSPB(NBANDS) *
!* COMMON /PRECISE/ ONEMINUS *
!* COMMON /PROFILE/ NLAYERS,PAVEL(MXLAY),TAVEL(MXLAY), *
!* & PZ(0:MXLAY),TZ(0:MXLAY) *
!* COMMON /PROFDATA/ LAYTROP,LAYSWTCH,LAYLOW, *
!* & COLH2O(MXLAY),COLCO2(MXLAY), *
!* & COLO3(MXLAY),COLN2O(MXLAY),COLCH4(MXLAY), *
!* & COLO2(MXLAY),CO2MULT(MXLAY) *
!* COMMON /INTFAC/ FAC00(MXLAY),FAC01(MXLAY), *
!* & FAC10(MXLAY),FAC11(MXLAY) *
!* COMMON /INTIND/ JP(MXLAY),JT(MXLAY),JT1(MXLAY) *
!* COMMON /SELF/ SELFFAC(MXLAY), SELFFRAC(MXLAY), INDSELF(MXLAY) *
!* *
!* Description: *
!* NG(IBAND) - number of g-values in band IBAND *
!* NSPA(IBAND) - for the lower atmosphere, the number of reference *
!* atmospheres that are stored for band IBAND per *
!* pressure level and temperature. Each of these *
!* atmospheres has different relative amounts of the *
!* key species for the band (i.e. different binary *
!* species parameters). *
!* NSPB(IBAND) - same for upper atmosphere *
!* ONEMINUS - since problems are caused in some cases by interpolation *
!* parameters equal to or greater than 1, for these cases *
!* these parameters are set to this value, slightly < 1. *
!* PAVEL - layer pressures (mb) *
!* TAVEL - layer temperatures (degrees K) *
!* PZ - level pressures (mb) *
!* TZ - level temperatures (degrees K) *
!* LAYTROP - layer at which switch is made from one combination of *
!* key species to another *
!* COLH2O, COLCO2, COLO3, COLN2O, COLCH4 - column amounts of water *
!* vapor,carbon dioxide, ozone, nitrous ozide, methane, *
!* respectively (molecules/cm**2) *
!* CO2MULT - for bands in which carbon dioxide is implemented as a *
!* trace species, this is the factor used to multiply the *
!* band's average CO2 absorption coefficient to get the added *
!* contribution to the optical depth relative to 355 ppm. *
!* FACij(LAY) - for layer LAY, these are factors that are needed to *
!* compute the interpolation factors that multiply the *
!* appropriate reference k-values. A value of 0 (1) for *
!* i,j indicates that the corresponding factor multiplies *
!* reference k-value for the lower (higher) of the two *
!* appropriate temperatures, and altitudes, respectively. *
!* JP - the index of the lower (in altitude) of the two appropriate *
!* reference pressure levels needed for interpolation *
!* JT, JT1 - the indices of the lower of the two appropriate reference *
!* temperatures needed for interpolation (for pressure *
!* levels JP and JP+1, respectively) *
!* SELFFAC - scale factor needed to water vapor self-continuum, equals *
!* (water vapor density)/(atmospheric density at 296K and *
!* 1013 mb) *
!* SELFFRAC - factor needed for temperature interpolation of reference *
!* water vapor self-continuum data *
!* INDSELF - index of the lower of the two appropriate reference *
!* temperatures needed for the self-continuum interpolation *
!* *
!* Data input *
!* COMMON /Kn/ KA(NSPA(n),5,13,MG), KB(NSPB(n),5,13:59,MG), SELFREF(10,MG) *
!* (note: n is the band number) *
!* *
!* Description: *
!* KA - k-values for low reference atmospheres (no water vapor *
!* self-continuum) (units: cm**2/molecule) *
!* KB - k-values for high reference atmospheres (all sources) *
!* (units: cm**2/molecule) *
!* SELFREF - k-values for water vapor self-continuum for reference *
!* atmospheres (used below LAYTROP) *
!* (units: cm**2/molecule) *
!* *
!* DIMENSION ABSA(65*NSPA(n),MG), ABSB(235*NSPB(n),MG) *
!* EQUIVALENCE (KA,ABSA),(KB,ABSB) *
!* *
!*******************************************************************************
!---------------------------------------------------------------------------
SUBROUTINE TAUGB1(kts,ktep1,COLH2O,FAC00,FAC01,FAC10,FAC11, & 2,2
FORFAC,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF, &
PFRAC,TAUG,LAYTROP )
!---------------------------------------------------------------------------
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
FORFAC, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! Written by Eli J. Mlawer, Atmospheric & Environmental Research.
! Revised by Michael J. Iacono, Atmospheric & Environmental Research.
! BAND 1: 10-250 cm-1 (low - H2O; high - H2O)
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
! Compute the optical depth by interpolating in ln(pressure) and
! temperature. Below LAYTROP, the water vapor self-continuum
! is interpolated (in temperature) separately.
!cdir novector
DO 2500 LAY = 1, LAYTROP
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(1) + 1
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(1) + 1
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG1
TAUG(IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSA1(IND0,IG) + &
FAC10(LAY) * ABSA1(IND0+1,IG) + &
FAC01(LAY) * ABSA1(IND1,IG) + &
FAC11(LAY) * ABSA1(IND1+1,IG) + &
SELFFAC(LAY) * (SELFREFC1(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC1(INDS+1,IG) - SELFREFC1(INDS,IG))) + &
FORFAC(LAY) * FORREFC1(IG))
PFRAC(IG,LAY) = FRACREFAC1(IG)
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(1) + 1
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(1) + 1
DO 3000 IG = 1, NG1
TAUG(IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSB1(IND0,IG) + &
FAC10(LAY) * ABSB1(IND0+1,IG) + &
FAC01(LAY) * ABSB1(IND1,IG) + &
FAC11(LAY) * ABSB1(IND1+1,IG) + &
FORFAC(LAY) * FORREFC1(IG))
PFRAC(IG,LAY) = FRACREFBC1(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB1
!----------------------------------------------------------------------------
SUBROUTINE TAUGB2(kts,ktep1,COLDRY,COLH2O,FAC00,FAC01,FAC10,FAC11, & 2,2
FORFAC,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF, &
PFRAC,TAUG,LAYTROP )
!----------------------------------------------------------------------------
! BAND 2: 250-500 cm-1 (low - H2O; high - H2O)
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, PARAMETER :: NGS1=8
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLDRY, &
COLH2O, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
FORFAC, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
DIMENSION FC00(kts:ktep1),FC01(kts:ktep1),FC10(kts:ktep1),FC11(kts:ktep1)
DIMENSION REFPARAM(13)
! These are the mixing ratios for H2O for a MLS atmosphere at the
! 13 RRTM reference pressure levels: 1.8759999E-02, 1.2223309E-02,
! 5.8908667E-03, 2.7675382E-03, 1.4065107E-03, 7.5969833E-04,
! 3.8875898E-04, 1.6542293E-04, 3.7189537E-05, 7.4764857E-06,
! 4.3081886E-06, 3.3319423E-06, 3.2039343E-06/
! The following are parameters related to the reference water vapor
! mixing ratios by REFPARAM(I) = REFH2O(I) / (.002+REFH2O(I)).
! These parameters are used for the Planck function interpolation.
DATA REFPARAM/ &
0.903661, 0.859386, 0.746542, 0.580496, 0.412889, 0.275283, &
0.162745, 7.63929E-02, 1.82553E-02, 3.72432E-03, &
2.14946E-03, 1.66320E-03, 1.59940E-03/
! Compute the optical depth by interpolating in ln(pressure) and
! temperature. Below LAYTROP, the water vapor self-continuum is
! interpolated (in temperature) separately.
!cdir novector
DO 2500 LAY = 1, LAYTROP
WATER = 1.E20 * COLH2O(LAY) / COLDRY(LAY)
H2OPARAM = WATER/(WATER +.002)
DO 1800 IFRAC = 2, 12
IF (H2OPARAM .GE. REFPARAM(IFRAC)) GO TO 1900
1800 CONTINUE
1900 CONTINUE
FRACINT = (H2OPARAM-REFPARAM(IFRAC))/ &
(REFPARAM(IFRAC-1)-REFPARAM(IFRAC))
FP = FAC11(LAY) + FAC01(LAY)
IFP = 2.E2*FP+0.5
IF (IFP.LE.0) IFP = 0
FC00(LAY) = FAC00(LAY) * CORR2(IFP)
FC10(LAY) = FAC10(LAY) * CORR2(IFP)
FC01(LAY) = FAC01(LAY) * CORR1(IFP)
FC11(LAY) = FAC11(LAY) * CORR1(IFP)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(2) + 1
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(2) + 1
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG2
TAUG(NGS1+IG,LAY) = COLH2O(LAY) * &
(FC00(LAY) * ABSA2(IND0,IG) + &
FC10(LAY) * ABSA2(IND0+1,IG) + &
FC01(LAY) * ABSA2(IND1,IG) + &
FC11(LAY) * ABSA2(IND1+1,IG) + &
SELFFAC(LAY) * (SELFREFC2(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC2(INDS+1,IG) - SELFREFC2(INDS,IG))) + &
FORFAC(LAY) * FORREFC2(IG))
PFRAC(NGS1+IG,LAY) = FRACREFAC2(IG,IFRAC) + FRACINT * &
(FRACREFAC2(IG,IFRAC-1)-FRACREFAC2(IG,IFRAC))
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
FP = FAC11(LAY) + FAC01(LAY)
IFP = 2.E2*FP+0.5
IF (IFP.LE.0) IFP = 0
FC00(LAY) = FAC00(LAY) * CORR2(IFP)
FC10(LAY) = FAC10(LAY) * CORR2(IFP)
FC01(LAY) = FAC01(LAY) * CORR1(IFP)
FC11(LAY) = FAC11(LAY) * CORR1(IFP)
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(2) + 1
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(2) + 1
DO 3000 IG = 1, NG2
TAUG(NGS1+IG,LAY) = COLH2O(LAY) * &
(FC00(LAY) * ABSB2(IND0,IG) + &
FC10(LAY) * ABSB2(IND0+1,IG) + &
FC01(LAY) * ABSB2(IND1,IG) + &
FC11(LAY) * ABSB2(IND1+1,IG) + &
FORFAC(LAY) * FORREFC2(IG))
PFRAC(NGS1+IG,LAY) = FRACREFBC2(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB2
!-----------------------------------------------------------------------------
SUBROUTINE TAUGB3(kts,ktep1,COLH2O,COLCO2,COLN2O,FAC00,FAC01,FAC10, & 2,3
FAC11,FORFAC,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF, &
PFRAC,TAUG,LAYTROP )
!-----------------------------------------------------------------------------
! BAND 3: 500-630 cm-1 (low - H2O,CO2; high - H2O,CO2)
INTEGER, PARAMETER :: NGS2=22
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLCO2, &
COLN2O, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
FORFAC, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
DIMENSION H2OREF(59),CO2REF(59), ETAREF(10)
REAL N2OMULT,N2OREF(59)
DATA ETAREF/ &
0.,0.125,0.25,0.375,0.5,0.625,0.75,0.875,0.9875,1.0/
DATA H2OREF/ &
1.87599E-02,1.22233E-02,5.89086E-03,2.76753E-03,1.40651E-03, &
7.59698E-04,3.88758E-04,1.65422E-04,3.71895E-05,7.47648E-06, &
4.30818E-06,3.33194E-06,3.20393E-06,3.16186E-06,3.25235E-06, &
3.42258E-06,3.62884E-06,3.91482E-06,4.14875E-06,4.30810E-06, &
4.44204E-06,4.57783E-06,4.70865E-06,4.79432E-06,4.86971E-06, &
4.92603E-06,4.96688E-06,4.99628E-06,5.05266E-06,5.12658E-06, &
5.25028E-06,5.35708E-06,5.45085E-06,5.48304E-06,5.50000E-06, &
5.50000E-06,5.45359E-06,5.40468E-06,5.35576E-06,5.25327E-06, &
5.14362E-06,5.03396E-06,4.87662E-06,4.69787E-06,4.51911E-06, &
4.33600E-06,4.14416E-06,3.95232E-06,3.76048E-06,3.57217E-06, &
3.38549E-06,3.19881E-06,3.01212E-06,2.82621E-06,2.64068E-06, &
2.45515E-06,2.26962E-06,2.08659E-06,1.93029E-06/
DATA N2OREF/ &
3.20000E-07,3.20000E-07,3.20000E-07,3.20000E-07,3.20000E-07, &
3.19652E-07,3.15324E-07,3.03830E-07,2.94221E-07,2.84953E-07, &
2.76714E-07,2.64709E-07,2.42847E-07,2.09547E-07,1.71945E-07, &
1.37491E-07,1.13319E-07,1.00354E-07,9.12812E-08,8.54633E-08, &
8.03631E-08,7.33718E-08,6.59754E-08,5.60386E-08,4.70901E-08, &
3.99774E-08,3.29786E-08,2.60642E-08,2.10663E-08,1.65918E-08, &
1.30167E-08,1.00900E-08,7.62490E-09,6.11592E-09,4.66725E-09, &
3.28574E-09,2.84838E-09,2.46198E-09,2.07557E-09,1.85507E-09, &
1.65675E-09,1.45843E-09,1.31948E-09,1.20716E-09,1.09485E-09, &
9.97803E-10,9.31260E-10,8.64721E-10,7.98181E-10,7.51380E-10, &
7.13670E-10,6.75960E-10,6.38250E-10,6.09811E-10,5.85998E-10, &
5.62185E-10,5.38371E-10,5.15183E-10,4.98660E-10/
DATA CO2REF/ &
53*3.55E-04, 3.5470873E-04, 3.5427220E-04, 3.5383567E-04, &
3.5339911E-04, 3.5282588E-04, 3.5079606E-04/
STRRAT = 1.19268
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
!cdir novector
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT*COLCO2(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
IF (JS .EQ. 8) THEN
IF (FS .GE. 0.9) THEN
JS = 9
FS = 10. * (FS - 0.9)
ELSE
FS = FS/0.9
ENDIF
ENDIF
NS = JS + INT(FS + 0.5)
FP = FAC01(LAY) + FAC11(LAY)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(3) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(3) + JS
INDS = INDSELF(LAY)
COLREF1 = N2OREF(JP(LAY))
COLREF2 = N2OREF(JP(LAY)+1)
IF (NS .EQ. 10) THEN
WCOMB1 = H2OREF(JP(LAY))
WCOMB2 = H2OREF(JP(LAY)+1)
ELSE
WCOMB1 = STRRAT * CO2REF(JP(LAY))/(1.-ETAREF(NS))
WCOMB2 = STRRAT * CO2REF(JP(LAY)+1)/(1.-ETAREF(NS))
ENDIF
RATIO = (COLREF1/WCOMB1)+FP*((COLREF2/WCOMB2)-(COLREF1/WCOMB1))
CURRN2O = SPECCOMB * RATIO
N2OMULT = COLN2O(LAY) - CURRN2O
!!DIR$ VECTOR
DO 2000 IG = 1, NG3
TAUG(NGS2+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA3(IND0,IG) + &
FAC100 * ABSA3(IND0+1,IG) + &
FAC010 * ABSA3(IND0+10,IG) + &
FAC110 * ABSA3(IND0+11,IG) + &
FAC001 * ABSA3(IND1,IG) + &
FAC101 * ABSA3(IND1+1,IG) + &
FAC011 * ABSA3(IND1+10,IG) + &
FAC111 * ABSA3(IND1+11,IG)) + &
COLH2O(LAY) * &
(SELFFAC(LAY) * (SELFREFC3(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC3(INDS+1,IG) - SELFREFC3(INDS,IG))) + &
FORFAC(LAY) * FORREFC3(IG)) &
+ N2OMULT * ABSN2OAC3(IG)
PFRAC(NGS2+IG,LAY) = FRACREFAC3(IG,JS) + FS * &
(FRACREFAC3(IG,JS+1) - FRACREFAC3(IG,JS))
2000 CONTINUE
2500 CONTINUE
!!DIR$ NOVECTOR
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
SPECCOMB = COLH2O(LAY) + STRRAT*COLCO2(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 4.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
NS = JS + INT(FS + 0.5)
FP = FAC01(LAY) + FAC11(LAY)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(3) + JS
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(3) + JS
COLREF1 = N2OREF(JP(LAY))
COLREF2 = N2OREF(JP(LAY)+1)
IF (NS .EQ. 5) THEN
WCOMB1 = H2OREF(JP(LAY))
WCOMB2 = H2OREF(JP(LAY)+1)
ELSE
WCOMB1 = STRRAT * CO2REF(JP(LAY))/(1.-ETAREF(NS))
WCOMB2 = STRRAT * CO2REF(JP(LAY)+1)/(1.-ETAREF(NS))
ENDIF
RATIO = (COLREF1/WCOMB1)+FP*((COLREF2/WCOMB2)-(COLREF1/WCOMB1))
CURRN2O = SPECCOMB * RATIO
N2OMULT = COLN2O(LAY) - CURRN2O
!!DIR$ VECTOR
DO 3000 IG = 1, NG3
TAUG(NGS2+IG,LAY) = SPECCOMB * &
(FAC000 * ABSB3(IND0,IG) + &
FAC100 * ABSB3(IND0+1,IG) + &
FAC010 * ABSB3(IND0+5,IG) + &
FAC110 * ABSB3(IND0+6,IG) + &
FAC001 * ABSB3(IND1,IG) + &
FAC101 * ABSB3(IND1+1,IG) + &
FAC011 * ABSB3(IND1+5,IG) + &
FAC111 * ABSB3(IND1+6,IG)) + &
COLH2O(LAY) * FORFAC(LAY) * FORREFC3(IG) &
+ N2OMULT * ABSN2OBC3(IG)
PFRAC(NGS2+IG,LAY) = FRACREFBC3(IG,JS) + FS * &
(FRACREFBC3(IG,JS+1) - FRACREFBC3(IG,JS))
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB3
!----------------------------------------------------------------------------
SUBROUTINE TAUGB4(kts,ktep1,COLH2O,COLCO2,COLO3,FAC00,FAC01,FAC10, & 2,3
FAC11,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF, &
PFRAC,TAUG,LAYTROP )
!----------------------------------------------------------------------------
! BAND 4: 630-700 cm-1 (low - H2O,CO2; high - O3,CO2)
INTEGER, PARAMETER :: NGS3=38
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLCO2, &
COLO3, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STRRAT1 = 850.577
STRRAT2 = 35.7416
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
!!DIR$ NOVECTOR
!cdir novector
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT1*COLCO2(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(4) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(4) + JS
INDS = INDSELF(LAY)
!!DIR$ VECTOR
DO 2000 IG = 1, NG4
TAUG(NGS3+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA4(IND0,IG) + &
FAC100 * ABSA4(IND0+1,IG) + &
FAC010 * ABSA4(IND0+9,IG) + &
FAC110 * ABSA4(IND0+10,IG) + &
FAC001 * ABSA4(IND1,IG) + &
FAC101 * ABSA4(IND1+1,IG) + &
FAC011 * ABSA4(IND1+9,IG) + &
FAC111 * ABSA4(IND1+10,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC4(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC4(INDS+1,IG) - SELFREFC4(INDS,IG)))
PFRAC(NGS3+IG,LAY) = FRACREFAC4(IG,JS) + FS * &
(FRACREFAC4(IG,JS+1) - FRACREFAC4(IG,JS))
2000 CONTINUE
2500 CONTINUE
!!DIR$ NOVECTOR
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
SPECCOMB = COLO3(LAY) + STRRAT2*COLCO2(LAY)
SPECPARM = COLO3(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 4.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
IF (JS .GT. 1) THEN
JS = JS + 1
ELSEIF (FS .GE. 0.0024) THEN
JS = 2
FS = (FS - 0.0024)/0.9976
ELSE
JS = 1
FS = FS/0.0024
ENDIF
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(4) + JS
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(4) + JS
!!DIR$ VECTOR
DO 3000 IG = 1, NG4
TAUG(NGS3+IG,LAY) = SPECCOMB * &
(FAC000 * ABSB4(IND0,IG) + &
FAC100 * ABSB4(IND0+1,IG) + &
FAC010 * ABSB4(IND0+6,IG) + &
FAC110 * ABSB4(IND0+7,IG) + &
FAC001 * ABSB4(IND1,IG) + &
FAC101 * ABSB4(IND1+1,IG) + &
FAC011 * ABSB4(IND1+6,IG) + &
FAC111 * ABSB4(IND1+7,IG))
PFRAC(NGS3+IG,LAY) = FRACREFBC4(IG,JS) + FS * &
(FRACREFBC4(IG,JS+1) - FRACREFBC4(IG,JS))
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB4
!----------------------------------------------------------------------------
SUBROUTINE TAUGB5(kts,ktep1,COLH2O,COLCO2,COLO3,FAC00,FAC01,FAC10, & 2,3
FAC11,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,WX, &
PFRAC,TAUG,LAYTROP )
!----------------------------------------------------------------------------
! BAND 5: 700-820 cm-1 (low - H2O,CO2; high - O3,CO2)
INTEGER, PARAMETER :: NGS4=52
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( MAXXSEC,kts:ktep1 ), &
INTENT(IN ) :: WX
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLCO2, &
COLO3, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STRRAT1 = 90.4894
STRRAT2 = 0.900502
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
!!DIR$ NOVECTOR
!cdir novector
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT1*COLCO2(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(5) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(5) + JS
INDS = INDSELF(LAY)
!!DIR$ VECTOR
DO 2000 IG = 1, NG5
TAUG(NGS4+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA5(IND0,IG) + &
FAC100 * ABSA5(IND0+1,IG) + &
FAC010 * ABSA5(IND0+9,IG) + &
FAC110 * ABSA5(IND0+10,IG) + &
FAC001 * ABSA5(IND1,IG) + &
FAC101 * ABSA5(IND1+1,IG) + &
FAC011 * ABSA5(IND1+9,IG) + &
FAC111 * ABSA5(IND1+10,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC5(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC5(INDS+1,IG) - SELFREFC5(INDS,IG))) &
+ WX(1,LAY) * CCL4C5(IG)
PFRAC(NGS4+IG,LAY) = FRACREFAC5(IG,JS) + FS * &
(FRACREFAC5(IG,JS+1) - FRACREFAC5(IG,JS))
2000 CONTINUE
2500 CONTINUE
!!DIR$ NOVECTOR
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
SPECCOMB = COLO3(LAY) + STRRAT2*COLCO2(LAY)
SPECPARM = COLO3(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 4.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(5) + JS
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(5) + JS
!!DIR$ VECTOR
DO 3000 IG = 1, NG5
TAUG(NGS4+IG,LAY) = SPECCOMB * &
(FAC000 * ABSB5(IND0,IG) + &
FAC100 * ABSB5(IND0+1,IG) + &
FAC010 * ABSB5(IND0+5,IG) + &
FAC110 * ABSB5(IND0+6,IG) + &
FAC001 * ABSB5(IND1,IG) + &
FAC101 * ABSB5(IND1+1,IG) + &
FAC011 * ABSB5(IND1+5,IG) + &
FAC111 * ABSB5(IND1+6,IG)) &
+ WX(1,LAY) * CCL4C5(IG)
PFRAC(NGS4+IG,LAY) = FRACREFBC5(IG,JS) + FS * &
(FRACREFBC5(IG,JS+1) - FRACREFBC5(IG,JS))
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB5
!-----------------------------------------------------------------------------
SUBROUTINE TAUGB6(kts,ktep1,COLH2O,CO2MULT,FAC00,FAC01,FAC10,FAC11, & 2,3
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,WX,PFRAC,TAUG, &
LAYTROP )
!-----------------------------------------------------------------------------
! BAND 6: 820-980 cm-1 (low - H2O; high - nothing)
INTEGER, PARAMETER :: NGS5=68
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( MAXXSEC,kts:ktep1 ), &
INTENT(IN ) :: WX
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
CO2MULT, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
! Compute the optical depth by interpolating in ln(pressure) and
! temperature. The water vapor self-continuum is interpolated
! (in temperature) separately.
!cdir novector
DO 2500 LAY = 1, LAYTROP
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(6) + 1
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(6) + 1
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG6
TAUG(NGS5+IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSA6(IND0,IG) + &
FAC10(LAY) * ABSA6(IND0+1,IG) + &
FAC01(LAY) * ABSA6(IND1,IG) + &
FAC11(LAY) * ABSA6(IND1+1,IG) + &
SELFFAC(LAY) * (SELFREFC6(INDS,IG) + &
SELFFRAC(LAY)* &
(SELFREFC6(INDS+1,IG)-SELFREFC6(INDS,IG)))) &
+ WX(2,LAY) * CFC11ADJC6(IG) &
+ WX(3,LAY) * CFC12C6(IG) &
+ CO2MULT(LAY) * ABSCO2C6(IG)
PFRAC(NGS5+IG,LAY) = FRACREFAC6(IG)
2000 CONTINUE
2500 CONTINUE
! Nothing important goes on above LAYTROP in this band.
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
DO 3000 IG = 1, NG6
TAUG(NGS5+IG,LAY) = 0.0 &
+ WX(2,LAY) * CFC11ADJC6(IG) &
+ WX(3,LAY) * CFC12C6(IG)
PFRAC(NGS5+IG,LAY) = FRACREFAC6(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB6
!-----------------------------------------------------------------------------
SUBROUTINE TAUGB7(kts,ktep1,COLH2O,COLO3,CO2MULT,FAC00,FAC01,FAC10, & 2,3
FAC11,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF, &
PFRAC,TAUG,LAYTROP )
!-----------------------------------------------------------------------------
! BAND 7: 980-1080 cm-1 (low - H2O,O3; high - O3)
INTEGER, PARAMETER :: NGS6=76
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLO3, &
CO2MULT, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STRRAT1 = 8.21104E4
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
!!DIR$ NOVECTOR
!cdir novector
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT1*COLO3(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*SPECPARM
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(7) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(7) + JS
INDS = INDSELF(LAY)
!!DIR$ VECTOR
DO 2000 IG = 1, NG7
TAUG(NGS6+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA7(IND0,IG) + &
FAC100 * ABSA7(IND0+1,IG) + &
FAC010 * ABSA7(IND0+9,IG) + &
FAC110 * ABSA7(IND0+10,IG) + &
FAC001 * ABSA7(IND1,IG) + &
FAC101 * ABSA7(IND1+1,IG) + &
FAC011 * ABSA7(IND1+9,IG) + &
FAC111 * ABSA7(IND1+10,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC7(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC7(INDS+1,IG) - SELFREFC7(INDS,IG)))&
+ CO2MULT(LAY) * ABSCO2C7(IG)
PFRAC(NGS6+IG,LAY) = FRACREFAC7(IG,JS) + FS * &
(FRACREFAC7(IG,JS+1) - FRACREFAC7(IG,JS))
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(7) + 1
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(7) + 1
DO 3000 IG = 1, NG7
TAUG(NGS6+IG,LAY) = COLO3(LAY) * &
(FAC00(LAY) * ABSB7(IND0,IG) + &
FAC10(LAY) * ABSB7(IND0+1,IG) + &
FAC01(LAY) * ABSB7(IND1,IG) + &
FAC11(LAY) * ABSB7(IND1+1,IG)) &
+ CO2MULT(LAY) * ABSCO2C7(IG)
PFRAC(NGS6+IG,LAY) = FRACREFBC7(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB7
!----------------------------------------------------------------------------
SUBROUTINE TAUGB8(kts,ktep1,COLH2O,COLO3,COLN2O,CO2MULT, & 2,3
FAC00,FAC01,FAC10,FAC11,SELFFAC,SELFFRAC, &
JP,JT,JT1,INDSELF,WX,PFRAC,TAUG,LAYSWTCH )
!----------------------------------------------------------------------------
! BAND 8: 1080-1180 cm-1 (low (i.e.>~300mb) - H2O; high - O3)
INTEGER, PARAMETER :: NGS7=88
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYSWTCH
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( MAXXSEC,kts:ktep1 ), &
INTENT(IN ) :: WX
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLO3, &
COLN2O, &
CO2MULT, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
DIMENSION H2OREF(59),O3REF(59)
REAL N2OMULT,N2OREF(59)
DATA H2OREF/ &
1.87599E-02,1.22233E-02,5.89086E-03,2.76753E-03,1.40651E-03, &
7.59698E-04,3.88758E-04,1.65422E-04,3.71895E-05,7.47648E-06, &
4.30818E-06,3.33194E-06,3.20393E-06,3.16186E-06,3.25235E-06, &
3.42258E-06,3.62884E-06,3.91482E-06,4.14875E-06,4.30810E-06, &
4.44204E-06,4.57783E-06,4.70865E-06,4.79432E-06,4.86971E-06, &
4.92603E-06,4.96688E-06,4.99628E-06,5.05266E-06,5.12658E-06, &
5.25028E-06,5.35708E-06,5.45085E-06,5.48304E-06,5.50000E-06, &
5.50000E-06,5.45359E-06,5.40468E-06,5.35576E-06,5.25327E-06, &
5.14362E-06,5.03396E-06,4.87662E-06,4.69787E-06,4.51911E-06, &
4.33600E-06,4.14416E-06,3.95232E-06,3.76048E-06,3.57217E-06, &
3.38549E-06,3.19881E-06,3.01212E-06,2.82621E-06,2.64068E-06, &
2.45515E-06,2.26962E-06,2.08659E-06,1.93029E-06/
DATA N2OREF/ &
3.20000E-07,3.20000E-07,3.20000E-07,3.20000E-07,3.20000E-07, &
3.19652E-07,3.15324E-07,3.03830E-07,2.94221E-07,2.84953E-07, &
2.76714E-07,2.64709E-07,2.42847E-07,2.09547E-07,1.71945E-07, &
1.37491E-07,1.13319E-07,1.00354E-07,9.12812E-08,8.54633E-08, &
8.03631E-08,7.33718E-08,6.59754E-08,5.60386E-08,4.70901E-08, &
3.99774E-08,3.29786E-08,2.60642E-08,2.10663E-08,1.65918E-08, &
1.30167E-08,1.00900E-08,7.62490E-09,6.11592E-09,4.66725E-09, &
3.28574E-09,2.84838E-09,2.46198E-09,2.07557E-09,1.85507E-09, &
1.65675E-09,1.45843E-09,1.31948E-09,1.20716E-09,1.09485E-09, &
9.97803E-10,9.31260E-10,8.64721E-10,7.98181E-10,7.51380E-10, &
7.13670E-10,6.75960E-10,6.38250E-10,6.09811E-10,5.85998E-10, &
5.62185E-10,5.38371E-10,5.15183E-10,4.98660E-10/
DATA O3REF/ &
3.01700E-08,3.47254E-08,4.24769E-08,5.27592E-08,6.69439E-08, &
8.71295E-08,1.13911E-07,1.56771E-07,2.17878E-07,3.24430E-07, &
4.65942E-07,5.68057E-07,6.96065E-07,1.11863E-06,1.76175E-06, &
2.32689E-06,2.95769E-06,3.65930E-06,4.59503E-06,5.31891E-06, &
5.96179E-06,6.51133E-06,7.06350E-06,7.69169E-06,8.25771E-06, &
8.70824E-06,8.83245E-06,8.71486E-06,8.09434E-06,7.33071E-06, &
6.31014E-06,5.36717E-06,4.48289E-06,3.83913E-06,3.28270E-06, &
2.82351E-06,2.49061E-06,2.16453E-06,1.83845E-06,1.66182E-06, &
1.50517E-06,1.34852E-06,1.19718E-06,1.04822E-06,8.99264E-07, &
7.63432E-07,6.53806E-07,5.44186E-07,4.34564E-07,3.64210E-07, &
3.11938E-07,2.59667E-07,2.07395E-07,1.91456E-07,1.93639E-07, &
1.95821E-07,1.98004E-07,2.06442E-07,2.81546E-07/
! Compute the optical depth by interpolating in ln(pressure) and
! temperature.
!cdir novector
DO 2500 LAY = 1, LAYSWTCH
FP = FAC01(LAY) + FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(8) + 1
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(8) + 1
INDS = INDSELF(LAY)
COLREF1 = N2OREF(JP(LAY))
COLREF2 = N2OREF(JP(LAY)+1)
WCOMB1 = H2OREF(JP(LAY))
WCOMB2 = H2OREF(JP(LAY)+1)
RATIO = (COLREF1/WCOMB1)+FP*((COLREF2/WCOMB2)-(COLREF1/WCOMB1))
CURRN2O = COLH2O(LAY) * RATIO
N2OMULT = COLN2O(LAY) - CURRN2O
DO 2000 IG = 1, NG8
TAUG(NGS7+IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSA8(IND0,IG) + &
FAC10(LAY) * ABSA8(IND0+1,IG) + &
FAC01(LAY) * ABSA8(IND1,IG) + &
FAC11(LAY) * ABSA8(IND1+1,IG) + &
SELFFAC(LAY) * (SELFREFC8(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC8(INDS+1,IG) - SELFREFC8(INDS,IG))))&
+ WX(3,LAY) * CFC12C8(IG) &
+ WX(4,LAY) * CFC22ADJC8(IG) &
+ CO2MULT(LAY) * ABSCO2AC8(IG) &
+ N2OMULT * ABSN2OAC8(IG)
PFRAC(NGS7+IG,LAY) = FRACREFAC8(IG)
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYSWTCH+1, NLAYERS
FP = FAC01(LAY) + FAC11(LAY)
IND0 = ((JP(LAY)-7)*5+(JT(LAY)-1))*NSPB(8) + 1
IND1 = ((JP(LAY)-6)*5+(JT1(LAY)-1))*NSPB(8) + 1
COLREF1 = N2OREF(JP(LAY))
COLREF2 = N2OREF(JP(LAY)+1)
WCOMB1 = O3REF(JP(LAY))
WCOMB2 = O3REF(JP(LAY)+1)
RATIO = (COLREF1/WCOMB1)+FP*((COLREF2/WCOMB2)-(COLREF1/WCOMB1))
CURRN2O = COLO3(LAY) * RATIO
N2OMULT = COLN2O(LAY) - CURRN2O
DO 3000 IG = 1, NG8
TAUG(NGS7+IG,LAY) = COLO3(LAY) * &
(FAC00(LAY) * ABSB8(IND0,IG) + &
FAC10(LAY) * ABSB8(IND0+1,IG) + &
FAC01(LAY) * ABSB8(IND1,IG) + &
FAC11(LAY) * ABSB8(IND1+1,IG)) &
+ WX(3,LAY) * CFC12C8(IG) &
+ WX(4,LAY) * CFC22ADJC8(IG) &
+ CO2MULT(LAY) * ABSCO2BC8(IG) &
+ N2OMULT * ABSN2OBC8(IG)
PFRAC(NGS7+IG,LAY) = FRACREFBC8(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB8
!-----------------------------------------------------------------------------
SUBROUTINE TAUGB9(kts,ktep1,COLH2O,COLN2O,COLCH4,FAC00,FAC01,FAC10, & 2,3
FAC11,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF, &
PFRAC,TAUG,LAYTROP,LAYSWTCH,LAYLOW )
!-----------------------------------------------------------------------------
! BAND 9: 1180-1390 cm-1 (low - H2O,CH4; high - CH4)
INTEGER, PARAMETER :: NGS8=96
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP,LAYSWTCH,LAYLOW
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLN2O, &
COLCH4, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
DIMENSION H2OREF(13),CH4REF(13),ETAREF(11)
REAL N2OMULT,N2OREF(13)
DATA N2OREF/ &
3.20000E-07,3.20000E-07,3.20000E-07,3.20000E-07,3.20000E-07, &
3.19652E-07,3.15324E-07,3.03830E-07,2.94221E-07,2.84953E-07, &
2.76714E-07,2.64709E-07,2.42847E-07/
DATA H2OREF/ &
1.8759999E-02, 1.2223309E-02, 5.8908667E-03, 2.7675382E-03, &
1.4065107E-03, 7.5969833E-04, 3.8875898E-04, 1.6542293E-04, &
3.7189537E-05, 7.4764857E-06, 4.3081886E-06, 3.3319423E-06, &
3.2039343E-06/
DATA CH4REF/ &
1.7000001E-06, 1.7000001E-06, 1.6998713E-06, 1.6904165E-06, &
1.6671424E-06, 1.6350652E-06, 1.6097551E-06, 1.5590465E-06, &
1.5119849E-06, 1.4741138E-06, 1.4384609E-06, 1.4002215E-06, &
1.3573376E-06/
DATA ETAREF/ &
0.,0.125,0.25,0.375,0.5,0.625,0.75,0.875,0.96,0.99,1.0/
STRRAT = 21.6282
IOFF = 0
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
!cdir novector
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT*COLCH4(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
JFRAC = JS
FS = MOD(SPECMULT,1.0)
FFRAC = FS
IF (JS .EQ. 8) THEN
IF (FS .LE. 0.68) THEN
FS = FS/0.68
ELSEIF (FS .LE. 0.92) THEN
JS = JS + 1
FS = (FS-0.68)/0.24
ELSE
JS = JS + 2
FS = (FS-0.92)/0.08
ENDIF
ELSEIF (JS .EQ.9) THEN
JS = 10
FS = 1.
JFRAC = 8
FFRAC = 1.
ENDIF
FP = FAC01(LAY) + FAC11(LAY)
NS = JS + INT(FS + 0.5)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(9) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(9) + JS
INDS = INDSELF(LAY)
IF (LAY .EQ. LAYLOW) IOFF = NG9
IF (LAY .EQ. LAYSWTCH) IOFF = 2*NG9
COLREF1 = N2OREF(JP(LAY))
COLREF2 = N2OREF(JP(LAY)+1)
IF (NS .EQ. 11) THEN
WCOMB1 = H2OREF(JP(LAY))
WCOMB2 = H2OREF(JP(LAY)+1)
ELSE
WCOMB1 = STRRAT * CH4REF(JP(LAY))/(1.-ETAREF(NS))
WCOMB2 = STRRAT * CH4REF(JP(LAY)+1)/(1.-ETAREF(NS))
ENDIF
RATIO = (COLREF1/WCOMB1)+FP*((COLREF2/WCOMB2)-(COLREF1/WCOMB1))
CURRN2O = SPECCOMB * RATIO
N2OMULT = COLN2O(LAY) - CURRN2O
DO 2000 IG = 1, NG9
TAUG(NGS8+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA9(IND0,IG) + &
FAC100 * ABSA9(IND0+1,IG) + &
FAC010 * ABSA9(IND0+11,IG) + &
FAC110 * ABSA9(IND0+12,IG) + &
FAC001 * ABSA9(IND1,IG) + &
FAC101 * ABSA9(IND1+1,IG) + &
FAC011 * ABSA9(IND1+11,IG) + &
FAC111 * ABSA9(IND1+12,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC9(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC9(INDS+1,IG) - SELFREFC9(INDS,IG))) &
+ N2OMULT * ABSN2OC9(IG+IOFF)
PFRAC(NGS8+IG,LAY) = FRACREFAC9(IG,JFRAC) + FFRAC * &
(FRACREFAC9(IG,JFRAC+1) - FRACREFAC9(IG,JFRAC))
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(9) + 1
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(9) + 1
DO 3000 IG = 1, NG9
TAUG(NGS8+IG,LAY) = COLCH4(LAY) * &
(FAC00(LAY) * ABSB9(IND0,IG) + &
FAC10(LAY) * ABSB9(IND0+1,IG) + &
FAC01(LAY) * ABSB9(IND1,IG) + &
FAC11(LAY) * ABSB9(IND1+1,IG))
PFRAC(NGS8+IG,LAY) = FRACREFBC9(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB9
!--------------------------------------------------------------------------------
SUBROUTINE TAUGB10(kts,ktep1,COLH2O,FAC00,FAC01,FAC10,FAC11,JP,JT,JT1, & 2,2
PFRAC,TAUG,LAYTROP )
!--------------------------------------------------------------------------------
! BAND 10: 1390-1480 cm-1 (low - H2O; high - H2O)
INTEGER, PARAMETER :: NGS9=108
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
FAC00, &
FAC01, &
FAC10, &
FAC11
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
! Compute the optical depth by interpolating in ln(pressure) and
! temperature.
!cdir novector
DO 2500 LAY = 1, LAYTROP
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(10) + 1
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(10) + 1
DO 2000 IG = 1, NG10
TAUG(NGS9+IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSA10(IND0,IG) + &
FAC10(LAY) * ABSA10(IND0+1,IG) + &
FAC01(LAY) * ABSA10(IND1,IG) + &
FAC11(LAY) * ABSA10(IND1+1,IG))
PFRAC(NGS9+IG,LAY) = FRACREFAC10(IG)
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(10) + 1
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(10) + 1
DO 3000 IG = 1, NG10
TAUG(NGS9+IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSB10(IND0,IG) + &
FAC10(LAY) * ABSB10(IND0+1,IG) + &
FAC01(LAY) * ABSB10(IND1,IG) + &
FAC11(LAY) * ABSB10(IND1+1,IG))
PFRAC(NGS9+IG,LAY) = FRACREFBC10(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB10
!--------------------------------------------------------------------------
SUBROUTINE TAUGB11(kts,ktep1,COLH2O,FAC00,FAC01,FAC10,FAC11, & 2,2
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP )
!--------------------------------------------------------------------------
! BAND 11: 1480-1800 cm-1 (low - H2O; high - H2O)
INTEGER, PARAMETER :: NGS10=114
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
! Compute the optical depth by interpolating in ln(pressure) and
! temperature. Below LAYTROP, the water vapor self-continuum
! is interpolated (in temperature) separately.
!cdir novector
DO 2500 LAY = 1, LAYTROP
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(11) + 1
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(11) + 1
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG11
TAUG(NGS10+IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSA11(IND0,IG) + &
FAC10(LAY) * ABSA11(IND0+1,IG) + &
FAC01(LAY) * ABSA11(IND1,IG) + &
FAC11(LAY) * ABSA11(IND1+1,IG) + &
SELFFAC(LAY) * (SELFREFC11(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC11(INDS+1,IG) - SELFREFC11(INDS,IG))))
PFRAC(NGS10+IG,LAY) = FRACREFAC11(IG)
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(11) + 1
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(11) + 1
DO 3000 IG = 1, NG11
TAUG(NGS10+IG,LAY) = COLH2O(LAY) * &
(FAC00(LAY) * ABSB11(IND0,IG) + &
FAC10(LAY) * ABSB11(IND0+1,IG) + &
FAC01(LAY) * ABSB11(IND1,IG) + &
FAC11(LAY) * ABSB11(IND1+1,IG))
PFRAC(NGS10+IG,LAY) = FRACREFBC11(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB11
!-----------------------------------------------------------------------------
SUBROUTINE TAUGB12(kts,ktep1,COLH2O,COLCO2,FAC00,FAC01,FAC10,FAC11, & 2,3
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP )
!-----------------------------------------------------------------------------
! BAND 12: 1800-2080 cm-1 (low - H2O,CO2; high - nothing)
INTEGER, PARAMETER :: NGS11=122
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLCO2, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STRRAT1 = 0.009736757
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
!!DIR$ NOVECTOR
!cdir novector
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT1*COLCO2(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(12) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(12) + JS
INDS = INDSELF(LAY)
!!DIR$ VECTOR
DO 2000 IG = 1, NG12
TAUG(NGS11+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA12(IND0,IG) + &
FAC100 * ABSA12(IND0+1,IG) + &
FAC010 * ABSA12(IND0+9,IG) + &
FAC110 * ABSA12(IND0+10,IG) + &
FAC001 * ABSA12(IND1,IG) + &
FAC101 * ABSA12(IND1+1,IG) + &
FAC011 * ABSA12(IND1+9,IG) + &
FAC111 * ABSA12(IND1+10,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC12(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC12(INDS+1,IG) - SELFREFC12(INDS,IG)))
PFRAC(NGS11+IG,LAY) = FRACREFAC12(IG,JS) + FS * &
(FRACREFAC12(IG,JS+1) - FRACREFAC12(IG,JS))
2000 CONTINUE
2500 CONTINUE
!cdir novector
DO 3500 LAY = LAYTROP+1, NLAYERS
DO 3000 IG = 1, NG12
TAUG(NGS11+IG,LAY) = 0.0
PFRAC(NGS11+IG,LAY) = 0.0
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB12
!-----------------------------------------------------------------------------
SUBROUTINE TAUGB13(kts,ktep1,COLH2O,COLN2O,FAC00,FAC01,FAC10,FAC11, & 2,3
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP )
!-----------------------------------------------------------------------------
! BAND 13: 2080-2250 cm-1 (low - H2O,N2O; high - nothing)
INTEGER, PARAMETER :: NGS12=130
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLN2O, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STRRAT1 = 16658.87
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT1*COLN2O(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(13) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(13) + JS
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG13
TAUG(NGS12+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA13(IND0,IG) + &
FAC100 * ABSA13(IND0+1,IG) + &
FAC010 * ABSA13(IND0+9,IG) + &
FAC110 * ABSA13(IND0+10,IG) + &
FAC001 * ABSA13(IND1,IG) + &
FAC101 * ABSA13(IND1+1,IG) + &
FAC011 * ABSA13(IND1+9,IG) + &
FAC111 * ABSA13(IND1+10,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC13(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC13(INDS+1,IG) - SELFREFC13(INDS,IG)))
PFRAC(NGS12+IG,LAY) = FRACREFAC13(IG,JS) + FS * &
(FRACREFAC13(IG,JS+1) - FRACREFAC13(IG,JS))
2000 CONTINUE
2500 CONTINUE
DO 3500 LAY = LAYTROP+1, NLAYERS
DO 3000 IG = 1, NG13
TAUG(NGS12+IG,LAY) = 0.0
PFRAC(NGS12+IG,LAY) = 0.0
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB13
!----------------------------------------------------------------------------
SUBROUTINE TAUGB14(kts,ktep1,COLCO2,FAC00,FAC01,FAC10,FAC11, & 2,2
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP )
!----------------------------------------------------------------------------
! BAND 14: 2250-2380 cm-1 (low - CO2; high - CO2)
INTEGER, PARAMETER :: NGS13=134
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLCO2, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
! Compute the optical depth by interpolating in ln(pressure) and
! temperature. Below LAYTROP, the water vapor self-continuum
! is interpolated (in temperature) separately.
DO 2500 LAY = 1, LAYTROP
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(14) + 1
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(14) + 1
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG14
TAUG(NGS13+IG,LAY) = COLCO2(LAY) * &
(FAC00(LAY) * ABSA14(IND0,IG) + &
FAC10(LAY) * ABSA14(IND0+1,IG) + &
FAC01(LAY) * ABSA14(IND1,IG) + &
FAC11(LAY) * ABSA14(IND1+1,IG) + &
SELFFAC(LAY) * (SELFREFC14(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC14(INDS+1,IG) - SELFREFC14(INDS,IG))))
PFRAC(NGS13+IG,LAY) = FRACREFAC14(IG)
2000 CONTINUE
2500 CONTINUE
DO 3500 LAY = LAYTROP+1, NLAYERS
IND0 = ((JP(LAY)-13)*5+(JT(LAY)-1))*NSPB(14) + 1
IND1 = ((JP(LAY)-12)*5+(JT1(LAY)-1))*NSPB(14) + 1
DO 3000 IG = 1, NG14
TAUG(NGS13+IG,LAY) = COLCO2(LAY) * &
(FAC00(LAY) * ABSB14(IND0,IG) + &
FAC10(LAY) * ABSB14(IND0+1,IG) + &
FAC01(LAY) * ABSB14(IND1,IG) + &
FAC11(LAY) * ABSB14(IND1+1,IG))
PFRAC(NGS13+IG,LAY) = FRACREFBC14(IG)
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB14
!------------------------------------------------------------------------------
SUBROUTINE TAUGB15(kts,ktep1,COLH2O,COLCO2,COLN2O,FAC00,FAC01,FAC10, & 2,3
FAC11,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF, &
PFRAC,TAUG,LAYTROP )
!------------------------------------------------------------------------------
! BAND 15: 2380-2600 cm-1 (low - N2O,CO2; high - nothing)
INTEGER, PARAMETER :: NGS14=136
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLCO2, &
COLN2O, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STRRAT1 = 0.2883201
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLN2O(LAY) + STRRAT1*COLCO2(LAY)
SPECPARM = COLN2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(15) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(15) + JS
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG15
TAUG(NGS14+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA15(IND0,IG) + &
FAC100 * ABSA15(IND0+1,IG) + &
FAC010 * ABSA15(IND0+9,IG) + &
FAC110 * ABSA15(IND0+10,IG) + &
FAC001 * ABSA15(IND1,IG) + &
FAC101 * ABSA15(IND1+1,IG) + &
FAC011 * ABSA15(IND1+9,IG) + &
FAC111 * ABSA15(IND1+10,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC15(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC15(INDS+1,IG) - SELFREFC15(INDS,IG)))
PFRAC(NGS14+IG,LAY) = FRACREFAC15(IG,JS) + FS * &
(FRACREFAC15(IG,JS+1) - FRACREFAC15(IG,JS))
2000 CONTINUE
2500 CONTINUE
DO 3500 LAY = LAYTROP+1, NLAYERS
DO 3000 IG = 1, NG15
TAUG(NGS14+IG,LAY) = 0.0
PFRAC(NGS14+IG,LAY) = 0.0
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB15
!-----------------------------------------------------------------------------
SUBROUTINE TAUGB16(kts,ktep1,COLH2O,COLCH4,FAC00,FAC01,FAC10,FAC11, & 2,3
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP )
!-----------------------------------------------------------------------------
! BAND 16: 2600-3000 cm-1 (low - H2O,CH4; high - nothing)
INTEGER, PARAMETER :: NGS15=138
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC, &
TAUG
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLH2O, &
COLCH4, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
JP, &
JT, &
JT1, &
INDSELF
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
STRRAT1 = 830.411
! Compute the optical depth by interpolating in ln(pressure),
! temperature, and appropriate species. Below LAYTROP, the water
! vapor self-continuum is interpolated (in temperature) separately.
DO 2500 LAY = 1, LAYTROP
SPECCOMB = COLH2O(LAY) + STRRAT1*COLCH4(LAY)
SPECPARM = COLH2O(LAY)/SPECCOMB
IF (SPECPARM .GE. ONEMINUS) SPECPARM = ONEMINUS
SPECMULT = 8.*(SPECPARM)
JS = 1 + INT(SPECMULT)
FS = MOD(SPECMULT,1.0)
FAC000 = (1. - FS) * FAC00(LAY)
FAC010 = (1. - FS) * FAC10(LAY)
FAC100 = FS * FAC00(LAY)
FAC110 = FS * FAC10(LAY)
FAC001 = (1. - FS) * FAC01(LAY)
FAC011 = (1. - FS) * FAC11(LAY)
FAC101 = FS * FAC01(LAY)
FAC111 = FS * FAC11(LAY)
IND0 = ((JP(LAY)-1)*5+(JT(LAY)-1))*NSPA(16) + JS
IND1 = (JP(LAY)*5+(JT1(LAY)-1))*NSPA(16) + JS
INDS = INDSELF(LAY)
DO 2000 IG = 1, NG16
TAUG(NGS15+IG,LAY) = SPECCOMB * &
(FAC000 * ABSA16(IND0,IG) + &
FAC100 * ABSA16(IND0+1,IG) + &
FAC010 * ABSA16(IND0+9,IG) + &
FAC110 * ABSA16(IND0+10,IG) + &
FAC001 * ABSA16(IND1,IG) + &
FAC101 * ABSA16(IND1+1,IG) + &
FAC011 * ABSA16(IND1+9,IG) + &
FAC111 * ABSA16(IND1+10,IG)) + &
COLH2O(LAY) * &
SELFFAC(LAY) * (SELFREFC16(INDS,IG) + &
SELFFRAC(LAY) * &
(SELFREFC16(INDS+1,IG) - SELFREFC16(INDS,IG)))
PFRAC(NGS15+IG,LAY) = FRACREFAC16(IG,JS) + FS * &
(FRACREFAC16(IG,JS+1) - FRACREFAC16(IG,JS))
2000 CONTINUE
2500 CONTINUE
DO 3500 LAY = LAYTROP+1, NLAYERS
DO 3000 IG = 1, NG16
TAUG(NGS15+IG,LAY) = 0.0
PFRAC(NGS15+IG,LAY) = 0.0
3000 CONTINUE
3500 CONTINUE
END SUBROUTINE TAUGB16
!-------------------------------------------------------------------------
SUBROUTINE RTRN(kts,ktep1, & 1
TAVEL, PZ, TZ, CLDFRAC, TAUCLOUD, TOTDFLUX, &
TOTUFLUX, HTR, ICLDLYR, ITR, PFRAC, TBOUND,SEMISS )
!-------------------------------------------------------------------------
! RRTM Longwave Radiative Transfer Model
! Atmospheric and Environmental Research, Inc., Cambridge, MA
!
! Original version: E. J. Mlawer, et al.
! Revision for NCAR CCM: Michael J. Iacono; September, 1998
!
! This program calculates the upward fluxes, downward fluxes, and
! heating rates for an arbitrary clear or cloudy atmosphere. The input
! to this program is the atmospheric profile, all Planck function
! information, and the cloud fraction by layer. The diffusivity angle
! (SECANG=1.66) is used for the angle integration for consistency with
! the NCAR CCM; the Gaussian weight appropriate to this angle (WTNUM=0.5)
! is applied here. Note that use of the emissivity angle for the flux
! integration can cause errors of 1 to 4 W/m2 within cloudy layers.
!-------------------------------------------------------------------------
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(IN ) :: ITR
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(IN ) :: PFRAC
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
TAVEL
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
CLDFRAC, &
TAUCLOUD
REAL, DIMENSION( 0:ktep1 ),INTENT(INOUT):: &
TOTDFLUX, &
TOTUFLUX
REAL, DIMENSION( 0:ktep1 ), INTENT(INOUT) :: &
HTR
REAL, DIMENSION( 0:ktep1 ), INTENT(IN ) :: &
PZ, &
TZ
INTEGER, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
ICLDLYR
REAL, INTENT(IN ) :: TBOUND
REAL, DIMENSION(NBANDS), INTENT(IN ) :: SEMISS
! LOCAL VAR
REAL, DIMENSION( 0:ktep1 ) :: &
TOTUCLFL, &
TOTDCLFL
REAL, DIMENSION( 0:ktep1 ) :: &
FNET, &
FNETC, &
HTRC
INTEGER :: kk
REAL :: CLRNTTOA,CLRNTSRF
! Parameters
! INTEGER, PARAMETER :: MXLAY=101
REAL, PARAMETER :: SECANG=1.66
REAL, PARAMETER :: WTNUM=0.5
! RRTM Definitions
! Input
! MXLAY ! Maximum number of model layers
! NGPT ! Total number of g-point subintervals
! NBANDS ! Number of longwave spectral bands
! SECANG ! Diffusivity angle
! WTNUM ! Weight for radiance to flux conversion
! NLAYERS ! Number of model layers (plev+1)
! PAVEL(MXLAY) ! Layer pressures (mb)
! PZ(0:MXLAY) ! Level (interface) pressures (mb)
! TAVEL(MXLAY) ! Layer temperatures (K)
! TZ(0:MXLAY) ! Level (interface) temperatures(mb)
! TBOUND ! Surface temperature (K)
! CLDFRAC(MXLAY) ! Layer cloud fraction
! TAUCLOUD(MXLAY) ! Layer cloud optical depth
! ITR(NGPT,MXLAY) ! Integer look-up table index
! PFRAC(NGPT,MXLAY) ! Planck fractions
! ICLDLYR(MXLAY) ! Flag for cloudy layers
! ICLD ! Flag for cloudy in column
! SEMISS(NBANDS) ! Surface emissivities for each band
! BPADE ! Pade constant
! TAU ! Clear sky optical depth look-up table
! TF ! Tau transition function look-up table
! TRANS ! Clear sky transmittance look-up table
! Local
! ABSS(NGPT*MXLAY) ! Gaseous absorptivity
! ABSCLD(MXLAY) ! Cloud absorptivity
! ATOT(NGPT*MXLAY) ! Combined gaseous and cloud absorptivity
! ODCLR(NGPT,MXLAY) ! Clear sky (gaseous) optical depth
! ODCLD(MXLAY) ! Cloud optical depth
! EFCLFRAC(MXLAY) ! Effective cloud fraction
! RADLU(NGPT) ! Upward radiance
! URAD ! Spectrally summed upward radiance
! RADCLRU(NGPT) ! Clear sky upward radiance
! CLRURAD ! Spectrally summed clear sky upward radiance
! RADLD(NGPT) ! Downward radiance
! DRAD ! Spectrally summed downward radiance
! RADCLRD(NGPT) ! Clear sky downward radiance
! CLRDRAD ! Spectrally summed clear sky downward radianc
! Output
! TOTUFLUX(0:MXLAY) ! Upward longwave flux (W/m2)
! TOTDFLUX(0:MXLAY) ! Downward longwave flux (W/m2)
! FNET(0:MXLAY) ! Net longwave flux (W/m2)
! HTR(0:MXLAY) ! Longwave heating rate (K/day)
! CLRNTTOA ! Clear sky TOA outgoing flux (W/m2)
! CLRNTSFC ! Clear sky net surface flux (W/m2)
! TOTUCLFL(0:MXLAY) ! Clear sky upward longwave flux (W/m2)
! TOTDCLFL(0:MXLAY) ! Clear sky downward longwave flux (W/m2)
! FNETC(0:MXLAY) ! Clear sky net longwave flux (W/m2)
! HTRC(0:MXLAY) ! Clear sky longwave heating rate (K/day)
!
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
DIMENSION BBU(NGPT*(ktep1-kts+1)),BBUTOT(NGPT*(ktep1-kts)),BGLEV(NGPT)
DIMENSION PLANKBND(NBANDS),PLNKEMIT(NBANDS)
DIMENSION PLVL(NBANDS,0:ktep1),PLAY(NBANDS,kts:ktep1)
DIMENSION INDLAY(kts:ktep1),INDLEV(0:ktep1)
DIMENSION TLAYFRAC(kts:ktep1),TLEVFRAC(0:ktep1)
DIMENSION ABSS(NGPT*(ktep1-kts+1)),ABSCLD(kts:ktep1-1),ATOT(NGPT*(ktep1-kts))
DIMENSION ODCLR(NGPT,kts:ktep1-1),ODCLD(kts:ktep1-1),EFCLFRAC(kts:ktep1-1)
DIMENSION RADLU(NGPT),RADLD(NGPT)
DIMENSION RADCLRU(NGPT),RADCLRD(NGPT)
DIMENSION SEMIS(NGPT),RADUEMIT(NGPT)
INDBOUND = TBOUND - 159.
TBNDFRAC = TBOUND - INT(TBOUND)
DO 200 LAY = 0, NLAYERS
TOTUFLUX(LAY) = 0.0
TOTDFLUX(LAY) = 0.0
TOTUCLFL(LAY) = 0.0
TOTDCLFL(LAY) = 0.0
INDLEV(LAY) = TZ(LAY) - 159.
TLEVFRAC(LAY) = TZ(LAY) - INT(TZ(LAY))
200 CONTINUE
DO 220 LEV = 1, NLAYERS
IF (ICLDLYR(LEV).EQ.1) THEN
INDLAY(LEV) = TAVEL(LEV) - 159.
TLAYFRAC(LEV) = TAVEL(LEV) - INT(TAVEL(LEV))
! Cloudy sky optical depth and absorptivity.
ODCLD(LEV) = SECANG * TAUCLOUD(LEV)
TRANSCLD = EXP(-ODCLD(LEV))
ABSCLD(LEV) = 1. - TRANSCLD
EFCLFRAC(LEV) = ABSCLD(LEV) * CLDFRAC(LEV)
! Get clear sky optical depth from TAU lookup table
DO 250 IPR = 1, NGPT
IND = ITR(IPR,LEV)
ODCLR(IPR,LEV) = TAU(IND)
250 CONTINUE
ELSE
INDLAY(LEV) = TAVEL(LEV) - 159.
TLAYFRAC(LEV) = TAVEL(LEV) - INT(TAVEL(LEV))
ENDIF
220 CONTINUE
! SUMPL = 0.0
! SUMPLEM = 0.0
! *** Loop over frequency bands.
DO 600 IBAND = 1, NBANDS
DBDTLEV = TOTPLNK(INDBOUND+1,IBAND)-TOTPLNK(INDBOUND,IBAND)
PLANKBND(IBAND) = DELWAVE(IBAND) * (TOTPLNK(INDBOUND,IBAND) + &
TBNDFRAC * DBDTLEV)
DBDTLEV = TOTPLNK(INDLEV(0)+1,IBAND) - &
TOTPLNK(INDLEV(0),IBAND)
PLVL(IBAND,0) = DELWAVE(IBAND) * (TOTPLNK(INDLEV(0),IBAND) + &
TLEVFRAC(0)*DBDTLEV)
PLNKEMIT(IBAND) = SEMISS(IBAND) * PLANKBND(IBAND)
! SUMPLEM = SUMPLEM + PLNKEMIT(IBAND)
! SUMPL = SUMPL + PLANKBND(IBAND)
DO 300 LEV = 1, NLAYERS
! Calculate the integrated Planck functions at the level and
! layer temperatures.
DBDTLEV = TOTPLNK(INDLEV(LEV)+1,IBAND) - &
TOTPLNK(INDLEV(LEV),IBAND)
DBDTLAY = TOTPLNK(INDLAY(LEV)+1,IBAND) - &
TOTPLNK(INDLAY(LEV),IBAND)
PLAY(IBAND,LEV) = DELWAVE(IBAND) * &
(TOTPLNK(INDLAY(LEV),IBAND) + TLAYFRAC(LEV) * DBDTLAY)
PLVL(IBAND,LEV) = DELWAVE(IBAND) * &
(TOTPLNK(INDLEV(LEV),IBAND) + TLEVFRAC(LEV) * DBDTLEV)
300 CONTINUE
600 CONTINUE
! SEMISLW = SUMPLEM / SUMPL
! *** Initialize for radiative transfer.
DO 500 IPR = 1, NGPT
RADCLRD(IPR) = 0.
RADLD(IPR) = 0.
SEMIS(IPR) = SEMISS(NGB(IPR))
RADUEMIT(IPR) = PFRAC(IPR,1) * PLNKEMIT(NGB(IPR))
BGLEV(IPR) = PFRAC(IPR,NLAYERS) * PLVL(NGB(IPR),NLAYERS)
500 CONTINUE
! *** DOWNWARD RADIATIVE TRANSFER
! *** DRAD holds summed radiance for total sky stream
! *** CLRDRAD holds summed radiance for clear sky stream
ICLDDN = 0
DO 3000 LEV = NLAYERS, 1, -1
DRAD = 0.0
CLRDRAD = 0.0
IF (ICLDLYR(LEV).EQ.1) THEN
! *** Cloudy layer
ICLDDN = 1
IENT = NGPT * (LEV-1)
DO 2000 IPR = 1, NGPT
INDEX = IENT + IPR
! Get lookup table index
IND = ITR(IPR,LEV)
! Add clear sky and cloud optical depths
ODSM = ODCLR(IPR,LEV) + ODCLD(LEV)
FACTOT = ODSM / (BPADE + ODSM)
BGLAY = PFRAC(IPR,LEV) * PLAY(NGB(IPR),LEV)
DELBGUP = BGLEV(IPR) - BGLAY
! Get TF from lookup table
TAUF = TF(IND)
BBU(INDEX) = BGLAY + TAUF * DELBGUP
BBUTOT(INDEX) = BGLAY + FACTOT * DELBGUP
BGLEV(IPR) = PFRAC(IPR,LEV) * PLVL(NGB(IPR),LEV-1)
DELBGDN = BGLEV(IPR) - BGLAY
BBD = BGLAY + TAUF * DELBGDN
BBDLEVD = BGLAY + FACTOT * DELBGDN
! Get clear sky transmittance from lookup table
ABSS(INDEX) = 1. - TRANS(IND)
ATOT(INDEX) = ABSS(INDEX) + ABSCLD(LEV) - &
ABSS(INDEX) * ABSCLD(LEV)
GASSRC = BBD * ABSS(INDEX)
! Total sky radiance
RADLD(IPR) = RADLD(IPR) - RADLD(IPR) * (ABSS(INDEX) + &
EFCLFRAC(LEV) * (1.-ABSS(INDEX))) + GASSRC + &
CLDFRAC(LEV) * (BBDLEVD * ATOT(INDEX) - GASSRC)
DRAD = DRAD + RADLD(IPR)
! Clear sky radiance
RADCLRD(IPR) = RADCLRD(IPR) + (BBD - RADCLRD(IPR)) &
* ABSS(INDEX)
CLRDRAD = CLRDRAD + RADCLRD(IPR)
2000 CONTINUE
ELSE
! *** Clear layer
IENT = NGPT * (LEV-1)
!DEC$ IVDEP
DO 2100 IPR = 1, NGPT
INDEX = IENT + IPR
IND = ITR(IPR,LEV)
BGLAY = PFRAC(IPR,LEV) * PLAY(NGB(IPR),LEV)
DELBGUP = BGLEV(IPR) - BGLAY
! Get TF from lookup table
TAUF = TF(IND)
BBU(INDEX) = BGLAY + TAUF * DELBGUP
BGLEV(IPR) = PFRAC(IPR,LEV) * PLVL(NGB(IPR),LEV-1)
DELBGDN = BGLEV(IPR) - BGLAY
BBD = BGLAY + TAUF * DELBGDN
! Get clear sky transmittance from lookup table
ABSS(INDEX) = 1. - TRANS(IND)
! Total sky radiance
RADLD(IPR) = RADLD(IPR) + (BBD - RADLD(IPR)) * &
ABSS(INDEX)
DRAD = DRAD + RADLD(IPR)
2100 CONTINUE
! Set clear sky stream to total sky stream as long as layers
! remain clear. Streams diverge when a cloud is reached.
IF (ICLDDN.EQ.1) THEN
DO 2200 IPR = 1, NGPT
RADCLRD(IPR) = RADCLRD(IPR) + (BBD - RADCLRD(IPR)) * &
ABSS(INDEX)
CLRDRAD = CLRDRAD + RADCLRD(IPR)
2200 CONTINUE
ELSE
DO 2300 IPR = 1, NGPT
RADCLRD(IPR) = RADLD(IPR)
CLRDRAD = DRAD
2300 CONTINUE
ENDIF
! 2100 CONTINUE
ENDIF
TOTDFLUX(LEV-1) = DRAD * WTNUM
TOTDCLFL(LEV-1) = CLRDRAD * WTNUM
3000 CONTINUE
! SPECTRAL EMISSIVITY & REFLECTANCE
! Include the contribution of spectrally varying longwave emissivity and
! reflection from the surface to the upward radiative transfer.
! Note: Spectral and Lambertian reflection are identical for the one angle
! flux integration used here.
URAD = 0.0
CLRURAD = 0.0
DO 3500 IPR = 1, NGPT
! Total sky radiance
RADLU(IPR) = RADUEMIT(IPR) + (1. - SEMIS(IPR)) * RADLD(IPR)
URAD = URAD + RADLU(IPR)
! Clear sky radiance
RADCLRU(IPR) = RADUEMIT(IPR) + (1. - SEMIS(IPR)) &
* RADCLRD(IPR)
CLRURAD = CLRURAD + RADCLRU(IPR)
3500 CONTINUE
TOTUFLUX(0) = URAD * WTNUM
TOTUCLFL(0) = CLRURAD * WTNUM
! *** UPWARD RADIATIVE TRANSFER
! *** URAD holds the summed radiance for total sky stream
! *** CLRURAD holds the summed radiance for clear sky stream
DO 5000 LEV = 1, NLAYERS
URAD = 0.0
CLRURAD = 0.0
! Check flag for cloud in current layer
IF (ICLDLYR(LEV).EQ.1) THEN
! *** Cloudy layers
IENT = NGPT * (LEV-1)
DO 4000 IPR = 1, NGPT
INDEX = IENT + IPR
GASSRC = BBU(INDEX) * ABSS(INDEX)
! Total sky radiance
RADLU(IPR) = RADLU(IPR) - RADLU(IPR) * (ABSS(INDEX) + &
EFCLFRAC(LEV) * (1.-ABSS(INDEX))) + GASSRC + &
CLDFRAC(LEV) * (BBUTOT(INDEX) * ATOT(INDEX) - GASSRC)
URAD = URAD + RADLU(IPR)
! Clear sky radiance
RADCLRU(IPR) = RADCLRU(IPR) + (BBU(INDEX) - RADCLRU(IPR)) * &
ABSS(INDEX)
CLRURAD = CLRURAD + RADCLRU(IPR)
4000 CONTINUE
ELSE
! *** Clear layer
IENT = NGPT * (LEV-1)
DO 4100 IPR = 1, NGPT
INDEX = IENT + IPR
! Total sky radiance
RADLU(IPR) = RADLU(IPR) + (BBU(INDEX)-RADLU(IPR)) * &
ABSS(INDEX)
URAD = URAD + RADLU(IPR)
! Clear sky radiance
! Upward clear and total sky streams must remain separate because surface
! reflectance is different for each.
RADCLRU(IPR) = RADCLRU(IPR) + (BBU(INDEX) - RADCLRU(IPR)) &
* ABSS(INDEX)
CLRURAD = CLRURAD + RADCLRU(IPR)
4100 CONTINUE
ENDIF
TOTUFLUX(LEV) = URAD * WTNUM
TOTUCLFL(LEV) = CLRURAD * WTNUM
5000 CONTINUE
! *** Convert radiances to fluxes and heating rates for total sky. Calculates
! clear sky surface and TOA values. To compute clear sky profiles, uncommen
! relevant lines below.
TOTUFLUX(0) = TOTUFLUX(0) * FLUXFAC
TOTDFLUX(0) = TOTDFLUX(0) * FLUXFAC
FNET(0) = TOTUFLUX(0) - TOTDFLUX(0)
TOTUCLFL(0) = TOTUCLFL(0) * FLUXFAC
TOTDCLFL(0) = TOTDCLFL(0) * FLUXFAC
FNETC(0) = TOTUCLFL(0) - TOTDCLFL(0)
CLRNTTOA = TOTUCLFL(NLAYERS)
CLRNTSRF = TOTUFLUX(0) - TOTDCLFL(0)
DO 7000 LEV = 1, NLAYERS
TOTUFLUX(LEV) = TOTUFLUX(LEV) * FLUXFAC
TOTDFLUX(LEV) = TOTDFLUX(LEV) * FLUXFAC
FNET(LEV) = TOTUFLUX(LEV) - TOTDFLUX(LEV)
TOTUCLFL(LEV) = TOTUCLFL(LEV) * FLUXFAC
TOTDCLFL(LEV) = TOTDCLFL(LEV) * FLUXFAC
FNETC(LEV) = TOTUCLFL(LEV) - TOTDCLFL(LEV)
L = LEV - 1
! Calculate Heating Rates.
HTR(L) = HEATFAC * (FNET(L) - FNET(LEV)) / (PZ(L) - PZ(LEV))
HTRC(L) = HEATFAC * (FNETC(L) - FNETC(LEV)) / (PZ(L) - PZ(LEV))
7000 CONTINUE
HTR(NLAYERS) = 0.0
HTRC(NLAYERS) = 0.0
END SUBROUTINE RTRN
!---------------------------------------------------------------------------
SUBROUTINE GASABS(kts,ktep1, & 1,16
COLDRY,COLH2O,COLCO2,COLO3,COLN2O,COLCH4, &
COLO2,CO2MULT, &
FAC00,FAC01,FAC10,FAC11, &
FORFAC,SELFFAC,SELFFRAC, &
JP,JT,JT1,INDSELF,ITR,WX,PFRAC,TAUG, &
LAYTROP,LAYSWTCH,LAYLOW )
!---------------------------------------------------------------------------
! RRTM Longwave Radiative Transfer Model
! Atmospheric and Environmental Research, Inc., Cambridge, MA
!
! Original version: E. J. Mlawer, et al.
! Revision for NCAR CCM: Michael J. Iacono; September, 1998
!
! This routine calculates the gaseous optical depths for all 16 longwave
! spectral bands. The optical depths are used to define the Pade
! approximation to the function of tau transition from tranparancy to
! opacity. This function, which varies from 0 to 1, is converted to an
! integer that will serve as an index for the lookup tables of tau
! transition function and transmittance used in the radiative transfer.
! These lookup tables are created on initialization in routine RRTMINIT.
!---------------------------------------------------------------------------
!
! Definitions
! NGPT ! Total number of g-point subintervals
! MXLAY ! Maximum number of model layers
! SECANG ! Diffusivity angle for flux computation
! TAU(NGPT,MXLAY) ! Gaseous optical depths
! NLAYERS ! Number of model layers used in RRTM
! PAVEL(MXLAY) ! Model layer pressures (mb)
! PZ(0:MXLAY) ! Model level (interface) pressures (mb)
! TAVEL(MXLAY) ! Model layer temperatures (K)
! TZ(0:MXLAY) ! Model level (interface) temperatures (K)
! TBOUND ! Surface temperature (K)
! BPADE ! Pade approximation constant (=1./0.278)
! ITR(NGPT,MXLAY) ! Integer lookup table index
!
! Parameters
IMPLICIT NONE
REAL, PARAMETER :: SECANG=1.66
INTEGER, INTENT(IN ) :: kts,ktep1
INTEGER, INTENT(IN ) :: LAYTROP,LAYSWTCH,LAYLOW
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: PFRAC
REAL, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: TAUG
REAL, DIMENSION( MAXXSEC,kts:ktep1 ), &
INTENT(IN ) :: WX
INTEGER, DIMENSION( NGPT,kts:ktep1 ), &
INTENT(INOUT) :: ITR
REAL, DIMENSION( kts:ktep1 ), INTENT(IN ) :: &
COLDRY, &
COLH2O, &
COLCO2, &
COLO3, &
COLN2O, &
COLCH4, &
COLO2, &
CO2MULT, &
FAC00, &
FAC01, &
FAC10, &
FAC11, &
FORFAC, &
SELFFAC, &
SELFFRAC
INTEGER, DIMENSION( kts:ktep1 ), INTENT(INOUT) :: &
JP, &
JT, &
JT1, &
INDSELF
INTEGER :: lay,ipr
REAL :: odepth,tff
! This compiler directive was added to insure private common block storage
! in multi-tasked mode on a CRAY or SGI for all commons except those that
! carry constants.
! **************************************************************************
! Calculate optical depth for each band
CALL TAUGB1(kts,ktep1,COLH2O,FAC00,FAC01,FAC10,FAC11, &
FORFAC,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB2(kts,ktep1,COLDRY,COLH2O,FAC00,FAC01,FAC10,FAC11, &
FORFAC,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB3(kts,ktep1,COLH2O,COLCO2,COLN2O,FAC00,FAC01,FAC10,FAC11,&
FORFAC,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB4(kts,ktep1,COLH2O,COLCO2,COLO3,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB5(kts,ktep1,COLH2O,COLCO2,COLO3,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,WX,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB6(kts,ktep1,COLH2O,CO2MULT,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,WX,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB7(kts,ktep1,COLH2O,COLO3,CO2MULT,FAC00,FAC01,FAC10,FAC11,&
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB8(kts,ktep1,COLH2O,COLO3,COLN2O,CO2MULT,FAC00,FAC01,FAC10,&
FAC11,SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,WX,PFRAC,TAUG,&
LAYSWTCH)
CALL TAUGB9(kts,ktep1,COLH2O,COLN2O,COLCH4,FAC00,FAC01,FAC10,FAC11,&
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP,LAYSWTCH,LAYLOW)
CALL TAUGB10(kts,ktep1,COLH2O,FAC00,FAC01,FAC10,FAC11,JP,JT,JT1,&
PFRAC,TAUG,LAYTROP)
CALL TAUGB11(kts,ktep1,COLH2O,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB12(kts,ktep1,COLH2O,COLCO2,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB13(kts,ktep1,COLH2O,COLN2O,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB14(kts,ktep1,COLCO2,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB15(kts,ktep1,COLH2O,COLCO2,COLN2O,FAC00,FAC01,FAC10,FAC11,&
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
CALL TAUGB16(kts,ktep1,COLH2O,COLCH4,FAC00,FAC01,FAC10,FAC11, &
SELFFAC,SELFFRAC,JP,JT,JT1,INDSELF,PFRAC,TAUG, &
LAYTROP)
! Compute the lookup table index from the Pade approximation of the
! tau transition function, which is derived from the optical depth.
DO 6000 LAY = 1, NLAYERS
DO 5000 IPR = 1, NGPT
ODEPTH = SECANG * TAUG(IPR,LAY)
TFF = ODEPTH/(BPADE+ODEPTH)
IF (ODEPTH.LE.0.) TFF=0.
ITR(IPR,LAY) = INT(5.E3*TFF+0.5)
5000 CONTINUE
6000 CONTINUE
END SUBROUTINE GASABS
!====================================================================
SUBROUTINE rrtminit( & 1,1
p_top, allowed_to_read , &
ids, ide, jds, jde, kds, kde, &
ims, ime, jms, jme, kms, kme, &
its, ite, jts, jte, kts, kte )
!--------------------------------------------------------------------
IMPLICIT NONE
!--------------------------------------------------------------------
LOGICAL , INTENT(IN) :: allowed_to_read
INTEGER , INTENT(IN) :: ids, ide, jds, jde, kds, kde, &
ims, ime, jms, jme, kms, kme, &
its, ite, jts, jte, kts, kte
REAL, INTENT(IN) :: p_top
! REAL, PARAMETER :: deltap = 4 ! Pressure interval for buffer layer (hPa)
REAL :: pi
PI = 2.*ASIN(1.)
FLUXFAC = PI * 2.D4
!NLAYERS = kme
NLAYERS = kme + nint(p_top*0.01/deltap)- 1 ! Model levels plus new levels
IF ( allowed_to_read ) THEN
CALL rrtm_lookuptable
ENDIF
END SUBROUTINE rrtminit
! **************************************************************************
SUBROUTINE rrtm_lookuptable 1,22
! **************************************************************************
USE module_wrf_error
!USE module_dm, ONLY : wrf_dm_bcast_bytes
IMPLICIT NONE
! RRTM Longwave Radiative Transfer Model
! Atmospheric and Environmental Research, Inc., Cambridge, MA
!
! Original version: Michael J. Iacono; July, 1998
! Revision for NCAR CCM: Michael J. Iacono; September, 1998
!
! This subroutine performs calculations necessary for the initialization
! of the LW model, RRTM. Lookup tables are computed for use in the LW
! radiative transfer, and input absorption coefficient data for each
! spectral band are reduced from 256 g-points to 140 for use in RRTM.
! **************************************************************************
! Definitions
! Arrays for 5000-point look-up tables:
! TAU Clear-sky optical depth (used in cloudy radiative transfer)
! TF Tau transition function; i.e. the transition of the Planck
! function from that for the mean layer temperature to that for
! the layer boundary temperature as a function of optical depth.
! The "linear in tau" method is used to make the table.
! TRANS Transmittance
! BPADE Inverse of the Pade approximation constant (= 1./0.278)
! Local
INTEGER :: i,itre,igcsm,ibnd,igc,ind,ig,ipr,iprsm
REAL :: tfn,fp,rtfp,wtsum
LOGICAL :: opened
LOGICAL , EXTERNAL :: wrf_dm_on_monitor
REAL :: WTSM(MG)
CHARACTER*80 errmess
INTEGER rrtm_unit
IF ( wrf_dm_on_monitor() ) THEN
DO i = 10,99
INQUIRE ( i , OPENED = opened )
IF ( .NOT. opened ) THEN
rrtm_unit = i
GOTO 2010
ENDIF
ENDDO
rrtm_unit = -1
2010 CONTINUE
ENDIF
CALL wrf_dm_bcast_bytes ( rrtm_unit , IWORDSIZE )
IF ( rrtm_unit < 0 ) THEN
CALL wrf_error_fatal ( 'module_ra_rrtm: rrtm_lookuptable: Can not '// &
'find unused fortran unit to read in lookup table.' )
ENDIF
! start data 1
! **************************************************************************
! RRTM Longwave Radiative Transfer Model
! Atmospheric and Environmental Research, Inc., Cambridge, MA
!
! Original version: E. J. Mlawer, et al.
! Revision for NCAR CCM: Michael J. Iacono; September, 1998
!
! This routine contains 16 READ statements that include the
! absorption coefficients and other data for each of the 16 longwave
! spectral bands used in RRTM. Here, the data are defined for 16
! g-points, or sub-intervals, per band. These data are combined and
! weighted using a mapping procedure in routine RRTMINIT to reduce
! the total number of g-points from 256 to 140 for use in the CCM.
! **************************************************************************
IF ( wrf_dm_on_monitor() ) THEN
OPEN(rrtm_unit,FILE='RRTM_DATA', &
FORM='UNFORMATTED',STATUS='OLD',ERR=9009)
ENDIF
! The array abscoefL1 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the corresponding TREF for this pressure level,
! JT = 2 refers to the temperatureTREF-15, JT = 1 is for TREF-30,
! JT = 4 is for TREF+15, and JT = 5 is for TREF+30. The second
! index, JP, runs from 1 to 13 and refers to the corresponding
! pressure level in PREF (e.g. JP = 1 is for a pressure of 1053.63 mb).
! The third index, IG, goes from 1 to 16, and tells us which
! g-interval the absorption coefficients are for.
! The array abscoefH1 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array SELFREF1 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
#define DM_BCAST_MACRO(A) CALL wrf_dm_bcast_bytes ( A , size ( A ) * RWORDSIZE )
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL1, abscoefH1, SELFREF1
DM_BCAST_MACRO(abscoefL1)
DM_BCAST_MACRO(abscoefH1)
DM_BCAST_MACRO(SELFREF1)
! **************************************************************************
! The array abscoefL2 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the corresponding TREF for this pressure level, &
! JT = 2 refers to the temperatureTREF-15, JT = 1 is for TREF-30, &
! JT = 4 is for TREF+15, and JT = 5 is for TREF+30. The second
! index, JP, runs from 1 to 13 and refers to the corresponding
! pressure level in PREF (e.g. JP = 1 is for a pressure of 1053.63 mb).
! The third index, IG, goes from 1 to 16, and tells us which
! g-interval the absorption coefficients are for.
! The array abscoefH2 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array SELFREF2 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL2, abscoefH2, SELFREF2
DM_BCAST_MACRO(abscoefL2)
DM_BCAST_MACRO(abscoefH2)
DM_BCAST_MACRO(SELFREF2)
! **************************************************************************
! The array abscoefL3 contains absorption coefs for each of the 16 g-intervals
! for a range of pressure levels > ~100mb, temperatures, and ratios
! of water vapor to CO2. The first index in the array, JS, runs
! from 1 to 10, and corresponds to different water vapor to CO2 ratios, &
! as expressed through the binary species parameter eta, defined as
! eta = h2o/(h20 + (rat) * co2), where rat is the ratio of the integrated
! line strength in the band of co2 to that of h2o. For instance, &
! JS=1 refers to dry air (eta = 0), JS = 10 corresponds to eta = 1.0.
! The 2nd index in the array, JT, which runs from 1 to 5, corresponds
! to different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature
! TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the reference pressure level (e.g. JP = 1 is for a
! pressure of 1053.63 mb). The fourth index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array abscoefH3 contains absorption coefs for each of the 16 g-intervals
! for a range of pressure levels < ~100mb, temperatures, and ratios
! of H2O to CO2. The first index in the array, JS, runs from 1 to 5, &
! and corresponds to different H2O to CO2 ratios, as expressed through
! the binary species parameter eta, defined as eta = H2O/(H2O+RAT*CO2), &
! where RAT is the ratio of the integrated line strength in the band
! of CO2 to that of H2O. For instance, JS=1 refers to no H2O, &
! JS = 2 corresponds to eta = 0.25, etc. The second index, JT, which
! runs from 1 to 5, corresponds to different temperatures. More
! specifically, JT = 3 means that the data are for the corresponding
! reference temperature TREF for this pressure level, JT = 2 refers
! to the TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and
! JT = 5 is for TREF+30. The third index, JP, runs from 13 to 59 and
! refers to the corresponding pressure level in PREF (e.g. JP = 13 is
! for a pressure of 95.5835 mb). The fourth index, IG, goes from 1 to
! 16, and tells us which g-interval the absorption coefficients are for.
! The array SELFREF3 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL3, abscoefH3, SELFREF3
DM_BCAST_MACRO(abscoefL3)
DM_BCAST_MACRO(abscoefH3)
DM_BCAST_MACRO(SELFREF3)
! **************************************************************************
! The array abscoefL4 contains absorption coefs for each of the 16 g-intervals
! for a range of pressure levels > ~100mb, temperatures, and ratios
! of water vapor to CO2. The first index in the array, JS, runs
! from 1 to 9 and corresponds to different water vapor to CO2 ratios, &
! as expressed through the binary species parameter eta, defined as
! eta = h2o/(h20 + (rat) * co2), where rat is the ratio of the integrated
! line strength in the band of co2 to that of h2o. For instance, &
! JS=1 refers to dry air (eta = 0), JS = 9 corresponds to eta = 1.0.
! The 2nd index in the array, JT, which runs from 1 to 5, corresponds
! to different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, &
! JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the reference pressure level (e.g. JP = 1 is for a
! pressure of 1053.63 mb). The fourth index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array abscoefH4 contains absorption coefs for each of the 16 g-intervals
! for a range of pressure levels < ~100mb, temperatures, and ratios
! of O3 to CO2. The first index in the array, JS, runs from 1 to 6, &
! and corresponds to different O3 to CO2 ratios, as expressed through
! the binary species parameter eta, defined as eta = O3/(O3+RAT*H2O), &
! where RAT is the ratio of the integrated line strength in the band
! of CO2 to that of O3. For instance, JS=1 refers to no O3 (eta = 0)
! and JS = 5 corresponds to eta = 1.0. The second index, JT, which
! runs from 1 to 5, corresponds to different temperatures. More
! specifically, JT = 3 means that the data are for the corresponding
! reference temperature TREF for this pressure level, JT = 2 refers
! to the TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and
! JT = 5 is for TREF+30. The third index, JP, runs from 13 to 59 and
! refers to the corresponding pressure level in PREF (e.g. JP = 13 is
! for a pressure of 95.5835 mb). The fourth index, IG, goes from 1 to
! 16, and tells us which g-interval the absorption coefficients are for.
! The array SELFREF4 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL4, abscoefH4, SELFREF4
DM_BCAST_MACRO(abscoefL4)
DM_BCAST_MACRO(abscoefH4)
DM_BCAST_MACRO(SELFREF4)
! **************************************************************************
! The array abscoefL5 contains absorption coefs for each of the 16 g-intervals
! for a range of pressure levels > ~100mb, temperatures, and ratios
! of water vapor to CO2. The first index in the array, JS, runs
! from 1 to 9 and corresponds to different water vapor to CO2 ratios, &
! as expressed through the binary species parameter eta, defined as
! eta = h2o/(h20 + (rat) * co2), where rat is the ratio of the integrated
! line strength in the band of co2 to that of h2o. For instance, &
! JS=1 refers to dry air (eta = 0), JS = 9 corresponds to eta = 1.0.
! The 2nd index in the array, JT, which runs from 1 to 5, corresponds
! to different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, &
! JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the reference pressure level (e.g. JP = 1 is for a
! pressure of 1053.63 mb). The fourth index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array abscoefH5 contains absorption coefs for each of the 16 g-intervals
! for a range of pressure levels < ~100mb, temperatures, and ratios
! of O3 to CO2. The first index in the array, JS, runs from 1 to 5, &
! and corresponds to different O3 to CO2 ratios, as expressed through
! the binary species parameter eta, defined as eta = O3/(O3+RAT*CO2), &
! where RAT is the ratio of the integrated line strength in the band
! of co2 to that of O3. For instance, JS=1 refers to no O3 (eta = 0)
! and JS = 5 corresponds to eta = 1.0. The second index, JT, which
! runs from 1 to 5, corresponds to different temperatures. More
! specifically, JT = 3 means that the data are for the corresponding
! reference temperature TREF for this pressure level, JT = 2 refers
! to the TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and
! JT = 5 is for TREF+30. The third index, JP, runs from 13 to 59 and
! refers to the corresponding pressure level in PREF (e.g. JP = 13 is
! for a pressure of 95.5835 mb). The fourth index, IG, goes from 1 to
! 16, and tells us which g-interval the absorption coefficients are for.
! The array SELFREF5 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL5, abscoefH5, SELFREF5
DM_BCAST_MACRO(abscoefL5)
DM_BCAST_MACRO(abscoefH5)
DM_BCAST_MACRO(SELFREF5)
! **************************************************************************
! The array abscoefL6 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the corresponding TREF for this pressure level, &
! JT = 2 refers to the temperatureTREF-15, JT = 1 is for TREF-30, &
! JT = 4 is for TREF+15, and JT = 5 is for TREF+30. The second
! index, JP, runs from 1 to 13 and refers to the corresponding
! pressure level in PREF (e.g. JP = 1 is for a pressure of 1053.63 mb).
! The third index, IG, goes from 1 to 16, and tells us which
! g-interval the absorption coefficients are for.
! The array SELFREF6 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL6, SELFREF6
DM_BCAST_MACRO(abscoefL6)
DM_BCAST_MACRO(SELFREF6)
! **************************************************************************
! The array abscoefL7 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels> ~100mb, temperatures, and binary
! species parameters (see taumol.f for definition). The first
! index in the array, JS, runs from 1 to 9, and corresponds to
! different values of the binary species parameter. For instance, &
! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, &
! JS = 3 corresponds to the parameter value 2/8, etc. The second index
! in the array, JT, which runs from 1 to 5, corresponds to different
! temperatures. More specifically, JT = 3 means that the data are for
! the reference temperature TREF for this pressure level, JT = 2 refers
! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the JPth reference pressure level (see taumol.f for these levels
! in mb). The fourth index, IG, goes from 1 to 16, and indicates
! which g-interval the absorption coefficients are for.
! The array abscoefH7 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array SELFREF7 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL7, abscoefH7, SELFREF7
DM_BCAST_MACRO(abscoefL7)
DM_BCAST_MACRO(abscoefH7)
DM_BCAST_MACRO(SELFREF7)
! **************************************************************************
! The array abscoefL8 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the corresponding TREF for this pressure level, &
! JT = 2 refers to the temperatureTREF-15, JT = 1 is for TREF-30, &
! JT = 4 is for TREF+15, and JT = 5 is for TREF+30. The second
! index, JP, runs from 1 to 13 and refers to the corresponding
! pressure level in PREF (e.g. JP = 1 is for a pressure of 1053.63 mb).
! The third index, IG, goes from 1 to 16, and tells us which
! g-interval the absorption coefficients are for.
! The array abscoefL8 contains absorption coef5s at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the cooresponding TREF for this pressure level, &
! JT = 2 refers to the temperature
! TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The second index, JP, runs from 1 to 13 and refers
! to the corresponding pressure level in PREF (e.g. JP = 1 is for a
! pressure of 1053.63 mb). The third index, IG, goes from 1 to 16, &
! and tells us which "g-channel" the absorption coefficients are for.
! The array abscoefH8 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
!
! SELFREF8 is the array for the self-continuum.
!
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL8, abscoefH8, SELFREF8
DM_BCAST_MACRO(abscoefL8)
DM_BCAST_MACRO(abscoefH8)
DM_BCAST_MACRO(SELFREF8)
! **************************************************************************
! The array abscoefL9 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels> ~100mb, temperatures, and binary
! species parameters (see taumol.f for definition). The first
! index in the array, JS, runs from 1 to 11, and corresponds to
! different values of the binary species parameter. For instance, &
! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, &
! JS = 3 corresponds to the parameter value 2/8, etc. The second index
! in the array, JT, which runs from 1 to 5, corresponds to different
! temperatures. More specifically, JT = 3 means that the data are for
! the reference temperature TREF for this pressure level, JT = 2 refers
! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the JPth reference pressure level (see taumol.f for these levels
! in mb). The fourth index, IG, goes from 1 to 16, and indicates
! which g-interval the absorption coefficients are for.
! The array abscoefH9 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array SELFREF9 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL9, abscoefH9, SELFREF9
DM_BCAST_MACRO(abscoefL9)
DM_BCAST_MACRO(abscoefH9)
DM_BCAST_MACRO(SELFREF9)
! **************************************************************************
! The array abscoefL10 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the corresponding TREF for this pressure level, &
! JT = 2 refers to the temperatureTREF-15, JT = 1 is for TREF-30, &
! JT = 4 is for TREF+15, and JT = 5 is for TREF+30. The second
! index, JP, runs from 1 to 13 and refers to the corresponding
! pressure level in PREF (e.g. JP = 1 is for a pressure of 1053.63 mb).
! The third index, IG, goes from 1 to 16, and tells us which
! g-interval the absorption coefficients are for.
! The array abscoefH10 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL10, abscoefH10
DM_BCAST_MACRO(abscoefL10)
DM_BCAST_MACRO(abscoefH10)
! **************************************************************************
! The array abscoefL11 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the corresponding TREF for this pressure level, &
! JT = 2 refers to the temperatureTREF-15, JT = 1 is for TREF-30, &
! JT = 4 is for TREF+15, and JT = 5 is for TREF+30. The second
! index, JP, runs from 1 to 13 and refers to the corresponding
! pressure level in PREF (e.g. JP = 1 is for a pressure of 1053.63 mb).
! The third index, IG, goes from 1 to 16, and tells us which
! g-interval the absorption coefficients are for.
! The array abscoefH11 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array SELFREF11 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL11, abscoefH11, SELFREF11
DM_BCAST_MACRO(abscoefL11)
DM_BCAST_MACRO(abscoefH11)
DM_BCAST_MACRO(SELFREF11)
! **************************************************************************
! The array abscoefL12 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels> ~100mb, temperatures, and binary
! species parameters (see taumol.f for definition). The first
! index in the array, JS, runs from 1 to 9, and corresponds to
! different values of the binary species parameter. For instance, &
! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, &
! JS = 3 corresponds to the parameter value 2/8, etc. The second index
! in the array, JT, which runs from 1 to 5, corresponds to different
! temperatures. More specifically, JT = 3 means that the data are for
! the reference temperature TREF for this pressure level, JT = 2 refers
! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the JPth reference pressure level (see taumol.f for these levels
! in mb). The fourth index, IG, goes from 1 to 16, and indicates
! which g-interval the absorption coefficients are for.
! The array SELFREF12 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL12, SELFREF12
DM_BCAST_MACRO(abscoefL12)
DM_BCAST_MACRO(SELFREF12)
! **************************************************************************
! The array abscoefL13 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels> ~100mb, temperatures, and binary
! species parameters (see taumol.f for definition). The first
! index in the array, JS, runs from 1 to 9, and corresponds to
! different values of the binary species parameter. For instance, &
! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, &
! JS = 3 corresponds to the parameter value 2/8, etc. The second index
! in the array, JT, which runs from 1 to 5, corresponds to different
! temperatures. More specifically, JT = 3 means that the data are for
! the reference temperature TREF for this pressure level, JT = 2 refers
! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the JPth reference pressure level (see taumol.f for these levels
! in mb). The fourth index, IG, goes from 1 to 16, and indicates
! which g-interval the absorption coefficients are for.
! The array SELFREF13 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL13, SELFREF13
DM_BCAST_MACRO(abscoefL13)
DM_BCAST_MACRO(SELFREF13)
! **************************************************************************
! The array abscoefL14 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels > ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the corresponding TREF for this pressure level, &
! JT = 2 refers to the temperatureTREF-15, JT = 1 is for TREF-30, &
! JT = 4 is for TREF+15, and JT = 5 is for TREF+30. The second
! index, JP, runs from 1 to 13 and refers to the corresponding
! pressure level in PREF (e.g. JP = 1 is for a pressure of 1053.63 mb).
! The third index, IG, goes from 1 to 16, and tells us which
! g-interval the absorption coefficients are for.
! The array abscoefH14 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels < ~100mb and temperatures. The first
! index in the array, JT, which runs from 1 to 5, corresponds to
! different temperatures. More specifically, JT = 3 means that the
! data are for the reference temperature TREF for this pressure
! level, JT = 2 refers to the temperature TREF-15, JT = 1 is for
! TREF-30, JT = 4 is for TREF+15, and JT = 5 is for TREF+30.
! The second index, JP, runs from 13 to 59 and refers to the JPth
! reference pressure level (see taumol.f for the value of these
! pressure levels in mb). The third index, IG, goes from 1 to 16, &
! and tells us which g-interval the absorption coefficients are for.
! The array SELFREF14 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL14, abscoefH14, SELFREF14
DM_BCAST_MACRO(abscoefL14)
DM_BCAST_MACRO(abscoefH14)
DM_BCAST_MACRO(SELFREF14)
! **************************************************************************
! The array abscoefL15 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels> ~100mb, temperatures, and binary
! species parameters (see taumol.f for definition). The first
! index in the array, JS, runs from 1 to 9, and corresponds to
! different values of the binary species parameter. For instance, &
! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, &
! JS = 3 corresponds to the parameter value 2/8, etc. The second index
! in the array, JT, which runs from 1 to 5, corresponds to different
! temperatures. More specifically, JT = 3 means that the data are for
! the reference temperature TREF for this pressure level, JT = 2 refers
! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the JPth reference pressure level (see taumol.f for these levels
! in mb). The fourth index, IG, goes from 1 to 16, and indicates
! which g-interval the absorption coefficients are for.
! The array SELFREF15 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL15, SELFREF15
DM_BCAST_MACRO(abscoefL15)
DM_BCAST_MACRO(SELFREF15)
! **************************************************************************
! The array abscoefL16 contains absorption coefs at the 16 chosen g-values
! for a range of pressure levels> ~100mb, temperatures, and binary
! species parameters (see taumol.f for definition). The first
! index in the array, JS, runs from 1 to 9, and corresponds to
! different values of the binary species parameter. For instance, &
! JS=1 refers to dry air, JS = 2 corresponds to the paramter value 1/8, &
! JS = 3 corresponds to the parameter value 2/8, etc. The second index
! in the array, JT, which runs from 1 to 5, corresponds to different
! temperatures. More specifically, JT = 3 means that the data are for
! the reference temperature TREF for this pressure level, JT = 2 refers
! to TREF-15, JT = 1 is for TREF-30, JT = 4 is for TREF+15, and JT = 5
! is for TREF+30. The third index, JP, runs from 1 to 13 and refers
! to the JPth reference pressure level (see taumol.f for these levels
! in mb). The fourth index, IG, goes from 1 to 16, and indicates
! which g-interval the absorption coefficients are for.
! The array SELFREF16 contains the coefficient of the water vapor
! self-continuum (including the energy term). The first index
! refers to temperature in 7.2 degree increments. For instance, &
! JT = 1 refers to a temperature of 245.6, JT = 2 refers to 252.8, &
! etc. The second index runs over the g-channel (1 to 16).
IF ( wrf_dm_on_monitor() ) READ (rrtm_unit,ERR=9010) abscoefL16, SELFREF16
DM_BCAST_MACRO(abscoefL16)
DM_BCAST_MACRO(SELFREF16)
IF ( wrf_dm_on_monitor() ) CLOSE (rrtm_unit)
!-----------------------------------------------------------------------
! Compute lookup tables for transmittance, tau transition function,
! and clear sky tau (for the cloudy sky radiative transfer). Tau is
! computed as a function of the tau transition function, transmittance
! is calculated as a function of tau, and the tau transition function
! is calculated using the linear in tau formulation at values of tau
! above 0.01. TF is approximated as tau/6 for tau < 0.01. All tables
! are computed at intervals of 0.001. The inverse of the constant used
! in the Pade approximation to the tau transition function is set to b.
TAU(0) = 0.0
TAU(5000) = 1.E10
TRANS(0) = 1.0
TRANS(5000) = 0.0
TF(0) = 0.0
TF(5000) = 1.0
BPADE=1./0.278
DO 1000 ITRE = 1,4999
TFN = ITRE/5.E3
TAU(ITRE) = BPADE*TFN/(1.-TFN)
TRANS(ITRE) = EXP(-TAU(ITRE))
IF (TAU(ITRE).LT.0.1) THEN
TF(ITRE) = TAU(ITRE)/6.
ELSE
TF(ITRE) = 1.-2.*((1./TAU(ITRE))-(TRANS(ITRE)/(1.-TRANS(ITRE))))
ENDIF
1000 CONTINUE
! Calculate lookup tables for functions needed in routine TAUMOL (TAUGB2)
CORR1(0) = 1.
CORR1(200) = 1.
CORR2(0) = 1.
CORR2(200) = 1.
DO 1200 I = 1,199
FP = 0.005*FLOAT(I)
RTFP = SQRT(FP)
CORR1(I) = RTFP/FP
CORR2(I) = (1.-RTFP)/(1.-FP)
1200 CONTINUE
! Perform g-point reduction from 16 per band (256 total points) to
! a band dependant number (140 total points) for all absorption
! coefficient input data and Planck fraction input data.
! Compute relative weighting for new g-point combinations.
IGCSM = 0
DO 500 IBND = 1,NBANDS
IPRSM = 0
IF (NGC(IBND).LT.16) THEN
DO 450 IGC = 1,NGC(IBND)
IGCSM = IGCSM + 1
WTSUM = 0.
DO 420 IPR = 1, NGN(IGCSM)
IPRSM = IPRSM + 1
WTSUM = WTSUM + WT(IPRSM)
420 CONTINUE
WTSM(IGC) = WTSUM
450 CONTINUE
DO 400 IG = 1,NG(IBND)
IND = (IBND-1)*16 + IG
RWGT(IND) = WT(IG)/WTSM(NGM(IND))
400 CONTINUE
ELSE
DO 300 IG = 1,NG(IBND)
IGCSM = IGCSM + 1
IND = (IBND-1)*16 + IG
RWGT(IND) = 1.0
300 CONTINUE
ENDIF
500 CONTINUE
! Reduce g-points for relevant data in each LW spectral band.
CALL CMBGB1 (abscoefL1, abscoefH1, SELFREF1, &
FRACREFA1, FRACREFB1, FORREF1, &
SELFREFC1, FORREFC1, FRACREFAC1, &
FRACREFBC1 &
)
CALL CMBGB2 (abscoefL2, abscoefH2, SELFREF2, &
FRACREFA2, FRACREFB2, FORREF2, &
SELFREFC2, FORREFC2, FRACREFAC2, &
FRACREFBC2 &
)
CALL CMBGB3 (abscoefL3, abscoefH3, SELFREF3, &
FRACREFA3, FRACREFB3, &
FORREF3, ABSN2OA3, ABSN2OB3, &
SELFREFC3, FORREFC3, &
ABSN2OAC3, ABSN2OBC3, FRACREFAC3, FRACREFBC3 &
)
CALL CMBGB4 (abscoefL4, abscoefH4, SELFREF4, &
FRACREFA4, FRACREFB4, &
SELFREFC4, FRACREFAC4, FRACREFBC4 &
)
CALL CMBGB5 (abscoefL5, abscoefH5, SELFREF5, &
FRACREFA5, FRACREFB5, CCL45, &
SELFREFC5, CCL4C5, FRACREFAC5, &
FRACREFBC5 &
)
CALL CMBGB6 (abscoefL6, SELFREF6, &
FRACREFA6, ABSCO26, CFC11ADJ6, CFC126, &
SELFREFC6, ABSCO2C6, CFC11ADJC6, CFC12C6, &
FRACREFAC6 &
)
CALL CMBGB7 (abscoefL7, abscoefH7, SELFREF7, &
FRACREFA7, FRACREFB7, ABSCO27, &
SELFREFC7, ABSCO2C7, FRACREFAC7, &
FRACREFBC7 &
)
CALL CMBGB8 (abscoefL8, abscoefH8, SELFREF8, &
FRACREFA8, FRACREFB8, ABSCO2A8, ABSCO2B8, &
ABSN2OA8, ABSN2OB8, CFC128, CFC22ADJ8, &
SELFREFC8, ABSCO2AC8, ABSCO2BC8, &
ABSN2OAC8, ABSN2OBC8, CFC12C8, CFC22ADJC8, &
FRACREFAC8, FRACREFBC8 &
)
CALL CMBGB9 (abscoefL9, abscoefH9, SELFREF9, &
FRACREFA9, FRACREFB9, ABSN2O9, &
SELFREFC9, ABSN2OC9, FRACREFAC9, &
FRACREFBC9 &
)
CALL CMBGB10(abscoefL10, abscoefH10, &
FRACREFA10, FRACREFB10, &
FRACREFAC10, FRACREFBC10 &
)
CALL CMBGB11(abscoefL11, abscoefH11, SELFREF11, &
FRACREFA11, FRACREFB11, &
SELFREFC11, FRACREFAC11, &
FRACREFBC11 &
)
CALL CMBGB12(abscoefL12, SELFREF12, &
FRACREFA12, &
SELFREFC12, FRACREFAC12 &
)
CALL CMBGB13(abscoefL13, SELFREF13, &
FRACREFA13, &
SELFREFC13, FRACREFAC13 &
)
CALL CMBGB14(abscoefL14, abscoefH14, SELFREF14, &
FRACREFA14, FRACREFB14, &
SELFREFC14, FRACREFAC14, &
FRACREFBC14 &
)
CALL CMBGB15(abscoefL15, SELFREF15, &
FRACREFA15, &
SELFREFC15, FRACREFAC15 &
)
CALL CMBGB16(abscoefL16, SELFREF16, &
FRACREFA16, &
SELFREFC16, FRACREFAC16 &
)
RETURN
9009 CONTINUE
WRITE( errmess , '(A,I4)' ) 'module_ra_rrtm: error opening RRTM_DATA on unit ',rrtm_unit
CALL wrf_error_fatal(errmess)
RETURN
9010 CONTINUE
WRITE( errmess , '(A,I4)' ) 'module_ra_rrtm: error reading RRTM_DATA on unit ',rrtm_unit
CALL wrf_error_fatal(errmess)
END SUBROUTINE rrtm_lookuptable
!------------------------------------------------------------------
END MODULE module_ra_rrtm