15 |
rv, rcpd, rcvd, rcpv, rcvv, rkappa, retv, rcw, rcs, rtt, rlvtt, & |
rv, rcpd, rcvd, rcpv, rcvv, rkappa, retv, rcw, rcs, rtt, rlvtt, & |
16 |
rlstt, rlmlt, ratm, restt, rgamw, rbetw, ralpw, rgams, rbets, ralps, & |
rlstt, rlmlt, ratm, restt, rgamw, rbetw, ralpw, rgams, rbets, ralps, & |
17 |
rgamd, rbetd, ralpd |
rgamd, rbetd, ralpd |
18 |
use yoethf |
use yoethf, only: r2es, r3ies, r3les, r4ies, r4les, r5ies, r5les, rhoh2o, & |
19 |
|
rvtmp2 |
|
LOGICAL:: firstcall = .TRUE. |
|
20 |
|
|
21 |
!------------------------------------------ |
!------------------------------------------ |
22 |
|
|
23 |
IF (firstcall) THEN |
PRINT *, 'Call sequence information: suphec' |
24 |
PRINT *, 'suphec initialise les constantes du GCM' |
|
25 |
firstcall = .FALSE. |
! 1. DEFINE FUNDAMENTAL CONSTANTS |
26 |
! |
|
27 |
!* 1. DEFINE FUNDAMENTAL CONSTANTS. |
print *, 'Constants of the ICM' |
28 |
! |
RPI=2.*ASIN(1.) |
29 |
WRITE(UNIT=6,FMT='(''0*** Constants of the ICM ***'')') |
RCLUM=299792458. |
30 |
RPI=2.*ASIN(1.) |
RHPLA=6.6260755E-34 |
31 |
RCLUM=299792458. |
RKBOL=1.380658E-23 |
32 |
RHPLA=6.6260755E-34 |
RNAVO=6.0221367E+23 |
33 |
RKBOL=1.380658E-23 |
print *, 'Fundamental constants ' |
34 |
RNAVO=6.0221367E+23 |
print '('' PI = '',E13.7,'' -'')', RPI |
35 |
WRITE(UNIT=6,FMT='('' *** Fundamental constants ***'')') |
print '('' c = '',E13.7,''m s-1'')', RCLUM |
36 |
WRITE(UNIT=6,FMT='('' PI = '',E13.7,'' -'')')RPI |
print '('' h = '',E13.7,''J s'')', RHPLA |
37 |
WRITE(UNIT=6,FMT='('' c = '',E13.7,''m s-1'')') & |
print '('' K = '',E13.7,''J K-1'')', RKBOL |
38 |
RCLUM |
print '('' N = '',E13.7,''mol-1'')', RNAVO |
39 |
WRITE(UNIT=6,FMT='('' h = '',E13.7,''J s'')') & |
|
40 |
RHPLA |
! 2. DEFINE ASTRONOMICAL CONSTANTS |
41 |
WRITE(UNIT=6,FMT='('' K = '',E13.7,''J K-1'')') & |
|
42 |
RKBOL |
RDAY=86400. |
43 |
WRITE(UNIT=6,FMT='('' N = '',E13.7,''mol-1'')') & |
REA=149597870000. |
44 |
RNAVO |
REPSM=0.409093 |
45 |
! |
|
46 |
! |
RSIYEA=365.25*RDAY*2.*RPI/6.283076 |
47 |
!* 2. DEFINE ASTRONOMICAL CONSTANTS. |
RSIDAY=RDAY/(1.+RDAY/RSIYEA) |
48 |
! |
ROMEGA=2.*RPI/RSIDAY |
49 |
RDAY=86400. |
|
50 |
REA=149597870000. |
print *, 'Astronomical constants ' |
51 |
REPSM=0.409093 |
print '('' day = '',E13.7,'' s'')', RDAY |
52 |
! |
print '('' half g. axis = '',E13.7,'' m'')', REA |
53 |
RSIYEA=365.25*RDAY*2.*RPI/6.283076 |
print '('' mean anomaly = '',E13.7,'' -'')', REPSM |
54 |
RSIDAY=RDAY/(1.+RDAY/RSIYEA) |
print '('' sideral year = '',E13.7,'' s'')', RSIYEA |
55 |
ROMEGA=2.*RPI/RSIDAY |
print '('' sideral day = '',E13.7,'' s'')', RSIDAY |
56 |
! |
print '('' omega = '',E13.7,'' s-1'')', ROMEGA |
57 |
WRITE(UNIT=6,FMT='('' *** Astronomical constants ***'')') |
|
58 |
WRITE(UNIT=6,FMT='('' day = '',E13.7,'' s'')')RDAY |
! 3. DEFINE GEOIDE. |
59 |
WRITE(UNIT=6,FMT='('' half g. axis = '',E13.7,'' m'')')REA |
|
60 |
WRITE(UNIT=6,FMT='('' mean anomaly = '',E13.7,'' -'')')REPSM |
RG=9.80665 |
61 |
WRITE(UNIT=6,FMT='('' sideral year = '',E13.7,'' s'')')RSIYEA |
RA=6371229. |
62 |
WRITE(UNIT=6,FMT='('' sideral day = '',E13.7,'' s'')')RSIDAY |
R1SA=SNGL(1.D0/DBLE(RA)) |
63 |
WRITE(UNIT=6,FMT='('' omega = '',E13.7,'' s-1'')') & |
print *, ' Geoide ' |
64 |
ROMEGA |
print '('' Gravity = '',E13.7,'' m s-2'')', RG |
65 |
! |
print '('' Earth radius = '',E13.7,'' m'')', RA |
66 |
!* 3. DEFINE GEOIDE. |
print '('' Inverse E.R. = '',E13.7,'' m'')', R1SA |
67 |
! |
|
68 |
RG=9.80665 |
! 4. DEFINE RADIATION CONSTANTS. |
69 |
RA=6371229. |
|
70 |
R1SA=SNGL(1.D0/DBLE(RA)) |
rsigma = 2.*rpi**5 * (rkbol/rhpla)**3 * rkbol/rclum/rclum/15. |
71 |
WRITE(UNIT=6,FMT='('' *** Geoide ***'')') |
print *, ' Radiation ' |
72 |
WRITE(UNIT=6,FMT='('' Gravity = '',E13.7,'' m s-2'')') & |
print '('' Stefan-Bol. = '',E13.7,'' W m-2 K-4'')', RSIGMA |
73 |
RG |
|
74 |
WRITE(UNIT=6,FMT='('' Earth radius = '',E13.7,'' m'')')RA |
! 5. DEFINE THERMODYNAMIC CONSTANTS, GAS PHASE. |
75 |
WRITE(UNIT=6,FMT='('' Inverse E.R. = '',E13.7,'' m'')')R1SA |
|
76 |
! |
R=RNAVO*RKBOL |
77 |
! |
RMD=28.9644 |
78 |
!* 4. DEFINE RADIATION CONSTANTS. |
RMO3=47.9942 |
79 |
! |
RMV=18.0153 |
80 |
! z.x.li RSIGMA=2. * RPI**5 * RKBOL**4 /(15.* RCLUM**2 * RHPLA**3) |
RD=1000.*R/RMD |
81 |
rsigma = 2.*rpi**5 * (rkbol/rhpla)**3 * rkbol/rclum/rclum/15. |
RV=1000.*R/RMV |
82 |
!IM init. dans conf_phys.F90 RI0=1365. |
RCPD=3.5*RD |
83 |
WRITE(UNIT=6,FMT='('' *** Radiation ***'')') |
RCVD=RCPD-RD |
84 |
WRITE(UNIT=6,FMT='('' Stefan-Bol. = '',E13.7,'' W m-2 K-4'')') RSIGMA |
RCPV=4. *RV |
85 |
|
RCVV=RCPV-RV |
86 |
! |
RKAPPA=RD/RCPD |
87 |
!* 5. DEFINE THERMODYNAMIC CONSTANTS, GAS PHASE. |
RETV=RV/RD-1. |
88 |
! |
print *, 'Thermodynamic, gas ' |
89 |
R=RNAVO*RKBOL |
print '('' Perfect gas = '',e13.7)', R |
90 |
RMD=28.9644 |
print '('' Dry air mass = '',e13.7)', RMD |
91 |
RMO3=47.9942 |
print '('' Ozone mass = '',e13.7)', RMO3 |
92 |
RMV=18.0153 |
print '('' Vapour mass = '',e13.7)', RMV |
93 |
RD=1000.*R/RMD |
print '('' Dry air cst. = '',e13.7)', RD |
94 |
RV=1000.*R/RMV |
print '('' Vapour cst. = '',e13.7)', RV |
95 |
RCPD=3.5*RD |
print '('' Cpd = '',e13.7)', RCPD |
96 |
RCVD=RCPD-RD |
print '('' Cvd = '',e13.7)', RCVD |
97 |
RCPV=4. *RV |
print '('' Cpv = '',e13.7)', RCPV |
98 |
RCVV=RCPV-RV |
print '('' Cvv = '',e13.7)', RCVV |
99 |
RKAPPA=RD/RCPD |
print '('' Rd/Cpd = '',e13.7)', RKAPPA |
100 |
RETV=RV/RD-1. |
print '('' Rv/Rd-1 = '',e13.7)', RETV |
101 |
WRITE(UNIT=6,FMT='('' *** Thermodynamic, gas ***'')') |
|
102 |
WRITE(UNIT=6,FMT='('' Perfect gas = '',e13.7)') R |
! 6. DEFINE THERMODYNAMIC CONSTANTS, LIQUID PHASE. |
103 |
WRITE(UNIT=6,FMT='('' Dry air mass = '',e13.7)') RMD |
|
104 |
WRITE(UNIT=6,FMT='('' Ozone mass = '',e13.7)') RMO3 |
RCW=RCPV |
105 |
WRITE(UNIT=6,FMT='('' Vapour mass = '',e13.7)') RMV |
print *, 'Thermodynamic, liquid ' |
106 |
WRITE(UNIT=6,FMT='('' Dry air cst. = '',e13.7)') RD |
print '('' Cw = '',E13.7)', RCW |
107 |
WRITE(UNIT=6,FMT='('' Vapour cst. = '',e13.7)') RV |
|
108 |
WRITE(UNIT=6,FMT='('' Cpd = '',e13.7)') RCPD |
! 7. DEFINE THERMODYNAMIC CONSTANTS, SOLID PHASE. |
109 |
WRITE(UNIT=6,FMT='('' Cvd = '',e13.7)') RCVD |
|
110 |
WRITE(UNIT=6,FMT='('' Cpv = '',e13.7)') RCPV |
RCS=RCPV |
111 |
WRITE(UNIT=6,FMT='('' Cvv = '',e13.7)') RCVV |
print *, 'thermodynamic, solid' |
112 |
WRITE(UNIT=6,FMT='('' Rd/Cpd = '',e13.7)') RKAPPA |
print '('' Cs = '',E13.7)', RCS |
113 |
WRITE(UNIT=6,FMT='('' Rv/Rd-1 = '',e13.7)') RETV |
|
114 |
! |
! 8. DEFINE THERMODYNAMIC CONSTANTS, TRANSITION OF PHASE. |
115 |
! |
|
116 |
!* 6. DEFINE THERMODYNAMIC CONSTANTS, LIQUID PHASE. |
RTT=273.16 |
117 |
! |
RLVTT=2.5008E+6 |
118 |
RCW=RCPV |
RLSTT=2.8345E+6 |
119 |
WRITE(UNIT=6,FMT='('' *** Thermodynamic, liquid ***'')') |
RLMLT=RLSTT-RLVTT |
120 |
WRITE(UNIT=6,FMT='('' Cw = '',E13.7)') RCW |
RATM=100000. |
121 |
! |
print *, 'Thermodynamic, trans. ' |
122 |
! |
print '('' Fusion point = '',E13.7)', RTT |
123 |
!* 7. DEFINE THERMODYNAMIC CONSTANTS, SOLID PHASE. |
print '('' RLvTt = '',E13.7)', RLVTT |
124 |
! |
print '('' RLsTt = '',E13.7)', RLSTT |
125 |
RCS=RCPV |
print '('' RLMlt = '',E13.7)', RLMLT |
126 |
WRITE(UNIT=6,FMT='('' *** thermodynamic, solid ***'')') |
print '('' Normal press. = '',E13.7)', RATM |
127 |
WRITE(UNIT=6,FMT='('' Cs = '',E13.7)') RCS |
|
128 |
! |
! 9. SATURATED VAPOUR PRESSURE. |
129 |
! |
|
130 |
!* 8. DEFINE THERMODYNAMIC CONSTANTS, TRANSITION OF PHASE. |
RESTT=611.14 |
131 |
! |
RGAMW=(RCW-RCPV)/RV |
132 |
RTT=273.16 |
RBETW=RLVTT/RV+RGAMW*RTT |
133 |
RLVTT=2.5008E+6 |
RALPW=LOG(RESTT)+RBETW/RTT+RGAMW*LOG(RTT) |
134 |
RLSTT=2.8345E+6 |
RGAMS=(RCS-RCPV)/RV |
135 |
RLMLT=RLSTT-RLVTT |
RBETS=RLSTT/RV+RGAMS*RTT |
136 |
RATM=100000. |
RALPS=LOG(RESTT)+RBETS/RTT+RGAMS*LOG(RTT) |
137 |
WRITE(UNIT=6,FMT='('' *** Thermodynamic, trans. ***'')') |
RGAMD=RGAMS-RGAMW |
138 |
WRITE(UNIT=6,FMT='('' Fusion point = '',E13.7)') RTT |
RBETD=RBETS-RBETW |
139 |
WRITE(UNIT=6,FMT='('' RLvTt = '',E13.7)') RLVTT |
RALPD=RALPS-RALPW |
140 |
WRITE(UNIT=6,FMT='('' RLsTt = '',E13.7)') RLSTT |
|
141 |
WRITE(UNIT=6,FMT='('' RLMlt = '',E13.7)') RLMLT |
! calculer les constantes pour les fonctions thermodynamiques |
142 |
WRITE(UNIT=6,FMT='('' Normal press. = '',E13.7)') RATM |
|
143 |
WRITE(UNIT=6,FMT='('' Latent heat : '')') |
RVTMP2=RCPV/RCPD-1. |
144 |
! |
RHOH2O=RATM/100. |
145 |
! |
R2ES=RESTT*RD/RV |
146 |
!* 9. SATURATED VAPOUR PRESSURE. |
R3LES=17.269 |
147 |
! |
R3IES=21.875 |
148 |
RESTT=611.14 |
R4LES=35.86 |
149 |
RGAMW=(RCW-RCPV)/RV |
R4IES=7.66 |
150 |
RBETW=RLVTT/RV+RGAMW*RTT |
R5LES=R3LES*(RTT-R4LES) |
151 |
RALPW=LOG(RESTT)+RBETW/RTT+RGAMW*LOG(RTT) |
R5IES=R3IES*(RTT-R4IES) |
|
RGAMS=(RCS-RCPV)/RV |
|
|
RBETS=RLSTT/RV+RGAMS*RTT |
|
|
RALPS=LOG(RESTT)+RBETS/RTT+RGAMS*LOG(RTT) |
|
|
RGAMD=RGAMS-RGAMW |
|
|
RBETD=RBETS-RBETW |
|
|
RALPD=RALPS-RALPW |
|
|
! |
|
|
! |
|
|
! calculer les constantes pour les fonctions thermodynamiques |
|
|
! |
|
|
RVTMP2=RCPV/RCPD-1. |
|
|
RHOH2O=RATM/100. |
|
|
R2ES=RESTT*RD/RV |
|
|
R3LES=17.269 |
|
|
R3IES=21.875 |
|
|
R4LES=35.86 |
|
|
R4IES=7.66 |
|
|
R5LES=R3LES*(RTT-R4LES) |
|
|
R5IES=R3IES*(RTT-R4IES) |
|
|
|
|
|
ELSE |
|
|
PRINT *, 'suphec DEJA APPELE ' |
|
|
ENDIF |
|
152 |
|
|
153 |
END SUBROUTINE suphec |
END SUBROUTINE suphec |
154 |
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|