1 | !-------------------------------------------------------------------------- |
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2 | !---------------------------- compute_hydrostatic_pressure ---------------------------------- |
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3 | SELECT CASE(caldyn_thermo) |
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4 | CASE(thermo_boussinesq) |
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5 | ! use hydrostatic balance with theta*rhodz to find pk (=Lagrange multiplier=pressure) |
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6 | !$OMP DO SCHEDULE(STATIC) |
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7 | DO ij=1,primal_num |
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8 | pk(llm,ij) = ptop + .5*g* theta_rhodz(llm,ij,1) |
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9 | DO l = llm-1,1,-1 |
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10 | pk(l,ij) = pk(l+1,ij) + (.5*g)*( theta_rhodz(l,ij,1) + theta_rhodz(l+1,ij,1) ) |
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11 | END DO |
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12 | IF(caldyn_eta == eta_lag) THEN |
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13 | ps(ij) = pk(1,ij) + .5*g* theta_rhodz(1,ij,1) |
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14 | END IF |
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15 | END DO |
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16 | !$OMP END DO |
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17 | CASE(thermo_theta, thermo_entropy, thermo_variable_Cp) |
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18 | !$OMP DO SCHEDULE(STATIC) |
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19 | DO ij=1,primal_num |
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20 | pk(llm,ij) = ptop + .5*g* rhodz(llm,ij) |
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21 | DO l = llm-1,1,-1 |
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22 | pk(l,ij) = pk(l+1,ij) + (.5*g)*( rhodz(l,ij) + rhodz(l+1,ij) ) |
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23 | END DO |
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24 | IF(caldyn_eta == eta_lag) THEN |
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25 | ps(ij) = pk(1,ij) + .5*g* rhodz(1,ij) |
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26 | END IF |
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27 | END DO |
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28 | !$OMP END DO |
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29 | CASE(thermo_moist) |
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30 | !$OMP DO SCHEDULE(STATIC) |
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31 | DO ij=1,primal_num |
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32 | pk(llm,ij) = ptop + .5*g* (rhodz(llm,ij)+theta_rhodz(llm,ij,2)) |
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33 | DO l = llm-1,1,-1 |
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34 | pk(l,ij) = pk(l+1,ij) + (.5*g)*( (rhodz(l,ij)+theta_rhodz(l,ij,2)) + (rhodz(l+1,ij)+theta_rhodz(l+1,ij,2)) ) |
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35 | END DO |
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36 | IF(caldyn_eta == eta_lag) THEN |
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37 | ps(ij) = pk(1,ij) + .5*g* (rhodz(1,ij)+theta_rhodz(1,ij,2)) |
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38 | END IF |
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39 | END DO |
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40 | !$OMP END DO |
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41 | END SELECT |
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42 | !---------------------------- compute_hydrostatic_pressure ---------------------------------- |
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43 | !-------------------------------------------------------------------------- |
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