| 1 | c*********************************************************************** |
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| 2 | subroutine neutral(u10_mps,ustar_mps,obklen_m, |
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| 3 | + u10n_mps ) |
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| 4 | c----------------------------------------------------------------------- |
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| 5 | c subroutine to compute u10 neutral wind speed |
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| 6 | c inputs |
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| 7 | c u10_mps - wind speed at 10 m (m/s) |
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| 8 | c ustar_mps - friction velocity (m/s) |
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| 9 | c obklen_m - monin-obukhov length scale (m) |
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| 10 | c outputs |
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| 11 | c u10n_mps - wind speed at 10 m under neutral conditions (m/s) |
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| 12 | c following code assumes reference height Z is 10m, consistent with use |
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| 13 | c of u10 and u10_neutral. If not, code |
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| 14 | c should be changed so that constants of 50. and 160. in equations |
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| 15 | c below are changed to -5 * Z and -16 * Z respectively. |
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| 16 | c Reference: G. L. Geernaert. 'Bulk parameterizations for the |
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| 17 | c wind stress and heat fluxes,' in Surface Waves and Fluxes, Vol. I, |
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| 18 | c Current Theory, Geernaert and W.J. Plant, editors, Kluwer Academic |
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| 19 | c Publishers, Boston, MA, 1990. |
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| 20 | c subroutine written Feb 2001 by eg chapman |
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| 21 | c adapted to LMD-ZT by E. Cosme 310801 |
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| 22 | c Following Will Shaw (PNL, Seattle) the theory applied for flux |
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| 23 | c calculation with the scheme of Nightingale et al. (2000) does not |
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| 24 | c hold anymore when -1<obklen<20. In this case, u10n is set to 0, |
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| 25 | c so that the transfer velocity computed in nightingale.F will also |
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| 26 | c be 0. The flux is then set to 0. |
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| 27 | c---------------------------------------------------------------------- |
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| 28 | c |
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| 29 | USE dimphy |
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| 30 | #include "dimensions.h" |
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| 31 | c |
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| 32 | real u10_mps(klon),ustar_mps(klon),obklen_m(klon) |
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| 33 | real u10n_mps(klon) |
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| 34 | real pi,von_karman |
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| 35 | c parameter (pi = 3.141592653589793, von_karman = 0.4) |
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| 36 | c pour etre coherent avec vk de bl_for_dms.F |
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| 37 | parameter (pi = 3.141592653589793, von_karman = 0.35) |
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| 38 | c |
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| 39 | real phi, phi_inv, phi_inv_sq, f1, f2, f3, dum1, psi |
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| 40 | integer i |
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| 41 | |
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| 42 | |
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| 43 | psi = 0. |
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| 44 | do i=1,klon |
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| 45 | |
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| 46 | if (u10_mps(i) .lt. 0.) u10_mps(i) = 0.0 |
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| 47 | |
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| 48 | if (obklen_m(i) .lt. 0.) then |
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| 49 | phi = (1. - 160./obklen_m(i))**(-0.25) |
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| 50 | phi_inv = 1./phi |
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| 51 | phi_inv_sq = 1./phi * 1./phi |
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| 52 | f1 = (1. + phi_inv) / 2. |
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| 53 | f2 = (1. + phi_inv_sq)/2. |
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| 54 | c following to avoid numerical overruns. recall tan(90deg)=infinity |
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| 55 | dum1 = min (1.e24, phi_inv) |
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| 56 | f3 = atan(dum1) |
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| 57 | psi = 2.*log(f1) + log(f2) - 2.*f3 + pi/2. |
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| 58 | else if (obklen_m(i) .gt. 0.) then |
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| 59 | psi = -50. / obklen_m(i) |
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| 60 | end if |
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| 61 | |
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| 62 | u10n_mps(i) = u10_mps(i) + (ustar_mps(i) * psi /von_karman ) |
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| 63 | c u10n set to 0. if -1 < obklen < 20 |
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| 64 | if ((obklen_m(i).gt.-1.).and.(obklen_m(i).lt.20.)) then |
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| 65 | u10n_mps(i) = 0. |
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| 66 | endif |
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| 67 | if (u10n_mps(i) .lt. 0.) u10n_mps(i) = 0.0 |
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| 68 | |
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| 69 | enddo |
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| 70 | return |
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| 71 | end |
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| 72 | c*********************************************************************** |
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