All functions
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Ar()
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Ar: Archimedes number |
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E()
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Evaporation (mol / (m^2 s)) |
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constants()
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S3 class constants |
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convert_conductance()
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Convert conductance units |
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.get_Dx()
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D_x: Calculate diffusion coefficient for a given temperature and pressure |
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.get_H()
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H: sensible heat flux density (W / m^2) |
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.get_L()
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L: Latent heat flux density (W / m^2) |
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.get_Pa()
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P_a: density of dry air (g / m^3) |
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.get_Rabs()
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R_abs: total absorbed radiation (W / m^2) |
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.get_Sr()
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S_r: longwave re-radiation (W / m^2) |
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.get_Tv()
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Calculate virtual temperature |
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.get_dwv()
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d_wv: water vapour gradient (mol / m ^ 3) |
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.get_gbw()
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g_bw: Boundary layer conductance to water vapour (m / s) |
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.get_gh()
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g_h: boundary layer conductance to heat (m / s) |
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.get_gr()
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Gr: Grashof number |
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.get_gtw()
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g_tw: total conductance to water vapour (m/s) |
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.get_hvap()
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h_vap: heat of vaporization (J / mol) |
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.get_nu()
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Nu: Nusselt number |
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.get_ps()
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Saturation water vapour pressure (kPa) |
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.get_re()
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Re: Reynolds number |
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.get_sh()
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Sh: Sherwood number |
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energy_balance()
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Calculate leaf energy balance |
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enviro_par()
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S3 class enviro_par |
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leaf_par()
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S3 class leaf_par |
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make_leafpar() make_enviropar() make_constants()
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Make lists of parameters of leaf, environmental, or constant parameters |
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parameter_names()
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Get vector of parameter names |
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tealeaves
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tealeaves package
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tl_example1
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tealeaves example output 1 |
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tleaves() tleaf()
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tleaves: find leaf temperatures for multiple parameter sets
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