function interp_CFSRv2(NCEP_dir,Y,M,Roa,interp_method,... lon1,lat1,mask1,tin,... nc_frc,nc_blk,lon,lat,angle,tout,Get_My_Data) % % Read the local NCEP files and perform the interpolations % % % 1: Air temperature: Convert from Kelvin to Celsius % varname='TAIR'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); tair=squeeze(nc{varname}(tin,:,:)); close(nc); tair=get_missing_val(lon1,lat1,mask1.*tair,nan,Roa,nan); tair=tair-273.15; tair=interp2(lon1,lat1,tair,lon,lat,interp_method); % % 2: Relative humidity: Convert from % to fraction % % Get Specific Humidity [Kg/Kg] % varname='SPECHUM'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); shum=squeeze(nc{varname}(tin,:,:)); close(nc); shum=get_missing_val(lon1,lat1,mask1.*shum,nan,Roa,nan); shum=interp2(lon1,lat1,shum,lon,lat,interp_method); % % computes specific humidity at saturation (Tetens formula) % (see air_sea tools, fonction qsat) % rhum=shum./qsat(tair); % % 3: Precipitation rate: Convert from [kg/m^2/s] to cm/day % varname='PRATE'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); prate=squeeze(nc{varname}(tin,:,:)); close(nc); prate=get_missing_val(lon1,lat1,mask1.*prate,nan,Roa,nan); prate=prate*0.1*(24.*60.*60.0); prate=interp2(lon1,lat1,prate,lon,lat,interp_method); prate(abs(prate)<1.e-4)=0; % % 4: Net shortwave flux: [W/m^2] % CROCO convention: downward = positive % % Downward solar shortwave % varname='SHORT_WAVE_DOWN'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); dswrf=squeeze(nc{varname}(tin,:,:)); close(nc); dswrf=get_missing_val(lon1,lat1,mask1.*dswrf,nan,Roa,nan); % % Upward solar shortwave % varname='SHORT_WAVE_UP'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); uswrf=squeeze(nc{varname}(tin,:,:)); close(nc); uswrf=get_missing_val(lon1,lat1,mask1.*uswrf,nan,Roa,nan); % % Net solar shortwave radiation % radsw=dswrf - uswrf; %---------------------------------------------------- % GC le 31 03 2009 % radsw is NET solar shortwave radiation % no more downward only solar radiation % GC bug fix by F. Marin IRD/LEGOS %----------------------------------------------------- radsw=interp2(lon1,lat1,radsw,lon,lat,interp_method); radsw(radsw<1.e-10)=0; % % 5: Net outgoing Longwave flux: [W/m^2] % CROCO convention: positive upward (opposite to nswrf !!!!) % % Get the net longwave flux [W/m^2] % % 5.1 get the downward longwave flux [W/m^2] % varname='LONG_WAVE_DOWN'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); dlwrf=squeeze(nc{varname}(tin,:,:)); close(nc); dlwrf=get_missing_val(lon1,lat1,mask1.*dlwrf,nan,Roa,nan); % % 5.2 get the upward longwave flux [W/m^2] % varname='LONG_WAVE_UP'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); ulwrf=squeeze(nc{varname}(tin,:,:)); close(nc); ulwrf=get_missing_val(lon1,lat1,mask1.*ulwrf,nan,Roa,nan); % % Net longwave flux % radlw=interp2(lon1,lat1,ulwrf-dlwrf,lon,lat,interp_method); % % get the downward longwave heat flux % radlw_in=interp2(lon1,lat1,dlwrf,lon,lat,interp_method); % % 6: Wind & Wind stress [m/s] % varname='U10m'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); uwnd=squeeze(nc{varname}(tin,:,:)); close(nc) uwnd=get_missing_val(lon1,lat1,mask1.*uwnd,nan,Roa,nan); uwnd=interp2(lon1,lat1,uwnd,lon,lat,interp_method); % varname='V10m'; nc=netcdf([NCEP_dir,'CFSv2_DODS_frc_blk_1hourly','_Y',num2str(Y),'M',num2str(M),'.nc']); vwnd=squeeze(nc{varname}(tin,:,:)); close(nc) vwnd=get_missing_val(lon1,lat1,mask1.*vwnd,nan,Roa,nan); vwnd=interp2(lon1,lat1,vwnd,lon,lat,interp_method); % % Compute the stress % wspd=sqrt(uwnd.^2+vwnd.^2); [Cd,uu]=cdnlp(wspd,10.); rhoa=air_dens(tair,rhum*100); tx=Cd.*rhoa.*uwnd.*wspd; ty=Cd.*rhoa.*vwnd.*wspd; % % Rotations on the CROCO grid % cosa=cos(angle); sina=sin(angle); % sustr=rho2u_2d(tx.*cosa+ty.*sina); svstr=rho2v_2d(ty.*cosa-tx.*sina); % % uwnd et vwnd sont aux points 'rho' % u10=rho2u_2d(uwnd.*cosa+vwnd.*sina); v10=rho2v_2d(vwnd.*cosa-uwnd.*sina); % % Fill the CROCO files % if ~isempty(nc_frc) nc_frc{'sustr'}(tout,:,:)=sustr; nc_frc{'svstr'}(tout,:,:)=svstr; end if ~isempty(nc_blk) nc_blk{'tair'}(tout,:,:)=tair; nc_blk{'rhum'}(tout,:,:)=rhum; nc_blk{'prate'}(tout,:,:)=prate; nc_blk{'wspd'}(tout,:,:)=wspd; nc_blk{'radlw'}(tout,:,:)=radlw; nc_blk{'radlw_in'}(tout,:,:)=radlw_in; nc_blk{'radsw'}(tout,:,:)=radsw; nc_blk{'uwnd'}(tout,:,:)=u10; nc_blk{'vwnd'}(tout,:,:)=v10; nc_blk{'sustr'}(tout,:,:)=sustr; nc_blk{'svstr'}(tout,:,:)=svstr; end