netcdf C6_5125024_1_13968104545281187540 { dimensions: time = UNLIMITED ; // (12 currently) lat = 768 ; lon = 1024 ; bnds = 2 ; variables: double time(time) ; time:bounds = "time_bnds" ; time:units = "days since 1950-01-01" ; time:calendar = "360_day" ; time:axis = "T" ; time:long_name = "time" ; time:standard_name = "time" ; double time_bnds(time, bnds) ; double lat(lat) ; lat:bounds = "lat_bnds" ; lat:units = "degrees_north" ; lat:axis = "Y" ; lat:long_name = "latitude" ; lat:standard_name = "latitude" ; double lat_bnds(lat, bnds) ; double lon(lon) ; lon:bounds = "lon_bnds" ; lon:units = "degrees_east" ; lon:axis = "X" ; lon:long_name = "longitude" ; lon:standard_name = "longitude" ; double lon_bnds(lon, bnds) ; float rsds(time, lat, lon) ; rsds:standard_name = "surface_downwelling_shortwave_flux_in_air" ; rsds:long_name = "Surface Downwelling Shortwave Radiation" ; rsds:comment = "mo: For instantaneous outputs, this diagnostic represents an average over the radiation time step using the state of the atmosphere (T,q,clouds) from the first dynamics step within that interval. The time coordinate is the start of the radiation time step interval, so the value for t(N) is the average from t(N) to t(N+1)., HighResMIP_table_comment: surface solar irradiance for UV calculations" ; rsds:units = "W m-2" ; rsds:original_name = "mo: (stash: m01s01i235, lbproc: 128)" ; rsds:cell_methods = "area: time: mean" ; rsds:cell_measures = "area: areacella" ; rsds:history = "2018-07-05T16:04:34Z altered by CMOR: replaced missing value flag (-1.07374e+09) with standard missing value (1e+20)." ; rsds:missing_value = 1.e+20f ; rsds:_FillValue = 1.e+20f ; // global attributes: :Conventions = "CF-1.7 CMIP-6.0" ; :activity_id = "HighResMIP" ; :branch_method = "fixed historical forcing from 1950 was applied for a 30 year spin-up period, after which a fixed forcing was imposed." ; :contact = "