solweig-gpu 1.2.15

GPU-accelerated SOLWEIG model for urban thermal comfort simulation

SOLWEIG-GPU: GPU-Accelerated Thermal Comfort Modeling Framework

SOLWEIG-GPU is a Python package and command-line interface for running standalone SOLWEIG (Solar and LongWave Environmental Irradiance Geometry) model on CPU or GPU (if available). It enables high-resolution urban microclimate modeling by computing key variables such as Sky View Factor (SVF), Mean Radiant Temperature (Tmrt), and the Universal Thermal Climate Index (UTCI).

SOLWEIG was originally developed by Dr. Fredrik Lindberg's group. Journal reference: Lindberg, F., Holmer, B. & Thorsson, S. SOLWEIG 1.0 – Modelling spatial variations of 3D radiant fluxes and mean radiant temperature in complex urban settings. Int J Biometeorol 52, 697–713 (2008). https://doi.org/10.1007/s00484-008-0162-7

SOLWEIG GPU code is an extension of the original SOLWEIG Python model that is part of the Urban Multi-scale Environmental Predictor (UMEP). GitHub code: https://github.com/UMEP-dev/UMEP
UMEP journal reference: Lindberg, F., Grimmond, C.S.B., Gabey, A., Huang, B., Kent, C.W., Sun, T., Theeuwes, N.E., Järvi, L., Ward, H.C., Capel-Timms, I. and Chang, Y., 2018. Urban Multi-scale Environmental Predictor (UMEP): An integrated tool for city-based climate services. Environmental Modelling & Software, 99, pp.70-87. https://doi.org/10.1016/j.envsoft.2017.09.020

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Features

• CPU and GPU support (automatically uses GPU if available)
• Divides larger areas into tiles based on the selected tile size
• CPU-based computations of wall height and aspect are parallelized across multiple CPUs
• GPU-based computation of SVF, shortwave/longwave radiation, shadows, Tmrt, and UTCI
• Compatible with meteorological data from UMEP, ERA5, and WRF (wrfout)

Flowchart of the SOLWEIG-GPU modeling framework

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Required Input Data

• Building DSM: Includes both buildings and terrain elevation (e.g., Building_DSM.tif)
• DEM: Digital Elevation Model excluding buildings (e.g., DEM.tif)
• Tree DSM: Vegetation height data only (e.g., Trees.tif)

Currently tested only for hourly data

• Meteorological forcing:
  • Custom .txt file (from UMEP)
  • ERA5 (both instantaneous and accumulated)
  • WRF output NetCDF (wrfout)

ERA5 Variables Required

• 2-meter air temperature
• 2-meter dew point temperature
• Surface pressure
• 10-meter U and V wind components
• Downwelling shortwave radiation (accumulated)
• Downwelling longwave radiation (accumulated)

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Output Details

• Output directory: Outputs/
• Structure: One folder per tile (e.g., tile_0_0/, tile_0_600/)
• SVF: Single-band raster
• Other outputs: Multi-band raster (e.g., 24 bands for hourly results)

UTCI for New Delhi, India, generated using SOLWEIG-GPU and visualized with ArcGIS Online.

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Installation

conda create -n solweig python=3.10
conda activate solweig
conda install -c conda-forge gdal cudnn pytorch timezonefinder matplotlib pyqt=5 sip
pip install solweig-gpu

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Sample Data

Please refer to the sample dataset to familiarize yourself with the expected inputs. Sample data can be found at:
https://doi.org/10.5281/zenodo.17048978

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Python Usage

Notes on sample data and forcing options

• The Input_raster folder in the sample contains the raster files required by SOLWEIG-GPU:

  1. Building_DSM.tif
  2. DEM.tif
  3. Trees.tif
  4. Landcover.tif (optional)

• SOLWEIG-GPU can be meteorologically forced in three ways:

  1. Using your own meteorological .txt file
  2. ERA5 reanalysis
  3. Weather Research and Forecasting (WRF) output files. Make sure filenames follow one of:
     • wrfout_d0x_yyyy-mm-dd_hh_mm_ss (preferred; works across operating systems)
     • wrfout_d0x_yyyy-mm-dd_hh:mm:ss
     • wrfout_d0x_yyyy-mm-dd_hh

• The Forcing_data folder in the sample data contains example data for all forcing methods.

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Examples with the provided sample data

Example 1: WRF

from solweig_gpu import thermal_comfort

thermal_comfort(
    base_path='/path/to/input',
    selected_date_str='2020-08-13',
    building_dsm_filename='Building_DSM.tif',
    dem_filename='DEM.tif',
    trees_filename='Trees.tif',
    landcover_filename=None,
    tile_size=1000,
    overlap=100,
    use_own_met=False,
    own_met_file='/path/to/met.txt',  # Placeholder as use_own_met=False
    start_time='2020-08-13 06:00:00',
    end_time='2020-08-14 05:00:00',
    data_source_type='wrfout',
    data_folder='/path/to/era5_or_wrfout',
    save_tmrt=False,  # True if you want to save TMRT, likewise below
    save_svf=False,
    save_kup=False,
    save_kdown=False,
    save_lup=False,
    save_ldown=False,
    save_shadow=False
)

• The model simulation date is 2020-08-13
• The start and end dates provided to the model are 2020-08-13 06:00:00 UTC and 2020-08-14 05:00:00 UTC, respectively. These are start and end time of wrfout in UTC. In local time it is 2020-08-13 01:00:00 to 2020-08-13 23:00:00 (Austin, TX). UTC to local time conversion will be done internally.
• The tile_size depends on the RAM of the GPU but can be set to 1000 in the example.
• overlap is set to 100 pixels meaning the raster size will be 1100*1100 pixels. The additional 100 pixels are for shadow transfer between the tiles.

Example 2: ERA5

from solweig_gpu import thermal_comfort

thermal_comfort(
    base_path='/path/to/input',
    selected_date_str='2020-08-13',
    building_dsm_filename='Building_DSM.tif',
    dem_filename='DEM.tif',
    trees_filename='Trees.tif',
    landcover_filename = None,
    tile_size =1000,
    overlap = 100,
    use_own_met=False,
    own_met_file='/path/to/met.txt',  #Placeholder as use_own_met=False
    start_time='2020-08-13 06:00:00',
    end_time=  '2020-08-13 23:00:00',
    data_source_type='ERA5',
    data_folder='/path/to/era5_or_wrfout',
    save_tmrt=False, #True if you want to save TMRT, likewise below
    save_svf=False,
    save_kup=False,
    save_kdown=False,
    save_lup=False,
    save_ldown=False,
    save_shadow=False
)

• For the ERA-5, the sample data provided is from 2020-08-13 06:00:00 UTC to 2020-08-13 23:00:00 UTC. So the simulation will run from 2020-08-13 01:00:00 to 2020-08-13 18:00:00 local time (Austin, TX)

Example 3: Own File

from solweig_gpu import thermal_comfort
thermal_comfort(
    base_path='/path/to/input',
    selected_date_str='2020-08-13',
    building_dsm_filename='Building_DSM.tif',
    dem_filename='DEM.tif',
    trees_filename='Trees.tif',
    landcover_filename = None,
    tile_size =1000,
    overlap = 100,
    use_own_met= True,
    own_met_file='/path/to/met.txt',
    start_time='2020-08-13 06:00:00', # Placeholder
    end_time=  '2020-08-13 23:00:00', # Placeholder
    data_source_type='ERA5', # Placeholder
    data_folder='/path/to/era5_or_wrfout', # Placeholder
    save_tmrt=False, #True if you want to save TMRT, likewise below
    save_svf=False,
    save_kup=False,
    save_kdown=False,
    save_lup=False,
    save_ldown=False,
    save_shadow=False
)

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Command-Line Interface (CLI)

Example using sample ERA5 data

conda activate solweig
thermal_comfort --base_path '/path/to/input' ^
                --date '2020-08-13' ^
                --building_dsm 'Building_DSM.tif' ^
                --dem 'DEM.tif' ^
                --trees 'Trees.tif' ^
                --tile_size 1000 ^
                --landcover  'Landcover2.tif' ^
                --overlap 100 ^
                --use_own_met False ^
                --data_source_type 'ERA5' ^
                --data_folder '/path/to/era5' ^
                --start '2020-08-13 06:00:00' ^
                --end '2020-08-13 23:00:00' ^
                --save_tmrt True ^
                --save_svf False ^
                --save_kup False ^
                --save_kdown False ^
                --save_lup False ^
                --save_ldown False ^
                --save_shadow False

Tip: Use --help to list all CLI options.

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GUI Usage

To launch the GUI:

conda activate solweig
solweig_gpu_gui

GUI Workflow

1. Select the base path containing input datasets.
2. Choose the Building DSM, DEM, Tree DSM, and Land cover (optional) raster files.
3. Set the tile size (e.g., 600 or 1200 pixels).
4. Select a meteorological source (metfile, ERA5, or wrfout):
   • If metfile: Provide a .txt file.
   • If ERA5: Provide a folder with both instantaneous and accumulated files.
   • If wrfout: Provide a folder with WRF output NetCDF files.
5. Set the start and end times in UTC (YYYY-MM-DD HH:MM:SS).
6. Choose which outputs to generate (e.g., Tmrt, UTCI, radiation fluxes).
7. Output will be saved in Outputs/, with subfolders for each tile.

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Contributing

1. Fork the repository
2. Create a feature branch
3. Commit your changes
4. Push to the branch
5. Create a Pull Request

Please keep your pull requests small and focused. This will make it easier to review and merge.