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A part of HyRiver software stack for retrieving and post-processing climate data from the Daymet Webservice.

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Package Description
PyNHD Navigate and subset NHDPlus (MR and HR) using web services
Py3DEP Access topographic data through National Map's 3DEP web service
PyGeoHydro Access NWIS, NID, WQP, eHydro, NLCD, CAMELS, and SSEBop databases
PyDaymet Access daily, monthly, and annual climate data via Daymet
PyGridMET Access daily climate data via GridMET
PyNLDAS2 Access hourly NLDAS-2 data via web services
HydroSignatures A collection of tools for computing hydrological signatures
AsyncRetriever High-level API for asynchronous requests with persistent caching
PyGeoOGC Send queries to any ArcGIS RESTful-, WMS-, and WFS-based services
PyGeoUtils Utilities for manipulating geospatial, (Geo)JSON, and (Geo)TIFF data

PyDaymet: Daily climate data through Daymet

PyPi Conda Version CodeCov Python Versions Downloads

CodeFactor Ruff pre-commit Binder

Warning

Since the release of Daymet v4 R1 on November 2022, the URL of Daymet's server has been changed. Therefore, only PyDaymet v0.13.7+ is going to work, and previous versions will not work anymore.

Features

PyDaymet is a part of HyRiver software stack that is designed to aid in hydroclimate analysis through web services. This package provides access to climate data from Daymet V4 R1 database using NetCDF Subset Service (NCSS). Both single pixel (using get_bycoords function) and gridded data (using get_bygeom) are supported which are returned as pandas.DataFrame and xarray.Dataset, respectively. Climate data is available for North America, Hawaii from 1980, and Puerto Rico from 1950 at three time scales: daily, monthly, and annual. Additionally, PyDaymet can compute Potential EvapoTranspiration (PET) using three methods: penman_monteith, priestley_taylor, and hargreaves_samani for both single pixel and gridded data.

For PET computations, PyDaymet accepts four additional user-defined parameters:

  • penman_monteith: soil_heat_flux, albedo, alpha,
    and arid_correction.
  • priestley_taylor: soil_heat_flux, albedo, and arid_correction.
  • hargreaves_samani: None.

Default values for the parameters are: soil_heat_flux = 0, albedo = 0.23, alpha = 1.26, and arid_correction = False. An important parameter for priestley_taylor and penman_monteith methods is arid_correction which is used to correct the actual vapor pressure for arid regions. Since relative humidity is not provided by Daymet, the actual vapor pressure is computed assuming that the dew point temperature is equal to the minimum temperature. However, for arid regions, FAO 56 suggests subtracting minimum temperature by 2-3 °C to account for the fact that in arid regions, the air might not be saturated when its temperature is at its minimum. For such areas, you can pass {"arid_correction": True, ...} to subtract 2 °C from the minimum temperature for computing the actual vapor pressure.

You can find some example notebooks here.

Moreover, under the hood, PyDaymet uses PyGeoOGC and AsyncRetriever packages for making requests in parallel and storing responses in chunks. This improves the reliability and speed of data retrieval significantly.

You can control the request/response caching behavior and verbosity of the package by setting the following environment variables:

  • HYRIVER_CACHE_NAME: Path to the caching SQLite database for asynchronous HTTP requests. It defaults to ./cache/aiohttp_cache.sqlite
  • HYRIVER_CACHE_NAME_HTTP: Path to the caching SQLite database for HTTP requests. It defaults to ./cache/http_cache.sqlite
  • HYRIVER_CACHE_EXPIRE: Expiration time for cached requests in seconds. It defaults to one week.
  • HYRIVER_CACHE_DISABLE: Disable reading/writing from/to the cache. The default is false.
  • HYRIVER_SSL_CERT: Path to a SSL certificate file.

For example, in your code before making any requests you can do:

import os

os.environ["HYRIVER_CACHE_NAME"] = "path/to/aiohttp_cache.sqlite"
os.environ["HYRIVER_CACHE_NAME_HTTP"] = "path/to/http_cache.sqlite"
os.environ["HYRIVER_CACHE_EXPIRE"] = "3600"
os.environ["HYRIVER_CACHE_DISABLE"] = "true"
os.environ["HYRIVER_SSL_CERT"] = "path/to/cert.pem"

You can also try using PyDaymet without installing it on your system by clicking on the binder badge. A Jupyter Lab instance with the HyRiver stack pre-installed will be launched in your web browser, and you can start coding!

Moreover, requests for additional functionalities can be submitted via issue tracker.

Citation

If you use any of HyRiver packages in your research, we appreciate citations:

@article{Chegini_2021,
    author = {Chegini, Taher and Li, Hong-Yi and Leung, L. Ruby},
    doi = {10.21105/joss.03175},
    journal = {Journal of Open Source Software},
    month = {10},
    number = {66},
    pages = {1--3},
    title = {{HyRiver: Hydroclimate Data Retriever}},
    volume = {6},
    year = {2021}
}

Installation

You can install PyDaymet using pip after installing libgdal on your system (for example, in Ubuntu run sudo apt install libgdal-dev):

$ pip install pydaymet

Alternatively, PyDaymet can be installed from the conda-forge repository using Conda:

$ conda install -c conda-forge pydaymet

Quick start

You can use PyDaymet using command-line or as a Python library. The commanda-line provides access to two functionality:

  • Getting gridded climate data: You must create a geopandas.GeoDataFrame that contains the geometries of the target locations. This dataframe must have four columns: id, start, end, geometry. The id column is used as filenames for saving the obtained climate data to a NetCDF (.nc) file. The start and end columns are starting and ending dates of the target period. Then, you must save the dataframe as a shapefile (.shp) or geopackage (.gpkg) with CRS attribute.
  • Getting single pixel climate data: You must create a CSV file that contains coordinates of the target locations. This file must have at four columns: id, start, end, lon, and lat. The id column is used as filenames for saving the obtained climate data to a CSV (.csv) file. The start and end columns are the same as the geometry command. The lon and lat columns are the longitude and latitude coordinates of the target locations.
$ pydaymet -h
Usage: pydaymet [OPTIONS] COMMAND [ARGS]...

Command-line interface for PyDaymet.

Options:
-h, --help  Show this message and exit.

Commands:
coords    Retrieve climate data for a list of coordinates.
geometry  Retrieve climate data for a dataframe of geometries.

The coords sub-command is as follows:

$ pydaymet coords -h
Usage: pydaymet coords [OPTIONS] FPATH

Retrieve climate data for a list of coordinates.

FPATH: Path to a csv file with four columns:
    - ``id``: Feature identifiers that daymet uses as the output netcdf filenames.
    - ``start``: Start time.
    - ``end``: End time.
    - ``lon``: Longitude of the points of interest.
    - ``lat``: Latitude of the points of interest.
    - ``time_scale``: (optional) Time scale, either ``daily`` (default), ``monthly`` or ``annual``.
    - ``pet``: (optional) Method to compute PET. Supported methods are:
                ``penman_monteith``, ``hargreaves_samani``, ``priestley_taylor``, and ``none`` (default).
    - ``snow``: (optional) Separate snowfall from precipitation, default is ``False``.

Examples:
    $ cat coords.csv
    id,lon,lat,start,end,pet
    california,-122.2493328,37.8122894,2012-01-01,2014-12-31,hargreaves_samani
    $ pydaymet coords coords.csv -v prcp -v tmin

Options:
-v, --variables TEXT  Target variables. You can pass this flag multiple
                        times for multiple variables.
-s, --save_dir PATH   Path to a directory to save the requested files.
                        Extension for the outputs is .nc for geometry and .csv
                        for coords.
--disable_ssl         Pass to disable SSL certification verification.
-h, --help            Show this message and exit.

And, the geometry sub-command is as follows:

$ pydaymet geometry -h
Usage: pydaymet geometry [OPTIONS] FPATH

Retrieve climate data for a dataframe of geometries.

FPATH: Path to a shapefile (.shp) or geopackage (.gpkg) file.
This file must have four columns and contain a ``crs`` attribute:
    - ``id``: Feature identifiers that daymet uses as the output netcdf filenames.
    - ``start``: Start time.
    - ``end``: End time.
    - ``geometry``: Target geometries.
    - ``time_scale``: (optional) Time scale, either ``daily`` (default), ``monthly`` or ``annual``.
    - ``pet``: (optional) Method to compute PET. Supported methods are:
                ``penman_monteith``, ``hargreaves_samani``, ``priestley_taylor``, and ``none`` (default).
    - ``snow``: (optional) Separate snowfall from precipitation, default is ``False``.

Examples:
    $ pydaymet geometry geo.gpkg -v prcp -v tmin

Options:
-v, --variables TEXT  Target variables. You can pass this flag multiple
                        times for multiple variables.
-s, --save_dir PATH   Path to a directory to save the requested files.
                        Extension for the outputs is .nc for geometry and .csv
                        for coords.
--disable_ssl         Pass to disable SSL certification verification.
-h, --help            Show this message and exit.

Now, let's see how we can use PyDaymet as a library.

PyDaymet offers two functions for getting climate data; get_bycoords and get_bygeom. The arguments of these functions are identical except the first argument where the latter should be polygon and the former should be a coordinate (a tuple of length two as in (x, y)). The input geometry or coordinate can be in any valid CRS (defaults to EPSG:4326). The dates argument can be either a tuple of length two like (start_str, end_str) or a list of years like [2000, 2005]. It is noted that both functions have a pet flag for computing PET and a snow flag for separating snow from precipitation using Martinez and Gupta (2010) method. Additionally, we can pass time_scale to get daily, monthly or annual summaries. This flag by default is set to daily.

from pynhd import NLDI
import pydaymet as daymet

geometry = NLDI().get_basins("01031500").geometry[0]

var = ["prcp", "tmin"]
dates = ("2000-01-01", "2000-06-30")

daily = daymet.get_bygeom(geometry, dates, variables=var, pet="priestley_taylor", snow=True)
monthly = daymet.get_bygeom(geometry, dates, variables=var, time_scale="monthly")
https://raw.githubusercontent.com/hyriver/HyRiver-examples/main/notebooks/_static/daymet_grid.png

If the input geometry (or coordinate) is in a CRS other than EPSG:4326, we should pass it to the functions.

coords = (-1431147.7928, 318483.4618)
crs = 3542
dates = ("2000-01-01", "2006-12-31")
annual = daymet.get_bycoords(coords, dates, variables=var, loc_crs=crs, time_scale="annual")
https://raw.githubusercontent.com/hyriver/HyRiver-examples/main/notebooks/_static/daymet_loc.png

Additionally, the get_bycoords function accepts a list of coordinates and by setting the to_xarray flag to True it can return the results as a xarray.Dataset instead of a pandas.DataFrame:

coords = [(-94.986, 29.973), (-95.478, 30.134)]
idx = ["P1", "P2"]
clm_ds = daymet.get_bycoords(coords, range(2000, 2021), coords_id=idx, to_xarray=True)

Also, we can use the potential_et function to compute PET by passing the daily climate data. We can either pass a pandas.DataFrame or a xarray.Dataset. Note that, penman_monteith and priestley_taylor methods have parameters that can be passed via the params argument, if any value other than the default values are needed. For example, default value of alpha for priestley_taylor method is 1.26 (humid regions), we can set it to 1.74 (arid regions) as follows:

pet_hs = daymet.potential_et(daily, methods="priestley_taylor", params={"alpha": 1.74})

Next, let's get annual total precipitation for Hawaii and Puerto Rico for 2010.

hi_ext = (-160.3055, 17.9539, -154.7715, 23.5186)
pr_ext = (-67.9927, 16.8443, -64.1195, 19.9381)
hi = daymet.get_bygeom(hi_ext, 2010, variables="prcp", region="hi", time_scale="annual")
pr = daymet.get_bygeom(pr_ext, 2010, variables="prcp", region="pr", time_scale="annual")

Some example plots are shown below:

https://raw.githubusercontent.com/hyriver/HyRiver-examples/main/notebooks/_static/hi.png https://raw.githubusercontent.com/hyriver/HyRiver-examples/main/notebooks/_static/pr.png

Contributing

Contributions are very welcomed. Please read CONTRIBUTING.rst file for instructions.

Credits

Credits to Koen Hufkens for his implementation of accessing the Daymet RESTful service, daymetpy.

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A part of HyRiver software stack for retrieving and post-processing climate data from the Daymet Webservice.

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