Observations

This section will aid in how to use MONET to load observational datasets available.

First we will import several libraries to aid for in the future.

import numpy as np          # numpy
import pandas as pd         # pandas
from monet.obs import *     # observations from MONET
import matplotlib.pyplot as plt # plotting
import seaborn as sns       # better color palettes
import cartopy.crs as ccrs  # map projections
import cartopy.feature as cfeature # politcal and geographic features

AirNow

AirNow is the near realtime dataset for air composition and meteorology measurements.

“The U.S. EPA AirNow program is the national repository of real time air quality data and forecasts for the United States. AirNow is the vehicle for providing timely Air Quality Index (AQI) information to the public, media outlets, other federal agencies and their applications, and to the research community. The system is managed by the U.S. EPA’s Office of Air Quality Planning and Standards Outreach and Information Division, Information Transfer Group in Research Triangle Park (RTP), North Carolina. AirNow is currently hosted and operated at a contractor facility, known as the AirNow Data Management Center (DMC), which currently resides outside of RTP.” - https://www.airnow.gov/index.cfm?action=ani.airnowUS

AirNow data can be downloaded from the Amazon S3 server and aggregated using the monet.obs.airnow class. For example,lets say that we want to look at data from 2018-05-01 to 2018-05-05.

Now we need to set the dates. We want hourly data so lets set the hourly flag

dates = pd.date_range(start='2018-05-01', end='2018-05-05', freq='H')

Now a simple one stop command to return the pandas DataFrame of the aggregated data on the given dates. MONET reads the hourly data from AirNow.

df = airnow.add_data(dates)

This provides a structured DataFrame.

df.head()

Some users may want to keep a local copy of the data and not have to retrieve the data each time they want to access the data. There is a simple kwarg that can be used to download the data, download=True. By default, download is set to False.

df = airnow.add_data(dates,download=True)

This format may be less intuitive. It is the “long” ASCII format found in the files where each index is a single record with a single variable and value. This may be incovinient but there are a helper function in monet.utils.tools to assist in reshaping the pandas DataFrame so that it can be more convenient.

from monet.utils.tools import unstack
df2 = unstack(df2)
df2.head()

Available Measurements

  • O3 (OZONE)

  • PM2.5

  • PM10

  • SO2

  • NO2

  • CO

  • NO2

  • NOx

  • NO

  • Wind Speed and Direction (WS, WDIR)

  • Temperature (TEMP)

  • Relative Humidity (RH)

  • Solar Radiation (SRAD)

EPA AQS

MONET is able to use the EPA AQS data that is collected and reported on an hourly and daily time scale.

“The Air Quality System (AQS) contains ambient air pollution data collected by EPA, state, local, and tribal air pollution control agencies from over thousands of monitors. AQS also contains meteorological data, descriptive information about each monitoring station (including its geographic location and its operator), and data quality assurance/quality control information. AQS data is used to: assess air quality, evaluate State Implementation Plans for non-attainment areas, prepare reports for Congress as mandated by the Clean Air Act.” - https://www.epa.gov/aqs

We will begin by loading hourly ozone concentrations from 2018. The EPA AQS data is separated into yearly files and separate files for hourly and daily data. The files are also separated by which variable is measured. For instance, hourly ozone files for the entire year of 2018 are found in https://aqs.epa.gov/aqsweb/airdata/hourly_44201_2018.zip. We will first load a single variable and then add multiple later on.

#first determine the dates
dates = pd.date_range(start='2018-01-01', end='2018-12-31', freq='H')
# load the data
df = aqs.add_data(dates, param=['OZONE'])

If you would rather daily data to get the 8HR max ozone concentration or daily maximum concentration you can add the daily kwarg.

df = aqs.add_data(dates, param=['OZONE'], daily=True)

As in AirNow you can download the data to the local disk using the download

df = aqs.add_data(dates, param=['OZONE'], daily=True, download=True)

Available Measurements

  • O3 (OZONE)

  • PM2.5 (PM2.5)

  • PM2.5_frm (PM2.5)

  • PM10

  • SO2

  • NO2

  • CO

  • NONOxNOy

  • VOC

  • Speciated PM (SPEC)

  • Speciated PM10 (PM10SPEC)

  • Wind Speed and Direction (WIND, WS, WDIR)

  • Temperature (TEMP)

  • Relative Humidity and Dew Point Temperature (RHDP)

Loading Multiple Measurements

Let’s load variables PM10 and OZONE using hourly data to get an idea of how to get multiple variables:

df = aqs.add_data(dates, param=['OZONE','PM10'])

Loading Specific Network

Sometimes you may want to load a specific network that is available in the AQS data files. For instance, lets load data from the Chemical Speciation Network (CSN; https://www.epa.gov/amtic/chemical-speciation-network-csn). As of writing this tutorial we will load the 2017 data as it is complete.

dates = pd.date_range(start='2017-01-01', end='2018-01-01', freq='H')
df = aqs.add_data(dates,param=['SPEC'], network='CSN', daily=True )

Available Networks

AERONET

“The AERONET (AErosol RObotic NETwork) project is a federation of ground-based remote sensing aerosol networks established by NASA and PHOTONS (PHOtométrie pour le Traitement Opérationnel de Normalisation Satellitaire; Univ. of Lille 1, CNES, and CNRS-INSU) and is greatly expanded by networks (e.g., RIMA, AeroSpan, AEROCAN, and CARSNET) and collaborators from national agencies, institutes, universities, individual scientists, and partners. For more than 25 years, the project has provided long-term, continuous and readily accessible public domain database of aerosol optical, microphysical and radiative properties for aerosol research and characterization, validation of satellite retrievals, and synergism with other databases. The network imposes standardization of instruments, calibration, processing and distribution.

AERONET collaboration provides globally distributed observations of spectral aerosol optical depth (AOD), inversion products, and precipitable water in diverse aerosol regimes. Version 3 AOD data are computed for three data quality levels: Level 1.0 (unscreened), Level 1.5 (cloud-screened and quality controlled), and Level 2.0 (quality-assured). Inversions, precipitable water, and other AOD-dependent products are derived from these levels and may implement additional quality checks. ” -https://aeronet.gsfc.nasa.gov

MONET uses the AERONET web services to access data. All data products available through their web service portal is available in MONET except for the raw sky scans. This includes the AOD and SSA as well as the inversion products.

Available Measurements

AOD and SDA Measurements

Product

Explanation

AOD10

Aerosol Optical Depth Level 1.0

AOD15

Aerosol Optical Depth Level 1.5

AOD20

Aerosol Optical Depth Level 2.0

SDA10

SDA Retrieval Level 1.0

SDA15

SDA Retrieval Level 1.5

SDA20

SDA Retrieval Level 2.0

TOT10

Total Optical Depth based on AOD Level 1.0 (all points only)

TOT15

Total Optical Depth based on AOD Level 1.5 (all points only)

TOT20

Total Optical Depth based on AOD Level 2.0 (all points only)

Inversion Products

Product

Explanation

SIZ

Size distribution

RIN

Refractive indices (real and imaginary)

CAD

Coincident AOT data with almucantar retrieval

VOL

Volume concentration, volume mean radius, effective radius and standard deviation

TAB

AOT absorption

AOD

AOT extinction

SSA

Single scattering albedo

ASY

Asymmetry factor

FRC

Radiative Forcing

LID

Lidar and Depolarization Ratios

FLX

Spectral flux

ALL

All of the above retrievals (SIZ to FLUX) in one file

PFN*

Phase function (available for only all points data format: AVG=10)

Loading AOD and SDA

Aeronet is global data so we are going to look at a single day to speed this along. First we need to create a datetime array

dates = pd.date_range(start='2017-09-25',end='2017-09-26',freq='H')

Now lets assume that we want to read the Aerosol Optical Depth Level 1.5 data that is cloud-screened and quality controlled.

df = aeroent.add_data(dates=dates, product='AOD15')
df.head()

Now sometimes you want only data over a specific region. To do this lets define a latitude longitude box [latmin,lonmin,latmax,lonmax] over northern Africa

df = aeroent.add_data(dates=dates, product='AOD15', latlonbox=[2.,-21,38,37])
df[['latitude','longitude']].describe()

To download inversion products you must supply the inv_type kwarg. It accepts either “ALM15” or “ALM20” from the AERONET web services. Lets get the size distribution from data over northern Africa

df = aeroent.add_data(dates=dates, product='SIZ', latlonbox=[2.,-21,38,37], inv_type='ALM15')

NADP

NADP is a composed of five regional networks; NTN, AIRMoN, AMoN, AMNet, and MDN. MONET allows you to read data from any of the five networks with a single call by specifying the wanted network.

To add data from any of the networks it is a simple call using the nadp object. As an example, to load data from the NTN network the call would look like:

df = nadp.add_data(dates, network='NTN')

To read data from another network simply replace the network with the name of the wanted network. The network name must be a string but is case insensitive.

NTN

“The NTN is the only network providing a long-term record of precipitation chemistry across the United States.

Sites predominantly are located away from urban areas and point sources of pollution. Each site has a precipitation chemistry collector and gauge. The automated collector ensures that the sample is exposed only during precipitation (wet-only-sampling).” - https://nadp.slh.wisc.edu/NTN/

Available Measurements

  • H+ (ph)

  • Ca2+ (ca)

  • Mg2+ (mg)

  • Na+ (na)

  • K+ (k)

  • SO42- (so4)

  • NO3- (no3)

  • Cl- (cl)

  • NH4+ (nh4)

MDN

“The MDN is the only network providing a longterm record of total mercury (Hg) concentration and deposition in precipitation in the United States and Canada. All MDN sites follow standard procedures and have uniform precipitation chemistry collectors and gauges. The automated collector has the same basic design as the NTN collector but is modified to preserve mercury. Modifications include a glass funnel, connecting tube, bottle for collecting samples, and an insulated enclosure to house this sampling train. The funnel and connecting tube reduce sample exposure to the open atmosphere and limit loss of dissolved mercury. As an additional sample preservation measure, the collection bottle is charged with 20 mL of a one percent hydrochloric acid solution.” - https://nadp.slh.wisc.edu/MDN/

Available Measurements

  • net concentration of methyl mercury in ng/L (conc)

  • precipitation amount (in inches) reported by the rain gauge for the entire sampling period. (rain gauge)

  • Mg2+ (mg)

  • Na+ (na)

  • K+ (k)

  • SO42- (so4)

  • NO3- (no3)

  • Cl- (cl)

  • NH4+ (nh4)

IMPROVE

to do…

OpenAQ

to do…..

CEMS

to do…..

Climate Reference Network

to do…..

Integrated Surface Database

dates = [pd.Timestamp('2012-01-01'), pd.Timestamp('2012-12-31')]
area = [-105.0, -97, 44.5, 49.5]

Now a simple one stop command to return the pandas DataFrame of the data on the given dates. MONET reads the hourly data from the ISD LITE database.

from monet.obs import ish
df = ish.add_data(dates, country=None, box=area, resample=False)

Or you can create your own instance of the ISH class.

from monet.obs import ish_mod
metdata = ish_mod.ISH()
df = metdata.add_data(dates, country=None, box=area, resample=False)

To see what data is in the DataFrame simply output the column header values

print(df.columns.values)

Available Measurements

  • dew point (dpt)

  • temperature (t)

  • visibility (vsb)

  • wind speed (ws)

  • wind direction (wdir)

The ISD (ISH) database contains latitude, longitude, station name, station id, time, dew point (dpt), temperature (t), visibility (vsb), wind speed (ws), wind direction (wdir), as well as various quality flags.

ICARTT

MONET is capable of reading the NASA ICARTT data format (https://www-air.larc.nasa.gov/missions/etc/IcarttDataFormat.htm). Many field campaigns save data in ICARTT format. Methods are available to combine flight data.

from monet.obs import icartt

f = icartt.add_data('filename')

This will return a xarray.Dataset. If you would prefer a pandas.DataFrame you can use the icartt.get_data function. This will try to automatically rename a few columns like latitude and longitude and time from the data array and return a monet compatible pandas.DataFrame.

df = icartt.get_data(f)