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  4. Work With NEON's Plant Phenology Data

Tutorial

Work With NEON's Plant Phenology Data

Authors: Megan A. Jones, Natalie Robinson, Lee Stanish

Last Updated: Jun 30, 2026

Many organisms, including plants, show patterns of change across seasons - the different stages of this observable change are called phenophases. In this tutorial we explore how to work with NEON plant phenophase data.

Objectives

After completing this activity, you will be able to:

  • work with NEON Plant Phenology Observation data.
  • use dplyr functions to filter data.
  • plot time series data in a bar plot using ggplot the function.

Things You’ll Need To Complete This Tutorial

  • You will need a current version of R (4+) and, preferably, RStudio loaded on your computer to complete this tutorial.
  • Create a NEON user account
  • Generate an API token for downloading data

Install R Packages

  • neonUtilities: install.packages("neonUtilities")
  • neonOS install.packages("neonOS")
  • ggplot2: install.packages("ggplot2")
  • dplyr: install.packages("dplyr")

More on Packages in R – Adapted from Software Carpentry.


Additional Resources

  • NEON data portal
  • NEON Plant Phenology Observations data product user guide
  • RStudio's data wrangling (dplyr/tidyr) cheatsheet
  • NEONScience GitHub Organization
  • nneo API wrapper on CRAN

Plants change throughout the year - these are phenophases. Why do they change?

Explore Phenology Data

The following sections provide a brief overview of the NEON plant phenology observation data. When designing a research project using this data, you need to consult the documents associated with this data product and not rely solely on this summary.

The following description of the NEON Plant Phenology Observation data is modified from the data product user guide.

NEON Plant Phenology Observation Data

NEON collects plant phenology data and provides it as NEON data product DP1.10055.001.

The plant phenology observations data product provides in-situ observations of the phenological status and intensity of tagged plants (or patches) during discrete observations events.

Sampling occurs at all terrestrial field sites at site and season specific intervals. During Phase I (dominant species) sampling (pre-2021), three species with 30 individuals each are sampled. In 2021, Phase II (community) sampling will begin, with <=20 species with 5 or more individuals sampled will occur.

Status-based Monitoring

NEON employs status-based monitoring, in which the phenological condition of an individual is reported any time that individual is observed. At every observations bout, records are generated for every phenophase that is occurring and for every phenophase not occurring. With this approach, events (such as leaf emergence in Mediterranean zones, or flowering in many desert species) that may occur multiple times during a single year, can be captured. Continuous reporting of phenophase status enables quantification of the duration of phenophases rather than just their date of onset while allows enabling the explicit quantification of uncertainty in phenophase transition dates that are introduced by monitoring in discrete temporal bouts.

Specific products derived from this sampling include the observed phenophase status (whether or not a phenophase is occurring) and the intensity of phenophases for individuals in which phenophase status = ‘yes’. Phenophases reported are derived from the USA National Phenology Network (USA-NPN) categories. The number of phenophases observed varies by growth form and ranges from 1 phenophase (cactus) to 7 phenophases (semi-evergreen broadleaf). In this tutorial we will focus only on the state of the phenophase, not the phenophase intensity data.

Phenology Transects

Plant phenology observations occur at all terrestrial NEON sites along an 800 meter square loop transect (primary) and within a 200 m x 200 m plot located within view of a canopy level, tower-mounted, phenology camera.

Diagram of a phenology transect layout, with meter layout marked. Point-level geolocations are recorded at eight reference
	points along the perimeter; plot-level geolocation at the plot centroid(star).
Diagram of a phenology transect layout, with meter layout marked. Point-level geolocations are recorded at eight reference points along the perimeter, plot-level geolocation at the plot centroid (star). Source: National Ecological Observatory Network (NEON)

Timing of Observations

At each site, there are:

  • ~50 observation bouts per year.
  • no more that 100 sampling points per phenology transect.
  • no more than 9 sampling points per phenocam plot.
  • 1 annual measurement per year to collect annual size and disease status measurements from each sampling point.

Available Data Tables

The phenology dataset contains three data tables:

  • phe_statusintensity: Plant phenophase status and intensity data
  • phe_perindividual: Geolocation and taxonomic identification for phenology plants
  • phe_perindividualperyear: Pecorded once per year, essentially the "metadata" about the plant: DBH, height, etc.

There are other files in each download including a readme with information on the data product and the download; a variables file that defines the term descriptions, data types, and units; a validation file with data entry validation and parsing rules; and a citation file giving the BibTeX citation for the downloaded data.

Set up R environment

This tutorial is designed to have you download data from the NEON API using the neonUtilities package. As of June 2026, NEON requires an API token for data downloads, to reduce bot scraping and improve user support. Tokens can be generated in NEON data portal user accounts - log in to your account or create one, and go to the API Tokens section. For best practices in storing and using tokens, follow the instructions here.

Install and load packages, and load your token. This code assumes you have stored your token as an environment variable, as described at the link above. If your token is stored in a different way, modify the line of code below as needed.

# install needed package (only uncomment & run if not already installed)

#install.packages("neonUtilities")

#install.packages("dplyr")

#install.packages("ggplot2")



# load needed packages

library(neonUtilities)

library(neonOS)

library(dplyr)

library(ggplot2)

token <- Sys.getenv("NEON_TOKEN")



# set working directory to ensure R can find the file we wish to import and where

# we want to save our files. Be sure to move the download into your working directory!

wd <- "~/data" # Change this to match your local environment

setwd(wd)

Let's start by loading our data of interest. For this series, we'll work with data from the NEON Domain 02 sites:

  • Blandy Farm (BLAN)
  • Smithsonian Conservation Biology Institute (SCBI)
  • Smithsonian Environmental Research Center (SERC)

And we'll use data from January 2017 to December 2019. This downloads over 9MB of data. If this is too large, use a smaller date range. If you opt to do this, your figures and some output may look different later in the tutorial.

With this information, we can download our data using the neonUtilities package.

phe <- loadByProduct(dpID = "DP1.10055.001", 
                     site=c("BLAN","SCBI","SERC"), 
										 startdate = "2017-01", 
										 enddate="2019-12", 
										 release="RELEASE-2026",
										 token=token,
										 check.size = F) 



# save dataframes from the downloaded list

ind <- phe$phe_perindividual  #individual information

status <- phe$phe_statusintensity  #status & intensity info

Let's explore the data. Let's get to know what the ind dataframe looks like.

# What are the fieldnames in this dataset?

names(ind)

##  [1] "uid"                         "namedLocation"               "domainID"                    "siteID"                     
##  [5] "plotID"                      "decimalLatitude"             "decimalLongitude"            "geodeticDatum"              
##  [9] "coordinateUncertainty"       "elevation"                   "elevationUncertainty"        "subtypeSpecification"       
## [13] "transectMeter"               "directionFromTransect"       "ninetyDegreeDistance"        "sampleLatitude"             
## [17] "sampleLongitude"             "sampleCoordinateUncertainty" "sampleElevation"             "sampleElevationUncertainty" 
## [21] "date"                        "editedDate"                  "individualID"                "taxonID"                    
## [25] "scientificName"              "identificationQualifier"     "taxonRank"                   "nativeStatusCode"           
## [29] "identificationHistoryID"     "growthForm"                  "vstTag"                      "measuredBy"                 
## [33] "identifiedBy"                "recordedBy"                  "remarks"                     "dataQF"                     
## [37] "publicationDate"             "release"

# Unsure of what some of the variables are? Look at the variables table!

View(phe$variables_10055)



# how many rows are in the data?

nrow(ind)

## [1] 791

# look at the first six rows of data.

head(ind)

##                                    uid          namedLocation domainID siteID   plotID decimalLatitude decimalLongitude
## 1 c1949cda-a607-4f9c-b866-3c77c1c47856 BLAN_061.phenology.phe      D02   BLAN BLAN_061        39.05963        -78.07385
## 2 4871339b-5815-43e1-b0ee-2f0491b28be7 BLAN_061.phenology.phe      D02   BLAN BLAN_061        39.05963        -78.07385
## 3 9f170c36-214b-49e9-9571-84475b10c37a BLAN_061.phenology.phe      D02   BLAN BLAN_061        39.05963        -78.07385
## 4 2c8bb258-91f3-444b-85e0-6a589bd5fb6a BLAN_061.phenology.phe      D02   BLAN BLAN_061        39.05963        -78.07385
## 5 76afbf22-34f0-4e73-979a-4daeac316ab3 BLAN_061.phenology.phe      D02   BLAN BLAN_061        39.05963        -78.07385
## 6 fc3cfb08-d6df-4112-ae08-6f2ad3544cd2 BLAN_061.phenology.phe      D02   BLAN BLAN_061        39.05963        -78.07385
##   geodeticDatum coordinateUncertainty elevation elevationUncertainty subtypeSpecification transectMeter
## 1         WGS84                    NA       183                   NA              primary           491
## 2         WGS84                    NA       183                   NA              primary           139
## 3         WGS84                    NA       183                   NA              primary           575
## 4         WGS84                    NA       183                   NA              primary           501
## 5         WGS84                    NA       183                   NA              primary           632
## 6         WGS84                    NA       183                   NA              primary           657
##   directionFromTransect ninetyDegreeDistance sampleLatitude sampleLongitude sampleCoordinateUncertainty sampleElevation
## 1                  Left                  0.5             NA              NA                          NA              NA
## 2                  Left                  2.0             NA              NA                          NA              NA
## 3                 Right                  2.0             NA              NA                          NA              NA
## 4                 Right                  3.0             NA              NA                          NA              NA
## 5                  Left                  3.0             NA              NA                          NA              NA
## 6                  Left                  2.0             NA              NA                          NA              NA
##   sampleElevationUncertainty       date editedDate            individualID taxonID         scientificName
## 1                         NA 2016-04-20 2016-05-09 NEON.PLA.D02.BLAN.06290    RHDA Rhamnus davurica Pall.
## 2                         NA 2017-02-24 2021-07-13 NEON.PLA.D02.BLAN.06231    RHDA Rhamnus davurica Pall.
## 3                         NA 2017-02-24 2021-07-13 NEON.PLA.D02.BLAN.06208    RHDA Rhamnus davurica Pall.
## 4                         NA 2017-02-24 2021-07-13 NEON.PLA.D02.BLAN.06503   SOAL6  Solidago altissima L.
## 5                         NA 2017-02-24 2021-07-13 NEON.PLA.D02.BLAN.06508   SOAL6  Solidago altissima L.
## 6                         NA 2017-02-24 2021-07-13 NEON.PLA.D02.BLAN.06214    RHDA Rhamnus davurica Pall.
##   identificationQualifier taxonRank nativeStatusCode identificationHistoryID          growthForm vstTag
## 1                    <NA>   species                I                    <NA> Deciduous broadleaf      N
## 2                    <NA>   species                I                    <NA> Deciduous broadleaf      N
## 3                    <NA>   species                I                    <NA> Deciduous broadleaf      N
## 4                    <NA>   species                N                    <NA>                Forb      N
## 5                    <NA>   species                N                    <NA>                Forb      N
## 6                    <NA>   species                I                    <NA> Deciduous broadleaf      N
##                     measuredBy          identifiedBy           recordedBy
## 1          jcoloso@neoninc.org  shackley@neoninc.org shackley@neoninc.org
## 2 mastersb@battelleecology.org llemmon@field-ops.org                 <NA>
## 3 mastersb@battelleecology.org llemmon@field-ops.org                 <NA>
## 4 mastersb@battelleecology.org llemmon@field-ops.org                 <NA>
## 5 mastersb@battelleecology.org llemmon@field-ops.org                 <NA>
## 6 mastersb@battelleecology.org llemmon@field-ops.org                 <NA>
##                                                                remarks dataQF  publicationDate      release
## 1                                               Nearly dead shaded out   <NA> 20251222T234455Z RELEASE-2026
## 2                                                                 <NA>   <NA> 20251222T234455Z RELEASE-2026
## 3                                                                 <NA>   <NA> 20251222T234455Z RELEASE-2026
## 4 Dropped 20190717 no individuals present had been small and unhealthy   <NA> 20251222T234455Z RELEASE-2026
## 5                                                                 <NA>   <NA> 20251222T234455Z RELEASE-2026
## 6                                                                 <NA>   <NA> 20251222T234455Z RELEASE-2026

# look at the structure of the dataframe.

str(ind)

## 'data.frame':	791 obs. of  38 variables:
##  $ uid                        : chr  "c1949cda-a607-4f9c-b866-3c77c1c47856" "4871339b-5815-43e1-b0ee-2f0491b28be7" "9f170c36-214b-49e9-9571-84475b10c37a" "2c8bb258-91f3-444b-85e0-6a589bd5fb6a" ...
##  $ namedLocation              : chr  "BLAN_061.phenology.phe" "BLAN_061.phenology.phe" "BLAN_061.phenology.phe" "BLAN_061.phenology.phe" ...
##  $ domainID                   : chr  "D02" "D02" "D02" "D02" ...
##  $ siteID                     : chr  "BLAN" "BLAN" "BLAN" "BLAN" ...
##  $ plotID                     : chr  "BLAN_061" "BLAN_061" "BLAN_061" "BLAN_061" ...
##  $ decimalLatitude            : num  39.1 39.1 39.1 39.1 39.1 ...
##  $ decimalLongitude           : num  -78.1 -78.1 -78.1 -78.1 -78.1 ...
##  $ geodeticDatum              : chr  "WGS84" "WGS84" "WGS84" "WGS84" ...
##  $ coordinateUncertainty      : num  NA NA NA NA NA NA NA NA NA NA ...
##  $ elevation                  : num  183 183 183 183 183 183 183 183 183 183 ...
##  $ elevationUncertainty       : num  NA NA NA NA NA NA NA NA NA NA ...
##  $ subtypeSpecification       : chr  "primary" "primary" "primary" "primary" ...
##  $ transectMeter              : num  491 139 575 501 632 657 336 680 753 38 ...
##  $ directionFromTransect      : chr  "Left" "Left" "Right" "Right" ...
##  $ ninetyDegreeDistance       : num  0.5 2 2 3 3 2 6 5 2 2 ...
##  $ sampleLatitude             : num  NA NA NA NA NA NA NA NA NA NA ...
##  $ sampleLongitude            : num  NA NA NA NA NA NA NA NA NA NA ...
##  $ sampleCoordinateUncertainty: num  NA NA NA NA NA NA NA NA NA NA ...
##  $ sampleElevation            : num  NA NA NA NA NA NA NA NA NA NA ...
##  $ sampleElevationUncertainty : num  NA NA NA NA NA NA NA NA NA NA ...
##  $ date                       : Date, format: "2016-04-20" "2017-02-24" "2017-02-24" "2017-02-24" ...
##  $ editedDate                 : Date, format: "2016-05-09" "2021-07-13" "2021-07-13" "2021-07-13" ...
##  $ individualID               : chr  "NEON.PLA.D02.BLAN.06290" "NEON.PLA.D02.BLAN.06231" "NEON.PLA.D02.BLAN.06208" "NEON.PLA.D02.BLAN.06503" ...
##  $ taxonID                    : chr  "RHDA" "RHDA" "RHDA" "SOAL6" ...
##  $ scientificName             : chr  "Rhamnus davurica Pall." "Rhamnus davurica Pall." "Rhamnus davurica Pall." "Solidago altissima L." ...
##  $ identificationQualifier    : chr  NA NA NA NA ...
##  $ taxonRank                  : chr  "species" "species" "species" "species" ...
##  $ nativeStatusCode           : chr  "I" "I" "I" "N" ...
##  $ identificationHistoryID    : chr  NA NA NA NA ...
##  $ growthForm                 : chr  "Deciduous broadleaf" "Deciduous broadleaf" "Deciduous broadleaf" "Forb" ...
##  $ vstTag                     : chr  "N" "N" "N" "N" ...
##  $ measuredBy                 : chr  "jcoloso@neoninc.org" "mastersb@battelleecology.org" "mastersb@battelleecology.org" "mastersb@battelleecology.org" ...
##  $ identifiedBy               : chr  "shackley@neoninc.org" "llemmon@field-ops.org" "llemmon@field-ops.org" "llemmon@field-ops.org" ...
##  $ recordedBy                 : chr  "shackley@neoninc.org" NA NA NA ...
##  $ remarks                    : chr  "Nearly dead shaded out" NA NA "Dropped 20190717 no individuals present had been small and unhealthy" ...
##  $ dataQF                     : chr  NA NA NA NA ...
##  $ publicationDate            : chr  "20251222T234455Z" "20251222T234455Z" "20251222T234455Z" "20251222T234455Z" ...
##  $ release                    : chr  "RELEASE-2026" "RELEASE-2026" "RELEASE-2026" "RELEASE-2026" ...

Notice that the neonUtilities package read the data type from the variables file and then automatically converts the data to the correct date type in R.

Phenology status

Now let's look at the status data.

# What variables are included in this dataset?

names(status)

##  [1] "uid"                           "namedLocation"                 "domainID"                     
##  [4] "siteID"                        "plotID"                        "date"                         
##  [7] "editedDate"                    "dayOfYear"                     "eventID"                      
## [10] "individualID"                  "phenophaseName"                "phenophaseStatus"             
## [13] "phenophaseIntensityDefinition" "phenophaseIntensity"           "samplingProtocolVersion"      
## [16] "measuredBy"                    "recordedBy"                    "remarks"                      
## [19] "dataEntryRecordID"             "dataQF"                        "publicationDate"              
## [22] "release"

nrow(status)

## [1] 219327

head(status)

##                                    uid          namedLocation domainID siteID   plotID       date editedDate dayOfYear
## 1 25367e54-14e2-4d60-add6-57e9232a4b4a BLAN_061.phenology.phe      D02   BLAN BLAN_061 2017-02-24 2017-03-31        55
## 2 95dc8be6-a8e7-44f6-a510-3d7024794fa5 BLAN_061.phenology.phe      D02   BLAN BLAN_061 2017-02-24 2017-03-31        55
## 3 29994dd9-6bf7-4fe5-9420-03fbdc9c6d35 BLAN_061.phenology.phe      D02   BLAN BLAN_061 2017-02-24 2017-03-31        55
## 4 03514dba-fa81-4734-b39c-3deacb4bece2 BLAN_061.phenology.phe      D02   BLAN BLAN_061 2017-02-24 2017-03-31        55
## 5 e93412c3-ec6d-4608-9a71-33e8cae7ac66 BLAN_061.phenology.phe      D02   BLAN BLAN_061 2017-02-24 2017-03-31        55
## 6 8d2ec4e2-58a1-4ec0-93ae-6544a5f877de BLAN_061.phenology.phe      D02   BLAN BLAN_061 2017-02-24 2017-03-31        55
##   eventID            individualID       phenophaseName phenophaseStatus phenophaseIntensityDefinition phenophaseIntensity
## 1    <NA> NEON.PLA.D02.BLAN.06238 Increasing leaf size               no                          <NA>                <NA>
## 2    <NA> NEON.PLA.D02.BLAN.06229       Colored leaves               no                          <NA>                <NA>
## 3    <NA> NEON.PLA.D02.BLAN.06221   Breaking leaf buds               no                          <NA>                <NA>
## 4    <NA> NEON.PLA.D02.BLAN.06212               Leaves               no                          <NA>                <NA>
## 5    <NA> NEON.PLA.D02.BLAN.06514       Initial growth               no                          <NA>                <NA>
## 6    <NA> NEON.PLA.D02.BLAN.06245   Breaking leaf buds               no                          <NA>                <NA>
##   samplingProtocolVersion          measuredBy          recordedBy remarks dataEntryRecordID     dataQF  publicationDate
## 1                    <NA> llemmon@neoninc.org llemmon@neoninc.org    <NA>              <NA> legacyData 20251222T234455Z
## 2                    <NA> llemmon@neoninc.org llemmon@neoninc.org    <NA>              <NA> legacyData 20251222T234455Z
## 3                    <NA> llemmon@neoninc.org llemmon@neoninc.org    <NA>              <NA> legacyData 20251222T234455Z
## 4                    <NA> llemmon@neoninc.org llemmon@neoninc.org    <NA>              <NA> legacyData 20251222T234455Z
## 5                    <NA> llemmon@neoninc.org llemmon@neoninc.org    <NA>              <NA> legacyData 20251222T234455Z
## 6                    <NA> llemmon@neoninc.org llemmon@neoninc.org    <NA>              <NA> legacyData 20251222T234455Z
##        release
## 1 RELEASE-2026
## 2 RELEASE-2026
## 3 RELEASE-2026
## 4 RELEASE-2026
## 5 RELEASE-2026
## 6 RELEASE-2026

str(status)

## 'data.frame':	219327 obs. of  22 variables:
##  $ uid                          : chr  "25367e54-14e2-4d60-add6-57e9232a4b4a" "95dc8be6-a8e7-44f6-a510-3d7024794fa5" "29994dd9-6bf7-4fe5-9420-03fbdc9c6d35" "03514dba-fa81-4734-b39c-3deacb4bece2" ...
##  $ namedLocation                : chr  "BLAN_061.phenology.phe" "BLAN_061.phenology.phe" "BLAN_061.phenology.phe" "BLAN_061.phenology.phe" ...
##  $ domainID                     : chr  "D02" "D02" "D02" "D02" ...
##  $ siteID                       : chr  "BLAN" "BLAN" "BLAN" "BLAN" ...
##  $ plotID                       : chr  "BLAN_061" "BLAN_061" "BLAN_061" "BLAN_061" ...
##  $ date                         : Date, format: "2017-02-24" "2017-02-24" "2017-02-24" "2017-02-24" ...
##  $ editedDate                   : Date, format: "2017-03-31" "2017-03-31" "2017-03-31" "2017-03-31" ...
##  $ dayOfYear                    : int  55 55 55 55 55 55 55 55 55 55 ...
##  $ eventID                      : chr  NA NA NA NA ...
##  $ individualID                 : chr  "NEON.PLA.D02.BLAN.06238" "NEON.PLA.D02.BLAN.06229" "NEON.PLA.D02.BLAN.06221" "NEON.PLA.D02.BLAN.06212" ...
##  $ phenophaseName               : chr  "Increasing leaf size" "Colored leaves" "Breaking leaf buds" "Leaves" ...
##  $ phenophaseStatus             : chr  "no" "no" "no" "no" ...
##  $ phenophaseIntensityDefinition: chr  NA NA NA NA ...
##  $ phenophaseIntensity          : chr  NA NA NA NA ...
##  $ samplingProtocolVersion      : chr  NA NA NA NA ...
##  $ measuredBy                   : chr  "llemmon@neoninc.org" "llemmon@neoninc.org" "llemmon@neoninc.org" "llemmon@neoninc.org" ...
##  $ recordedBy                   : chr  "llemmon@neoninc.org" "llemmon@neoninc.org" "llemmon@neoninc.org" "llemmon@neoninc.org" ...
##  $ remarks                      : chr  NA NA NA NA ...
##  $ dataEntryRecordID            : chr  NA NA NA NA ...
##  $ dataQF                       : chr  "legacyData" "legacyData" "legacyData" "legacyData" ...
##  $ publicationDate              : chr  "20251222T234455Z" "20251222T234455Z" "20251222T234455Z" "20251222T234455Z" ...
##  $ release                      : chr  "RELEASE-2026" "RELEASE-2026" "RELEASE-2026" "RELEASE-2026" ...

# date range

min(status$date)

## [1] "2017-02-24"

max(status$date)

## [1] "2019-12-12"

Data cleanup and transformation

  • Check for duplicates
  • Retain only the most recent editedDate in each table
  • Join tables

Check for duplicates

NEON data are quality-controlled on data entry and ingest to the database, but one of the most common data entry errors is duplicate entry. The neonOS package contains a function, removeDups(), that uses metadata from the variables file to check for duplicate records and resolve them if possible. Of course NEON also uses these tools internally; if you detect duplicates in data in one Release, they may be resolved in the next Release.

Let's check both tables for duplicates.

ind_noD <- removeDups(ind, 
                      variables=phe$variables_10055,
                      table="phe_perindividual")

## No duplicated key values found!

status_noD <- removeDups(status,
                         variables=phe$variables_10055,
                         table="phe_statusintensity")

## 1761 duplicated key values found, representing 3522 non-unique records. Attempting to resolve.

## 833 resolveable duplicates merged into matching records
## 833 resolved records flagged with duplicateRecordQF=1

## 1856 unresolveable duplicates flagged with duplicateRecordQF=2

There are no duplicates in the perindividual table, but there are 3522 duplicate records (out of 219327 total records) in the statusintensity table. Inspecting the records, the majority are commissioning tests, when two people recorded each phenophase to check for agreement. removeDups() has resolved each pair to a single record when the phenophase data matched, and left as duplicates when the data didn't match.

Filter to last editedDate

The individual (ind) table contains all instances that any of the location or taxonomy data of an individual was updated. Therefore there are many rows for some individuals. We only want the latest editedDate in the ind table.

ind_last <- ind_noD %>%
	group_by(individualID) %>%
	filter(editedDate==max(editedDate))

In this case no rows were removed from the table; NEON staff have already resolved the data to the most recent editedDate. It is always good to check for this, but it is more likely to come up in Provisional data.

Prepare to join: Variable overlap between tables

From the initial inspection of the data we can see there is overlap in variable names between the fields.

Let's see what they are.

intersect(names(status_noD), 
          names(ind_last))

##  [1] "uid"               "namedLocation"     "domainID"          "siteID"            "plotID"            "date"             
##  [7] "editedDate"        "individualID"      "measuredBy"        "recordedBy"        "remarks"           "dataQF"           
## [13] "publicationDate"   "release"           "duplicateRecordQF"

There are several fields that overlap between the datasets. Some of these are expected to be the same and will be what we join on.

However, some of these will have different values in each table. We want to keep those distinct value and not join on them. Therefore, we rename these fields before joining:

  • uid
  • date
  • editedDate
  • measuredBy
  • recordedBy
  • samplingProtocolVersion
  • remarks
  • dataQF
  • publicationDate

We'll rename all the variables in the status object to have "Stat" at the end of the variable name.

status_noD <- status_noD %>%
  rename(uidStat=uid, dateStat=date, 
         editedDateStat=editedDate, 
         measuredByStat=measuredBy, 
         recordedByStat=recordedBy, 
         samplingProtocolVersionStat=samplingProtocolVersion, 
         remarksStat=remarks, 
         dataQFStat=dataQF, 
         publicationDateStat=publicationDate)

Join Dataframes

Now we can join the two data frames on all the variables with the same name. We use a left_join() from the dpylr package because we want to match all the rows from the "left" (status) dataframe to any rows that also occur in the "right" (individual) dataframe.

Check out RStudio's data wrangling (dplyr/tidyr) cheatsheet for other types of joins.

phe_ind <- left_join(status_noD, 
                     ind_last)

## Joining with `by = join_by(namedLocation, domainID, siteID, plotID, individualID, release, duplicateRecordQF)`

In some cases, the steps above result in date fields being converted to string. Check, and convert back to dates if necessary.

if(class(phe_ind$date)=="character") {
  phe_ind$date <- as.POSIXct(phe_ind$date,
                             format="%Y-%m-%d",
                             tz="GMT")
}



if(class(phe_ind$dateStat)=="character") {
  phe_ind$dateStat <- as.POSIXct(phe_ind$dateStat,
                             format="%Y-%m-%d",
                             tz="GMT")
}

Now that we have a clean, joined dataset we can begin to explore our research question: do plants show patterns of changes in phenophase across season?

Patterns in phenophase

From our larger dataset (several sites, species, phenophases), let's create a dataframe with only the data from a single site, species, and phenophase and call it phe_1sp.

Select site(s) of interest

To do this, we'll first select our site of interest. Note how we set this up with an object that is our site of interest. This will allow us to more easily change which site or sites if we want to adapt our code later.

siteOfInterest <- "SCBI"



## using %in% allows one to add a vector if you want more than one site. 

## could also do it with == but won't work with vectors



phe_1st <- phe_ind %>% 
  filter(siteID %in% siteOfInterest)

Select species of interest

Now we may only want to view a single species or a set of species. Let's first look at the species that are present in our data. We could do this just by looking at the taxonID field which give the four letter UDSA plant code for each species. But if we don't know all the plant codes, we can get a bit fancier and view both the taxonID and scientificName.

unique(phe_1st$taxonID)

## [1] "JUNI" "LITU" "MIVI" NA

unique(paste(phe_1st$taxonID, 
             phe_1st$scientificName, 
             sep=' - ')) 

## [1] "JUNI - Juglans nigra L."                       "LITU - Liriodendron tulipifera L."            
## [3] "MIVI - Microstegium vimineum (Trin.) A. Camus" "NA - NA"

For now, let's choose only the flowering tree Liriodendron tulipifera (LITU). By writing it this way, we could also add a list of species to the speciesOfInterest object to select for multiple species.

speciesOfInterest <- "LITU"



phe_1sp <- phe_1st %>%
  filter(taxonID==speciesOfInterest)



# check that it worked

unique(phe_1sp$taxonID)

## [1] "LITU"

Select phenophase of interest

And, perhaps a single phenophase.

# see which phenophases are present

unique(phe_1sp$phenophaseName)

## [1] "Increasing leaf size" "Leaves"               "Colored leaves"       "Open flowers"         "Falling leaves"      
## [6] "Breaking leaf buds"

phenophaseOfInterest <- "Leaves"



# subset to just the phenophase of interest 

phe_1sp <- phe_1sp %>%
  filter(phenophaseName %in% phenophaseOfInterest)



# check that it worked

unique(phe_1sp$phenophaseName)

## [1] "Leaves"

Select only primary plots

NEON plant phenology observations are collected in two types of plots.

  • Primary plots: an 800 meter square phenology loop transect
  • Phenocam plots: a 200 m x 200 m plot located within view of a canopy level, tower-mounted, phenology camera

In the data, these plots are differentiated by the subtypeSpecification. Depending on your question you may want to use only one or both of these plot types. For this activity, we're going to only look at the primary plots.

**Data Tip:** How do I learn this on my own? Read the Data Product User Guide and use the variables files with the data download to find the corresponding variables names.
# what plots are present?

unique(phe_1sp$subtypeSpecification)

## [1] "primary"  "phenocam"

# filter

phe_1spPrimary <- phe_1sp %>%
  filter(subtypeSpecification == 'primary')



# check that it worked

unique(phe_1spPrimary$subtypeSpecification)

## [1] "primary"

Total in phenophase of interest

The phenophaseState is recorded as "yes" or "no" that the individual is in that phenophase. The phenophaseIntensity are categories for how much of the individual is in that state. For now, we will stick with phenophaseState.

We can now calculate the total number of individuals in that state. We use n_distinct(indvidualID) to count the individuals (and not the records) in case there are duplicate records for an individual.

But later on we'll also want to calculate the percent of the observed individuals in the "leaves" status, therefore, we're also adding in a step here to retain the sample size so that we can calculate % later.

sampSize <- phe_1spPrimary %>%
  group_by(dateStat) %>%
  summarise(numInd=n_distinct(individualID))



inStat <- phe_1spPrimary %>%
  group_by(dateStat, phenophaseStatus) %>%
  summarise(countYes=n_distinct(individualID))

## `summarise()` has regrouped the output.
## ℹ Summaries were computed grouped by dateStat and phenophaseStatus.
## ℹ Output is grouped by dateStat.
## ℹ Use `summarise(.groups = "drop_last")` to silence this message.
## ℹ Use `summarise(.by = c(dateStat, phenophaseStatus))` for per-operation grouping (`?dplyr::dplyr_by`) instead.

inStat <- full_join(sampSize, 
                    inStat, 
                    by="dateStat")



# Retain only Yes

inStat_T <- inStat %>% 
  filter(phenophaseStatus %in% "yes")



# check that it worked

unique(inStat_T$phenophaseStatus)

## [1] "yes"

Now that we have the data we can plot it.

Plot with ggplot

**Data Tip:** For a detailed introduction to using `ggplot()`, visit *Time Series 05: Plot Time Series with ggplot2 in R* tutorial.

The default setting for a ggplot bar plot - geom_bar() - is a histogram designated by stat="bin". However, in this case, we want to plot count values. We can use geom_bar(stat="identity") to force ggplot to plot actual values.

# plot number of individuals in leaf

phenoPlot <- ggplot(inStat_T, 
                    aes(dateStat, countYes)) +
    geom_bar(stat="identity", na.rm = TRUE) 



phenoPlot

Bar plot showing the count of Liriodendrum tulipifera (LITU) individuals from January 2017 through December 2019 at the Smithsonian Conservation Biology Institute (SCBI). Counts represent individuals that were recorded as a 'yes' for the phenophase of interest,'Leaves', and were from the primary plots.

# Now let's make the plot look a bit more presentable

phenoPlot <- ggplot(inStat_T, 
                    aes(dateStat, countYes)) +
    geom_bar(stat="identity", na.rm = TRUE) +
    ggtitle("Total Individuals in Leaf") +
    xlab("Date") + ylab("Number of Individuals") +
    theme(plot.title = element_text(lineheight=.8, 
                                    face="bold", 
                                    size = 20)) +
    theme(text = element_text(size=18))



phenoPlot

Bar plot showing the count of Liriodendrum tulipifera (LITU) individuals from January 2017 through December 2019 at the Smithsonian Conservation Biology Institute (SCBI). Counts represent individuals that were recorded as a 'yes' for the phenophase of interest,'Leaves', and were from the primary plots. Axis labels and title have been added to make the graph more presentable.

We could also covert this to percentage and plot that.

# convert to percent

inStat_T$percent <- ((inStat_T$countYes)/
                       inStat_T$numInd)*100



# plot percent of leaves

phenoPlot_P <- ggplot(inStat_T, 
                      aes(dateStat, percent)) +
    geom_bar(stat="identity", na.rm = TRUE) +
    ggtitle("Proportion in Leaf") +
    xlab("Date") + ylab("% of Individuals") +
    theme(plot.title = element_text(lineheight=.8, 
                                    face="bold", 
                                    size = 20)) +
    theme(text = element_text(size=18))



phenoPlot_P

It might also be useful to visualize the data in different ways while exploring the data. As such, before plotting, we can convert our count data into a percentage by writting an expression that divides the number of individuals with a 'yes' for the phenophase of interest, 'Leaves', by the total number of individuals and then multiplies the result by 100. Using this newly generated dataset of percentages, we can plot the data similarly to how we did in the previous plot. Only this time, the y-axis range goes from 0 to 100 to reflect the percentage data we just generated. The resulting plot now shows a bar plot of the proportion of Liriodendrum tulipifera (LITU) individuals from January 2017 through December 2019 at the Smithsonian Conservation Biology Institute (SCBI). The y-axis represents the percent of individuals that were recorded as a 'yes' for the phenophase of interest,'Leaves', and were from the primary plots.

The plots demonstrate the nice expected pattern of increasing leaf-out, peak, and drop-off.

Drivers of phenology

Now that we see that there are differences in and shifts in phenophases, what are the drivers of phenophases?

The NEON phenology measurements track sensitive and easily observed indicators of biotic responses to meteorological variability by monitoring the timing and duration of phenological stages in plant communities. Plant phenology is affected by forces such as temperature, timing and duration of pest infestations and disease outbreaks, water fluxes, nutrient budgets, carbon dynamics, and food availability and has feedbacks to trophic interactions, carbon sequestration, community composition and ecosystem function. (quoted from Plant Phenology Observations user guide.)

Filter by date

In the next part of this series, we will be exploring temperature as a driver of phenology. Temperature data are quite large (NEON provides this in 1 minute or 30 minute intervals) so let's trim our phenology date down to only one year so that we aren't working with as large a dataset.

Let's filter to just 2018 data.

# use filter to select only the date of interest 

phe_1sp_2018 <- inStat_T %>% 
  filter(dateStat >= "2018-01-01" & 
           dateStat <= "2018-12-31")



# did it work?

range(phe_1sp_2018$dateStat)

## [1] "2018-04-13 GMT" "2018-11-20 GMT"

How does that look?

# Now let's make the plot look a bit more presentable

phenoPlot18 <- ggplot(phe_1sp_2018, 
                      aes(dateStat, countYes)) +
    geom_bar(stat="identity", na.rm = TRUE) +
    ggtitle("Total Individuals in Leaf") +
    xlab("Date") + ylab("Number of Individuals") +
    theme(plot.title = element_text(lineheight=.8, 
                                    face="bold", 
                                    size = 20)) +
    theme(text = element_text(size=18))



phenoPlot18

In the previous step, we filtered our data by date to only include data from 2018. Reviewing the newly generated dataset we get a bar plot showing the count of Liriodendrum tulipifera (LITU) individuals at the Smithsonian Conservation Biology Institute (SCBI) for the year 2018. Counts represent individuals that were recorded as a 'yes' for the phenophase of interest,'Leaves', and were from the primary plots.

Now that we've filtered down to just the 2018 data from SCBI for LITU in leaf, we may want to save that subsetted data for another use. To do that you can write the data frame to a .csv file.

You do not need to follow this step if you are continuing on to the next tutorials in this series as you already have the data frame in your environment. Of course if you close R and then come back to it, you will need to re-load this data and instructions for that are provided in the relevant tutorials.

# optional

write.csv(phe_1sp_2018 , 

          file="NEONpheno_LITU_Leaves_SCBI_2018.csv", 

          row.names=F)

Get Lesson Code

01-explore-phenology-data.R

Questions?

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