bioRad

bioRad provides standardized methods for extracting and reporting biological signals from weather radars. It includes functionality to inspect low-level radar data, process these data into meaningful biological information on animal speeds and directions at different altitudes in the atmosphere, visualize these biological extractions, and calculate further summary statistics.

To get started, see:

• Dokter et al. (2019): a paper describing the package.
• bioRad vignette: an introduction to bioRad’s main functionalities.
• Function reference: an overview of all bioRad functions.
• Introductory exercises: a tutorial with code examples and exercises.

More vignettes:

• Range correction: estimate spatial images of vertically integrated density corrected for range effects.

Documentation for the latest development version can be found here.

Installation

bioRad depends on packages from both the CRAN and Bioconductor repositories. Enable both with:

setRepositories(ind = 1:2)

The following system libraries are required before installing bioRad on Linux systems. In terminal, install these with:

sudo apt install libcurl4-openssl-dev
sudo apt install libssl-dev
sudo apt install libgdal-dev

You can install the released version of bioRad from CRAN with:

install.packages("bioRad")

Alternatively, you can install the latest development version from GitHub with:

# install.packages("devtools")
devtools::install_github("adokter/bioRad")

Then load the package with:

library(bioRad)
#> Welcome to bioRad version 0.5.2
#> Docker daemon running, Docker functionality enabled (vol2bird version 0.5.0, MistNet available)

Docker (optional)

You need to install Docker to:

• Process radar data into vertical profiles of biological targets with calculate_vp().
• Read NEXRAD radar data or IRIS RAW data with read_pvolfile(). Docker is not required for reading ODIM radar data.
• Convert NEXRAD radar data to ODIM format with nexrad_to_odim().
• Use the MistNet neural network with calculate_vp() or apply_mistnet()

Why? bioRad makes use of a C implementation of the vol2bird algorithm through Docker to do the above. All other bioRad functions will work without a Docker installation.

1. Go to Docker Desktop.
2. Download Docker for Windows or Mac (free login required) and follow the installation instructions. Note that Docker for Windows requires Microsoft Windows 10 Professional or Enterprise 64-bit: installing Docker Toolbox for previous Windows versions will not work.
3. Open the Docker application. The Docker (whale) icon will appear in your menu or task bar and indicate if it is running correctly.
4. Make local drive(s) available for Docker containers:
   • On Windows: right click the Docker icon > Settings > Shared drives > Select the drive(s) where you will be processing radar files > Click Apply.
   • On Mac: click the Docker icon > Preferences > File sharing > Add the drive(s) where you will be processing radar files > Click Apply & Restart.
5. In R do check_docker().
6. You can now use the bioRad functionality that requires Docker.

1. Hyper-V / Virtualbox conflicts on Windows. Docker requires Hyper-V enabled, but Hyper-V can not run together with Virtualbox. To use Virtualbox you will need to disable Hyper-V, which also disables Docker, and requires a reboot of the system.
2. For firewall issues on Windows, see this issue
3. For permission issues when running docker, specifically the error Got permission denied while trying to connect to the Docker daemon socket at unix:///var/run/docker.sock, see this solution. Running sudo usermod -a -G docker $USER in a terminal will fix this problem.

Usage

Radar data example

bioRad can read weather radar data (= polar volumes) in the ODIM format and formats supported by the RSL library, such as NEXRAD data. NEXRAD data (US) are available as open data and on AWS.

Here we read an example polar volume data file with read_pvolfile(), extract the scan/sweep at elevation angle 3 with get_scan(), project the data to a plan position indicator with project_as_ppi() and plot the radial velocity of detected targets with plot():

library(tidyverse) # To pipe %>% the steps below
system.file("extdata", "volume.h5", package = "bioRad") %>%
  read_pvolfile() %>%
  get_scan(3) %>%
  project_as_ppi() %>%
  plot(param = "VRADH") # VRADH = radial velocity in m/s

Radial velocities towards the radar are negative, while radial velocities away from the radar are positive, so in this plot there is movement from the top right to the bottom left.

Vertical profile data example

Weather radar data can be processed into vertical profiles of biological targets using calculate_vp(). This type of data is available as open data for over 100 European weather radars.

Once vertical profile data are loaded into bioRad, these can be bound into time series using bind_into_vpts(). Here we read an example time series, project it on a regular time grid with regularize_vpts() and plot it with plot():

example_vpts %>%
  regularize_vpts() %>%
  plot()
#> projecting on 300 seconds interval grid...

The gray bars in the plot indicate gaps in the data.

The altitudes in the profile can be integrated with integrate_profile() resulting in a dataframe with rows for datetimes and columns for quantities. Here we plot the quantity migration traffic rate (column mtr) with plot():

my_vpi <- integrate_profile(example_vpts)

plot(my_vpi, quantity = "mtr") # mtr = migration traffic rate

To know the total number of birds passing over the radar during the full time series, we use the last value of the cumulative migration traffic (column mt):

my_vpi %>%
  pull(mt) %>% # Extract column mt as a vector
  last()
#> [1] 173023.8

For more exercises, see this tutorial.

Meta

• We welcome contributions including bug reports.
• License: MIT
• Get citation information for bioRad in R doing citation("bioRad").
• Please note that this project is released with a Contributor Code of Conduct. By participating in this project you agree to abide by its terms.