https://github.com/b-cubed-eu/gcube

Simulation framework for biodiversity data cubes
https://github.com/b-cubed-eu/gcube

biodiversity-informatics data-cubes r r-package simulations

Last synced: 20 days ago
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Simulation framework for biodiversity data cubes

• Host: GitHub
• URL: https://github.com/b-cubed-eu/gcube
• Owner: b-cubed-eu
• License: other
• Created: 2024-03-26T14:48:59.000Z (9 months ago)
• Default Branch: main
• Last Pushed: 2024-11-05T10:22:51.000Z (about 2 months ago)
• Last Synced: 2024-12-06T12:39:50.862Z (28 days ago)
• Topics: biodiversity-informatics, data-cubes, r, r-package, simulations
• Language: R
• Homepage: https://b-cubed-eu.github.io/gcube/
• Size: 603 MB
• Stars: 3
• Watchers: 1
• Forks: 2
• Open Issues: 8
• Metadata Files:
  • Readme: README.Rmd
  • Changelog: NEWS.md
  • Contributing: .github/CONTRIBUTING.md
  • License: LICENSE
  • Code of conduct: .github/CODE_OF_CONDUCT.md
  • Citation: CITATION.cff
  • Codemeta: codemeta.json

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README

        
---

output: github_document

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---

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knitr::opts_chunk$set(

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# gcube 

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[![DOI](https://zenodo.org/badge/777812249.svg)](https://doi.org/10.5281/zenodo.14038996)

The goal of **gcube** is to provide a simulation framework for biodiversity data cubes using the R programming language. This can start from simulating multiple species distributed in a landscape over a temporal scope. In a second phase, the simulation of a variety of observation processes and effort can generate actual occurrence datasets. Based on their (simulated) spatial uncertainty, occurrences can then be designated to a grid to form a data cube.

Simulation studies offer numerous benefits due to their ability to mimic real-world scenarios in controlled and customizable environments. Ecosystems and biodiversity data are very complex and involve a multitude of interacting factors. Simulations allow researchers to model and understand the complexity of ecological systems by varying parameters such as spatial and/or temporal clustering, species prevalence, etc.

## Installation

You can install the development version from [GitHub](https://github.com/) with:

``` r

# install.packages("remotes")

remotes::install_github("b-cubed-eu/gcube")

```

## Package name rationale and origin story

The name **gcube** stands for "generate cube" since it can be used to generate biodiversity data cubes from minimal input.

It was first developed during the hackathon "Hacking Biodiversity Data Cubes for Policy", where it won the first price in the category "Visualization and training".

You can read the full story here: 

## Example

This is a basic example which shows the workflow for simulating a biodiversity data cube.

It is divided in three steps or processes:

1.  Occurrence process

2.  Detection process

3.  Grid designation process

The functions are set up such that a single polygon as input is enough to go through this workflow using default arguments.

The user can change these arguments to allow for more flexibility.

```{r packages, message=FALSE, warning=FALSE}

# Load packages

library(gcube)

library(sf)      # working with spatial objects

library(dplyr)   # data wrangling

library(ggplot2) # visualisation with ggplot

```

We create a polygon as input. It represents the spatial extend of the species.

```{r polygon}

#| fig.alt: >

#|   Spatial extend in which we will simulate species occurrences.

# Create a polygon to simulate occurrences within

polygon <- st_polygon(list(cbind(c(5, 10, 8, 2, 3, 5), c(2, 1, 7,9, 5, 2))))

# Visualise

ggplot() + 

  geom_sf(data = polygon) +

  theme_minimal()

```

### Occurrence process

We generate occurrence points within the polygon using the `simulate_occurrences()` function.

In this function, the user can specify different levels of spatial clustering, and define the trend of number of occurrences over time.

The default is a random spatial pattern and a single time point with `rpois(1, 50)` occurrences.

```{r simulate-occurrences}

#| fig.alt: >

#|   Spatial distribution of occurrences within the polygon.

# Simulate occurrences within polygon

occurrences_df <- simulate_occurrences(

  species_range = polygon,

  initial_average_occurrences = 50,

  spatial_pattern = c("random", "clustered"),

  n_time_points = 1,

  seed = 123)

# Visualise

ggplot() + 

  geom_sf(data = polygon) +

  geom_sf(data = occurrences_df) +

  theme_minimal()

```

### Detection process

In the second step we define the sampling process, based on the detection probability of the species and the sampling bias.

This is done using the `sample_observations()` function.

The default sampling bias is `"no_bias"`, but bias can be added using a polygon or a grid as well.

```{r detect-occurrences}

#| fig.alt: >

#|   Spatial distribution of occurrences with indication of sampling status.

# Detect occurrences

detections_df_raw <- sample_observations(

  occurrences = occurrences_df,

  detection_probability = 0.5,

  sampling_bias = c("no_bias", "polygon", "manual"),

  seed = 123)

# Visualise

ggplot() + 

  geom_sf(data = polygon) +

  geom_sf(data = detections_df_raw,

          aes(colour = sampling_status)) +

  theme_minimal()

```

We select the detected occurrences and add an uncertainty to these observations.

This can be done using the `filter_observations()` and `add_coordinate_uncertainty()` functions, respectively.

```{r uncertainty-occurrences}

#| fig.alt: >

#|   Spatial distribution of detected occurrences with coordinate uncertainty.

# Select detected occurrences only

detections_df <- filter_observations(

  observations_total = detections_df_raw)

# Add coordinate uncertainty

set.seed(123)

coord_uncertainty_vec <- rgamma(nrow(detections_df), shape = 2, rate = 6)

observations_df <- add_coordinate_uncertainty(

  observations = detections_df,

  coords_uncertainty_meters = coord_uncertainty_vec)

# Created and sf object with uncertainty circles to visualise

buffered_observations <- st_buffer(

  observations_df,

  observations_df$coordinateUncertaintyInMeters)

# Visualise

ggplot() + 

  geom_sf(data = polygon) +

  geom_sf(data = buffered_observations,

          fill = alpha("firebrick", 0.3)) +

  geom_sf(data = observations_df, colour = "firebrick") +

  theme_minimal()

```

### Grid designation process

Finally, observations are designated to a grid with `grid_designation()` to create an occurrence cube.

We create a grid over the spatial extend using `sf::st_make_grid()`. 

```{r create-grid}

# Define a grid over spatial extend

grid_df <- st_make_grid(

    buffered_observations,

    square = TRUE,

    cellsize = c(1.2, 1.2)

  ) %>%

  st_sf() %>%

  mutate(intersect = as.vector(st_intersects(geometry, polygon,

                                             sparse = FALSE))) %>%

  dplyr::filter(intersect == TRUE) %>%

  dplyr::select(-"intersect")

```

To create an occurrence cube, `grid_designation()` will randomly take a point within the uncertainty circle around the observations.

These points can be extracted by setting the argument `aggregate = FALSE`.

```{r grid-designation}

#| fig.alt: >

#|   Distribution of random samples within uncertainty circle.

# Create occurrence cube

occurrence_cube_df <- grid_designation(

  observations = observations_df,

  grid = grid_df,

  seed = 123)

# Get sampled points within uncertainty circle

sampled_points <- grid_designation(

  observations = observations_df,

  grid = grid_df,

  aggregate = FALSE,

  seed = 123)

# Visualise grid designation

ggplot() +

  geom_sf(data = occurrence_cube_df, linewidth = 1) +

  geom_sf_text(data = occurrence_cube_df, aes(label = n)) +

  geom_sf(data = buffered_observations,

          fill = alpha("firebrick", 0.3)) +

  geom_sf(data = sampled_points, colour = "blue") +

  geom_sf(data = observations_df, colour = "firebrick") +

  labs(x = "", y = "", fill = "n") +

  theme_minimal()

```

The output gives the number of observations per grid cell and minimal coordinate uncertainty per grid cell.

```{r visualise-designation}

#| fig.alt: >

#|   Distribution of minimal coordinate uncertainty.

# Visualise minimal coordinate uncertainty

ggplot() +

  geom_sf(data = occurrence_cube_df, aes(fill = min_coord_uncertainty),

          alpha = 0.5, linewidth = 1) +

  geom_sf_text(data = occurrence_cube_df, aes(label = n)) +

  scale_fill_continuous(type = "viridis") +

  labs(x = "", y = "") +

  theme_minimal()

```

### Cubes for multiple species

Each cube simulation function mentioned earlier has a corresponding mapping function.

These mapping functions are designed to handle operations for multiple species simultaneously by using the `purrr::pmap()` function.

Please consult the documentation for detailed information on how these mapping functions are implemented.

| single species              | multiple species                |

|-----------------------------|---------------------------------|

| simulate_occurrences()      | map_simulate_occurrences()      |

| sample_observations()       | map_sample_observations()       |

| filter_observations()       | map_filter_observations()       |

| add_coordinate_uncertainty()| map_add_coordinate_uncertainty()|

| grid_designation()          | map_grid_designation()          |