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An R package to retrieve the centerline of polygons

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centerline

Website Project Status: Active – The project has reached a stable, usable state and is being actively developed. R-CMD-check Check CRAN status Codecov test coverage CRAN status Downloads

The centerline R package simplifies the extraction of linear features from complex polygons, such as roads or rivers, by computing their centerlines (or median-axis) based on skeletons. It uses the super-fast geos library in the background and have bindings for your favorite spatial data library (sf, terra and geos).

Installation

# The easiest way to get centerline is to install it from CRAN:
install.packages("centerline")

# Or the development version from GitHub:
# install.packages("pak")
pak::pak("atsyplenkov/centerline")

Examples for closed geometries

At the heart of this package is the cnt_skeleton function, which efficiently computes the skeleton of closed 2D polygonal geometries. The function uses geos::geos_simplify by default to keep the most important nodes and reduce noise from the beginning. However, it has option to densify the amount of points using geos::geos_densify, which can produce more smooth results. Otherwise, you can set the parameter keep = 1 to work with the initial geometry.

library(sf)
library(centerline)

lake <-
  sf::st_read(
    system.file("extdata/example.gpkg", package = "centerline"),
    layer = "lake",
    quiet = TRUE
  )

# Original
lake_skeleton <-
  cnt_skeleton(lake, keep = 1)

# Simplified
lake_skeleton_s <-
  cnt_skeleton(lake, keep = 0.1)

# Densified
lake_skeleton_d <-
  cnt_skeleton(lake, keep = 2)
cnt_skeleton() code πŸ‘‡
library(ggplot2)

skeletons <-
  rbind(lake_skeleton, lake_skeleton_s, lake_skeleton_d)
skeletons$type <- factor(
  c("Original", "Simplified", "Densified"),
  levels = c("Original", "Simplified", "Densified")
)

skeletons_plot <-
  ggplot() +
  geom_sf(
    data = lake,
    fill = "#c8e8f1",
    color = NA
  ) +
  geom_sf(
    data = skeletons,
    lwd = 0.2,
    alpha = 0.5,
    color = "#263238"
  ) +
  coord_sf(expand = FALSE, clip = "off") +
  labs(caption = "cnt_skeleton() example") +
  facet_wrap(~type) +
  theme_void() +
  theme(
    plot.caption = element_text(family = "mono", size = 6),
    plot.background = element_rect(fill = "white", color = NA),
    strip.text = element_text(face = "bold", hjust = 0.25, size = 12),
    plot.margin = margin(0.2, -0.5, 0.2, -0.5, unit = "lines"),
    panel.spacing.x = unit(-2, "lines")
  )


However, the above-generated lines are not exactly a centerline of a polygon. One way to find the centerline of a closed polygon is to define both start and end points with the cnt_path() function. For example, in the case of landslides, it could be the landslide initiation point and landslide terminus.

# Load Polygon Of Interest (POI)
polygon <-
  sf::st_read(
    system.file(
      "extdata/example.gpkg",
      package = "centerline"
    ),
    layer = "polygon",
    quiet = TRUE
  )

# Load points data
points <-
  sf::st_read(
    system.file(
      "extdata/example.gpkg",
      package = "centerline"
    ),
    layer = "polygon_points",
    quiet = TRUE
  ) |>
  head(n = 2)
points$id <- seq_len(nrow(points))

# Find POI's skeleton
pol_skeleton <- cnt_skeleton(polygon, keep = 1.5)

# Connect points
# For original skeleton
pol_path <-
  cnt_path(
    skeleton = pol_skeleton,
    start_point = subset(points, points$type == "start"),
    end_point = subset(points, points$type == "end")
  )
cnt_path() code πŸ‘‡
path_plot <- ggplot() +
  geom_sf(
    data = polygon,
    fill = "#d2d2d2",
    color = NA
  ) +
  geom_sf(
    data = pol_path,
    lwd = 1,
    color = "black"
  ) +
  geom_sf(
    data = points,
    aes(
      shape = type,
      fill = type
    ),
    color = "white",
    lwd = rel(1),
    size = rel(3)
  ) +
  scale_fill_manual(
    name = "",
    values = c(
      "start" = "dodgerblue",
      "end" = "firebrick"
    )
  ) +
  scale_shape_manual(
    name = "",
    values = c(
      "start" = 21,
      "end" = 22
    )
  ) +
  coord_sf(expand = FALSE, clip = "off") +
  labs(caption = "cnt_path() example") +
  theme_void() +
  theme(
    legend.position = "inside",
    legend.position.inside = c(0.85, 0.2),
    legend.key.spacing.y = unit(-0.5, "lines"),
    plot.caption = element_text(family = "mono", size = 6),
    plot.background = element_rect(fill = "white", color = NA),
    strip.text = element_text(face = "bold", hjust = 0.25, size = 12),
    plot.margin = margin(0.2, -0.5, 0.2, -0.5, unit = "lines"),
    panel.spacing.x = unit(-2, "lines")
  )


And what if we don’t know the starting and ending locations? What if we just want to place our label accurately in the middle of our polygon? In this case, one may find the cnt_path_guess function useful. It returns the line connecting the most distant points, i.e., the polygon’s length. Such an approach is used in limnology for measuring lake lengths, for example.

lake_centerline <- cnt_path_guess(lake, keep = 1)

You can plot polygon centerlines with the geom_cnt_* functions family:

cnt_path_guess() code πŸ‘‡
library(ggplot2)

lakes <- rbind(lake, lake)
lakes$lc <- c("black", NA_character_) 

centerline_plot <- 
  ggplot() +
  geom_sf(
    data = lakes,
    fill = "#c8e8f1",
    color = NA
  ) +
  geom_cnt_text(
    data = lakes,
    aes(
      label = name,
      linecolor = lc
    ),
    keep = 1
  ) +
  facet_wrap(~lc) +
  labs(
    caption = "cnt_path_guess() and geom_cnt_text() examples"
  ) +
  theme_void() +
  theme(
    legend.position = "inside",
    legend.position.inside = c(0.85, 0.2),
    legend.key.spacing.y = unit(-0.5, "lines"),
    plot.caption = element_text(family = "mono", size = 6),
    plot.background = element_rect(fill = "white", color = NA),
    strip.text = element_blank(),
    plot.margin = margin(0.2, -0.5, 0.2, -0.5, unit = "lines"),
    panel.spacing.x = unit(-2, "lines")
  )

Roadmap

centerline πŸ“¦
β”œβ”€β”€ Closed geometries (e.g., lakes, landslides)
β”‚   β”œβ”€β”€ When we do know starting and ending points (e.g., landslides) βœ…
β”‚   β”‚   β”œβ”€β”€ centerline::cnt_skeleton βœ…
β”‚   β”‚   └── centerline::cnt_path βœ…
β”‚   └── When we do NOT have points (e.g., lakes) βœ…
β”‚       β”œβ”€β”€ centerline::cnt_skeleton βœ…
β”‚       └── centerline::cnt_path_guess βœ…
β”œβ”€β”€ Linear objects (e.g., roads or rivers)  πŸ”²
└── Collapse parallel lines to centerline πŸ”²

Alternatives

  • R
    • midlines - A more hydrology-oriented library that provides a multi-step approach to generate a smooth centerline of complex curved polygons (like rivers).
    • cmgo - The main aim of the package is to propose a workflow to extract channel bank metrics, and as a part of that workflow, centerline extraction was implemented.
    • raybevel - Provides a way to generate straight skeletons of polygons. This approach is implemented in the cnt_skeleton(method = "straight") function of the current package.
  • 🐍 Python:
  • πŸ¦€ Rust:
  • JS Javascript:

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An R package to retrieve the centerline of polygons

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