Spatially annotated tree sequences

Model specification

Let’s first load all required R libraries:

library(slendr)

library(dplyr)
library(ggplot2)

init_env()

seed <- 314159
set.seed(seed)

We begin by specifying our spatial model. We will use the same demographic model of modern human history in West Eurasia, which we extensively discussed in the introductory tutorial and on the main landing page. Here is a complete model definition script, without further comments:

# simulated world map
map <- world(
  xrange = c(-13, 70), # min-max longitude
  yrange = c(18, 65),  # min-max latitude
  crs = "EPSG:3035"    # coordinate reference system (CRS) for West Eurasia
)

# couple of broad geographic regions
africa <- region(
  "Africa", map,
  polygon = list(c(-18, 20), c(38, 20), c(30, 33),
                 c(20, 33), c(10, 38), c(-6, 35))
)
europe <- region(
  "Europe", map,
  polygon = list(
    c(-8, 35), c(-5, 36), c(10, 38), c(20, 35), c(25, 35),
    c(33, 45), c(20, 58), c(-5, 60), c(-15, 50)
  )
)
anatolia <- region(
  "Anatolia", map,
  polygon = list(c(28, 35), c(40, 35), c(42, 40),
                 c(30, 43), c(27, 40), c(25, 38))
)

# define population histories

# African ancestral population
afr <- population(
  "AFR", time = 52000, N = 3000,
  map = map, polygon = africa
)

# population of the first migrants out of Africa
ooa <- population(
  "OOA", parent = afr, time = 51000, N = 500, remove = 25000,
  center = c(33, 30), radius = 400e3
) %>%
  move(
    trajectory = list(c(40, 30), c(50, 30), c(60, 40)),
    start = 50000, end = 40000, snapshots = 20
  )

# Eastern hunter-gatherers
ehg <- population(
  "EHG", parent = ooa, time = 28000, N = 1000, remove = 6000,
  polygon = list(
    c(26, 55), c(38, 53), c(48, 53), c(60, 53),
    c(60, 60), c(48, 63), c(38, 63), c(26, 60))
)

# European population
eur <- population(name = "EUR", parent = ehg, time = 25000, N = 2000, polygon = europe)

# Anatolian farmers
ana <- population(
  name = "ANA", time = 28000, N = 3000, parent = ooa, remove = 4000,
  center = c(34, 38), radius = 500e3, polygon = anatolia
) %>%
  expand_range(
    by = 2500e3, start = 10000, end = 7000,
    polygon = join(europe, anatolia), snapshots = 20
  ) # expand the range by 2.500 km

# Yamnaya steppe population
yam <- population(
  name = "YAM", time = 7000, N = 500, parent = ehg, remove = 2500,
  polygon = list(c(26, 50), c(38, 49), c(48, 50),
                 c(48, 56), c(38, 59), c(26, 56))
) %>%
  move(trajectory = list(c(15, 50)), start = 5000, end = 3000, snapshots = 10)

# geneflow events
gf <- list(
  gene_flow(from = ana, to = yam, rate = 0.5, start = 6000, end = 5000, overlap = FALSE),
  gene_flow(from = ana, to = eur, rate = 0.5, start = 8000, end = 6000),
  gene_flow(from = yam, to = eur, rate = 0.75, start = 4000, end = 3000)
)

# compile the spatial model
model <- compile_model(
  populations = list(afr, ooa, ehg, eur, ana, yam),
  gene_flow = gf,
  generation_time = 30, resolution = 10e3,
  competition = 150e3, mating = 120e3, dispersal = 90e3
)

As a sanity check that we defined the demography correctly, you can plot a graph summarizing population divergences and geneflow events by calling plot_model(model):

plot_model(model)

And for completeness, here is a (slightly busy) overview of the spatial population ranges that we defined above:

plot_map(afr, ooa, ehg, eur, ana, yam)

Scheduling sampling events and simulation

Now we will schedule the sampling of a single individual from each population every two thousand years, starting from 40 thousand years ago all the way to the present (this is a feature discussed in the basic tree sequence overview):

# one ancient individual every two thousand years
ancient <- schedule_sampling(model,
                    times = seq(40000, 1, by = -500),
                    list(ooa, 1), list(ehg, 1), list(eur, 1),
                    list(ana, 1), list(yam, 1))

# present-day Africans and Europeans
present <- schedule_sampling(model, times = 0, list(afr, 5), list(eur, 30))

samples <- rbind(ancient, present)

Finally, we can simulate data from our model and process the output tree sequence (recapitate and simplify it):

ts <- slim(
  model, sequence_length = 100e3, recombination_rate = 1e-8, burnin = 200e3,
  samples = samples, method = "batch", random_seed = 314159, max_attempts = 1
) %>%
  ts_recapitate(recombination_rate = 1e-8, Ne = 10000, random_seed = seed) %>%
  ts_simplify()

ts

#> ╔═════════════════════════╗
#> ║TreeSequence             ║
#> ╠═══════════════╤═════════╣
#> ║Trees          │       87║
#> ╟───────────────┼─────────╢
#> ║Sequence Length│   100000║
#> ╟───────────────┼─────────╢
#> ║Time Units     │    ticks║
#> ╟───────────────┼─────────╢
#> ║Sample Nodes   │      432║
#> ╟───────────────┼─────────╢
#> ║Total Size     │205.8 KiB║
#> ╚═══════════════╧═════════╝
#> ╔═══════════╤════╤════════╤════════════╗
#> ║Table      │Rows│Size    │Has Metadata║
#> ╠═══════════╪════╪════════╪════════════╣
#> ║Edges      │1173│36.7 KiB│          No║
#> ╟───────────┼────┼────────┼────────────╢
#> ║Individuals│ 711│71.2 KiB│         Yes║
#> ╟───────────┼────┼────────┼────────────╢
#> ║Migrations │   0│ 8 Bytes│          No║
#> ╟───────────┼────┼────────┼────────────╢
#> ║Mutations  │   0│ 1.2 KiB│          No║
#> ╟───────────┼────┼────────┼────────────╢
#> ║Nodes      │ 939│35.4 KiB│         Yes║
#> ╟───────────┼────┼────────┼────────────╢
#> ║Populations│   7│ 2.7 KiB│         Yes║
#> ╟───────────┼────┼────────┼────────────╢
#> ║Provenances│   3│37.9 KiB│          No║
#> ╟───────────┼────┼────────┼────────────╢
#> ║Sites      │   0│16 Bytes│          No║
#> ╚═══════════╧════╧════════╧════════════╝

Extracting spatial tree sequence information

As we showed in the basic tutorial, the most important function for data exploration is ts_nodes(). This function extracts all information about individuals and nodes recorded in a tree sequence object loaded and annotated by slendr :

data <- ts_nodes(ts)

For completeness, we have also functions such as ts_individuals(), ts_nodes() and ts_edges() which extract tree sequence tables in their “raw” unprocessed form, but ts_nodes() is much more convenient for data exploration and analyses. First, it combined information in the low-level tables of individuals and nodes into a single table but more importantly, if the model which generated this data was a spatial model, ts_nodes() automatically annotates the node/individual tables with the position of each node in space (in real projected coordinates) and time. This means that we can do spatial data analysis directly on the table returned by ts_nodes().

Even better, although we can see below that the returned object belongs to slendr’s own class slendr_ts_nodes, it is internally stored as a spatial sf object. This means that we can use all the functionality of the powerful R package sf as well as many other packages for geospatial analyses directly on the data:

class(data)

#> [1] "slendr"       "slendr_nodes" "sf"           "tbl_df"       "tbl"         
#> [6] "data.frame"

Typing the object into the R console presents a user-friendly summary of the spatio-temporal data extracted from the tree sequence:

data

#> Simple feature collection with 939 features and 12 fields (with 11 geometries empty)
#> Geometry type: POINT
#> Dimension:     XY
#> Bounding box:  xmin: 2426565 ymin: 257945.3 xmax: 8576618 ymax: 4878988
#> Projected CRS: ETRS89-extended / LAEA Europe
#> # A tibble: 939 × 13
#>    name  pop   node_id  time time_tskit           location sampled
#>    <chr> <fct>   <int> <dbl>      <dbl>        <POINT [m]> <lgl>  
#>  1 AFR_1 AFR       362     0          0  (3716841 1078277) TRUE   
#>  2 AFR_1 AFR       363     0          0  (3716841 1078277) TRUE   
#>  3 AFR_2 AFR       364     0          0 (3541863 257945.3) TRUE   
#>  4 AFR_2 AFR       365     0          0 (3541863 257945.3) TRUE   
#>  5 AFR_3 AFR       366     0          0 (3366331 688429.9) TRUE   
#>  6 AFR_3 AFR       367     0          0 (3366331 688429.9) TRUE   
#>  7 AFR_4 AFR       368     0          0  (3329518 1360326) TRUE   
#>  8 AFR_4 AFR       369     0          0  (3329518 1360326) TRUE   
#>  9 AFR_5 AFR       370     0          0  (3263687 1123829) TRUE   
#> 10 AFR_5 AFR       371     0          0  (3263687 1123829) TRUE   
#> # ℹ 929 more rows
#> # ℹ 6 more variables: remembered <lgl>, retained <lgl>, alive <lgl>,
#> #   pedigree_id <dbl>, ind_id <dbl>, pop_id <int>

In the first part of the summary, we see how many individuals (sampled or retained) and nodes are present in the tree sequence together with additional useful information, including a section of the internally stored sf object. And this is a crucial point—**we can always use the internal sf object with the spatial data directly*.

Because the data returned by ts_nodes() is internally transformed to the projected CRS used by the model, we can use the returned object as any other data of the class sf. For instance, at the beginning of this vignette, we specified the world map of the model to be represented in projected CRS (EPSG 3035) which we can verify by typing:

map

#> slendr 'map' object 
#> ------------------- 
#> map: internal coordinate reference system EPSG 3035 
#> spatial limits (in degrees longitude and latitude):
#>   - vertical -13 ... 70
#>   - horizontal 18 ... 65

The fact that the ts_nodes() result is just another sf object makes it easy to visualize overlay contents on this map, as we will see below.

Using the simple features interface

It’s hard to overstate how powerful the R ecosystem around the sf package is. However, getting familiar with this package and geospatial analysis in general can be a bit of a hurdle, especially for novice users because it takes time to get familiar with many new concepts.

Although many slendr features for encoding and programming spatial models and handling simulated tree sequence data discussed so far are designed to abstract away most of the complexities of the underlying low-level details to let you focus on the problem at hand, spatial data analysis is unfortunately whole another matter. Luckily, because the data generated by slendr is no different from any other source of spatial data out there and you have great free resources at your disposal.

The bottom line is: the spatio-temporal data extracted from tree sequences by slendr is no different than an any other normal sf object. Any resource that you find for manipulating, plotting, and analysing sf data can be applied to slendr results as well.

In the remainder of this vignette we will look at a couple of examples.

Plotting locations of simulated sampled individuals

Every spatial object in slendr is internally of the class sf. The flexibility of of ggplot2 and sf packages means that we can overlay the locations of sampled individuals (saved in a sf format by ts_nodes()) on top of our world map (also an sf object):

sampled_data <- ts_nodes(ts) %>% filter(sampled)

ggplot() +
  geom_sf(data = map, fill = "lightgray", color = NA) +
  geom_sf(data = sampled_data, aes(shape = pop, color = time)) +
  ggtitle("Locations of simulated sampled individuals") +
  scale_color_continuous(type = "viridis") +
  theme_bw()

Because sf simple features objects (and, by extension, even slendr_spatial objects) are internally stored as normal data frames with couple more bells and whistles on top of them, we have all the powerful tools for manipulating tabular data at our disposal.

As an example, let’s say we wanted to split the sampled individuals in the tree sequence into epochs and plot those individually using standard ggplot2 features. We could simply first do this, adding a new column specifying to which epoch does each simulated individual belong:

epochs <- sampled_data %>%
  mutate(epoch = cut(time, breaks = c(40000, 30000, 10000, 4000, 0)),
         epoch = ifelse(is.na(epoch), 0, epoch),
         epoch = factor(epoch, labels = c("present", "(present, 4 ky]", "(4 ky, 10 ky]",
                                          "(10 ky, 30 y]", "(30 ky, 40 ky]")))

This chunk of code simply adds a new column epoch to the sf spatial data frame object called epochs here.

Then we can use the ggplot2 function geom_sf to plot the locations of sampled individuals on the map, with each facet corresponding to one epoch (the warning can be safely ignored):

ggplot() +
  geom_sf(data = map, fill = "lightgray", color = NA) +
  geom_sf(data = epochs, aes(shape = pop, color = pop)) +
  facet_wrap(~ epoch) +
  ggtitle("Locations of simulated sampled individuals in different epochs") +
  theme_bw()

We hope this little excursion to handling slendr spatial objects (and, by extension, sf objects) with standard data frame manipulation functions and ggplot2 visualisation convinced you that you have a great flexibility in analysing spatial slendr data. For best introduction into so-called “tidy” data analysis, we encourage you to read the freely-available book R for Data Science.

Extracting spatio-temporal ancestral relationships

Perhaps even more useful than plotting the locations of simulated individuals is accessing the locations (and times) of all ancestors of a particular tree sequence node (a “focal node”). Starting from the focal node or individual, we can trace the geographical location of nodes in its lineage going back all the way to the root with the function ts_ancestors().

Because we record the time and the location of every individual that happens to be the ancestor of at least one sampled individual, this means that we know the true location of every node of the tree sequence.

The simplest use case is determining the locations and times of every single node in the genealogical history of an individual along the tree sequence (it is possible to recover ancestral relationships for multiple samples at once too):

ind <- "EUR_67"

lineages <- ts_ancestors(ts, ind, verbose = TRUE)

#> Collecting ancestors of EUR_67 [1/1]...

#> 
#> Generating data about spatial relationships of nodes...

The function starts at a given node (or, if a name of a sampled diploid individual is provided, two nodes), extracts information about all the parent nodes of that node in the entire tree sequence, records their locations and times, then proceeds one level “higher” in the genealogical history to gather information about the parents of those parent nodes, etc., until it reaches a root node. The result of this process is another sf object in which each row of the table encodes information about single branch in the genealogy of the “focal” node or individual (in our example, "EUR_25"):

lineages

#> Simple feature collection with 112 features and 12 fields
#> Active geometry column: connection
#> Geometry type: LINESTRING
#> Dimension:     XY
#> Bounding box:  xmin: 2736603 ymin: 607014.9 xmax: 8374222 ymax: 4762949
#> Projected CRS: ETRS89-extended / LAEA Europe
#> # A tibble: 112 × 15
#>    name  pop   node_id level child_id parent_id child_time parent_time child_pop
#>  * <chr> <fct>   <int> <fct>    <int>     <int>      <dbl>       <dbl> <fct>    
#>  1 EUR_… EUR       406 1          406       456          0        1900 EUR      
#>  2 EUR_… EUR       406 2          456       460       1900        2020 EUR      
#>  3 EUR_… EUR       406 3          460       469       2020        3010 EUR      
#>  4 EUR_… EUR       406 4          469       488       3010        5080 EUR      
#>  5 EUR_… EUR       406 5          488       495       5080        5740 EUR      
#>  6 EUR_… EUR       406 6          495       543       5740        9760 EUR      
#>  7 EUR_… EUR       406 7          543       608       9760       16090 EUR      
#>  8 EUR_… EUR       406 7          543       695       9760       22960 EUR      
#>  9 EUR_… EUR       406 8          608       695      16090       22960 EUR      
#> 10 EUR_… EUR       406 8          695       704      22960       23560 EUR      
#> # ℹ 102 more rows
#> # ℹ 6 more variables: parent_pop <fct>, child_location <POINT [m]>,
#> #   parent_location <POINT [m]>, connection <LINESTRING [m]>, left_pos <dbl>,
#> #   right_pos <dbl>

In each row of the table, two columns location and parent_location carry the spatial location of a node (node_id) and its parent node (parent_id), respectively, same with the columns time and parent_time (times of nodes) and pop and parent_pop (populations to which the nodes belong). The column connection contains an sf geometry object of the line connecting the two nodes in the coordinate reference system of the “model world”. The column focal_id tells us to which focal node’s genealogy the rows of the table belong to, and the level column shows how deep in the genealogical past does each branch (i.e. row of the table) belong to.

This table contains a complete information about spatio-temporal relationships between the nodes in the genealogy of the given focal sample. In the spirit of demonstrating of slendr tree sequence tables interact with the sf and ggplot2 environments, let’s look at the most immediate parent nodes of the two nodes in the sampled individual (i.e. nodes at the level 1) using the filter function from the R package dplyr:

filter(lineages, level == 1)

#> Simple feature collection with 2 features and 12 fields
#> Active geometry column: connection
#> Geometry type: LINESTRING
#> Dimension:     XY
#> Bounding box:  xmin: 3965813 ymin: 2689630 xmax: 4683571 ymax: 2918506
#> Projected CRS: ETRS89-extended / LAEA Europe
#> # A tibble: 2 × 15
#>   name   pop   node_id level child_id parent_id child_time parent_time child_pop
#> * <chr>  <fct>   <int> <fct>    <int>     <int>      <dbl>       <dbl> <fct>    
#> 1 EUR_67 EUR       406 1          406       456          0        1900 EUR      
#> 2 EUR_67 EUR       407 1          407       451          0        1390 EUR      
#> # ℹ 6 more variables: parent_pop <fct>, child_location <POINT [m]>,
#> #   parent_location <POINT [m]>, connection <LINESTRING [m]>, left_pos <dbl>,
#> #   right_pos <dbl>

As we mentioned above, there are three columns encoding spatial information: location and parent_location carry information about the location of the child and parent node (POINT class), and the connection object (LINESTRING class) contains the line connecting the two nodes (both a branch in the tree sequence and also the spatial connection). We can plot all three spatial features (two points and a line) individually on a map:

level1_branches <- ts_ancestors(ts, "EUR_67") %>% filter(level == 1)

ggplot() +
  geom_sf(data = map, fill = "lightgray", color = NA) +
  geom_sf(data = level1_branches[, ]$child_location, shape = 13, size = 3, color = "red") +
  geom_sf(data = level1_branches[, ]$connection, linetype = 3) +
  geom_sf(data = level1_branches[, ]$parent_location, shape = 20, color = "blue") +
  theme_bw() +
  ggtitle("Parent nodes (blue) of a focal individual (red)")

In the figure above we can see the red focal node and its immediate parents in the tree sequence genealogy (in the coalescent sense, not immediate parents of that individual!). In case you’re surprised to see more than two parents, recall that recombination events make the history encoded by a sample more complicated as it can involve more ancestors as we “move up” a tree from a sample, not just two ancestors. Looking at our example in more detail, we can see that one node (chromosome) of the individual “EUR_67” has two ancestors, each covering a portion of that individuals chromosome, with the other chromosome being covered by a single ancestor (columns left_pos and right_pos):

as_tibble(level1_branches)[, c("name", "node_id", "child_id", "parent_id", "left_pos", "right_pos")]

#> # A tibble: 2 × 6
#>   name   node_id child_id parent_id left_pos right_pos
#>   <chr>    <int>    <int>     <int>    <dbl>     <dbl>
#> 1 EUR_67     406      406       456        0    100000
#> 2 EUR_67     407      407       451        0    100000

A more convenient way to do this analysis is a companion function to ts_ancestors() called plot_ancestors(). This function accepts an sf object with the spatial branching data created by ts_ancestors() and plots the paths between nodes on a map leading from a focal node up to the root(s) of the tree sequence (instead of just paths to immediate parents shown in the previous figure). In this case, because we are working with a single diploid individual, we get two sets of paths for each of its nodes (chromosomes) and plot them in two facets:

ggplot() +
  geom_sf(data = map) +
  geom_sf(data = lineages, size = 0.5, alpha = 0.2) +
  geom_sf(data = sf::st_set_geometry(lineages, "parent_location"),
          aes(shape = parent_pop, color = parent_pop)) +
  geom_sf(data = filter(ts_nodes(ts), name == ind), size = 3) +
  guides(alpha = "none") +
  coord_sf(expand = 0) +
  labs(x = "longitude", y = "latitude") +
  facet_grid(. ~ node_id) +
  ggtitle("Ancestry encoded by two nodes (chromosomes) of EUR_67")

You can compare this result to the animation which recapitulates the simulation, presented in the first vignette.

After comparing our spatial tree sequence figure with the animation, we can immediately notice several things:

All spatial tree sequence paths trace the ancestry of our single European individual back to Africa. In fact, we also see a cluster of past ancestral nodes (i.e. concentrated coalescent events) in the place where the Out of Africa (OOA) migrant population settled around 40,000 thousand years ago (yellow population in the the animation).
One chromosome traces its ancestry to an EHG population indicated by a green square This is expected because we programmed a Yamnaya migration (descending from EHG) from east to central Europe to contribute significant part of ancestry to present-day Europeans (compare to the demographic graph on top of this vignette).
We also see that the other chromosome traces of its ancestry to the Anatolia (blue crosses). This makes sense, because we have simulated European ancestry as being part Anatolian.

Let’s look at the spatial ancestry of another sample. For instance, we know that the simulated history of the Anatolian population in our model is much simpler. According to the demographic graph above, Anatolians split from the ancestral population of Eurasians in Anatolia and then expanded in a wave to Europe. We have sampled the following individuals:

ts_samples(ts) %>% filter(pop == "ANA")

#> # A tibble: 48 × 3
#>    name    time pop  
#>    <chr>  <int> <chr>
#>  1 ANA_1  27500 ANA  
#>  2 ANA_2  27000 ANA  
#>  3 ANA_3  26500 ANA  
#>  4 ANA_4  26000 ANA  
#>  5 ANA_5  25500 ANA  
#>  6 ANA_6  25000 ANA  
#>  7 ANA_7  24500 ANA  
#>  8 ANA_8  24000 ANA  
#>  9 ANA_9  23500 ANA  
#> 10 ANA_10 23000 ANA  
#> # ℹ 38 more rows

Can we see a hint of the spatial dynamics of Anatolians in the spatio-temporal distribution of ancestral node locations of one of the sampled individuals? Let’s pick the last individual and immediately plot its spatial ancestry tidyverse-style using the pipe operator %>%:

lineages <- ts_ancestors(ts, "ANA_45")

ggplot() +
  geom_sf(data = map) +
  geom_sf(data = lineages, size = 0.5, alpha = 0.2) +
  geom_sf(data = sf::st_set_geometry(lineages, "parent_location"),
          aes(shape = parent_pop, color = parent_pop)) +
  geom_sf(data = filter(ts_nodes(ts), name == "ANA_45"), size = 3) +
  guides(alpha = "none") +
  coord_sf(expand = 0) +
  labs(x = "longitude", y = "latitude") +
  facet_grid(. ~ node_id) +
  ggtitle("Ancestry encoded by two nodes (chromosomes) of ANA_45")

As we might expect given the late age of the sample, its position in the map above (red crossed circle) is not in Anatolia but in Europe because it represents one of the descendants of migrants who moved from Anatolia into Europe. This can be clearly seen in the position of its parental nodes in the tree sequence: these nodes represent real individuals who lived at some point in the past, and we can see that they did, indeed, lived in Anatolia.

Calculating distances and other statistics using the sf package

How can we summarise the spatial ancestral dynamics in the figures using some statistics?

Lets take one more look at the sf object with the locations and times of ancestral nodes of sampled individuals, focusing on the following subset of columns:

lineages <-
  ts_samples(ts) %>%
  pull(name) %>%
  ts_ancestors(ts, x = .)

select(lineages, connection, child_time, parent_time)

#> Simple feature collection with 20798 features and 2 fields
#> Geometry type: LINESTRING
#> Dimension:     XY
#> Bounding box:  xmin: 2426565 ymin: 257945.3 xmax: 8576618 ymax: 4878988
#> Projected CRS: ETRS89-extended / LAEA Europe
#> # A tibble: 20,798 × 3
#>                              connection child_time parent_time
#>                        <LINESTRING [m]>      <dbl>       <dbl>
#>  1   (8481422 2958176, 8289917 2751867)      40000       40690
#>  2   (8289917 2751867, 8110419 2813524)      40690       41710
#>  3    (8110419 2813524, 3348636 939123)      41710       67030
#>  4   (8110419 2813524, 2736603 1136489)      41710       83530
#>  5   (8110419 2813524, 3202720 1100178)      41710      203980
#>  6  (8110419 2813524, 3475143 607014.9)      41710      205270
#>  7  (8110419 2813524, 4086614 772146.9)      41710      243100
#>  8    (3348636 939123, 3202720 1100178)      67030      203980
#>  9  (2736603 1136489, 3969941 671890.4)      83530       88810
#> 10 (3969941 671890.4, 3991115 816590.1)      88810       96730
#> # ℹ 20,788 more rows

We can use standard dplyr table manipulation functions to compute the distances between connected notes and the times that separate them (i.e. branch lengths in the traditional phylogenetic sense). We can then use those two quantities to compute how fast (if any at all) was the movement between ancestral individuals in different time periods of the history of a sample:

distances <- lineages %>%
  mutate(branch_length = abs(parent_time - child_time) / model$generation_time,
         distance = sf::st_length(connection) %>% units::set_units(km) %>% as.numeric(),
         speed = distance / branch_length,
         epoch = cut(parent_time, breaks = c(Inf, seq(60000, 0, by = -3000)), dig.lab = 10, include.lowest = TRUE)) %>%
  as_tibble() %>% # strip away the spatial annotation
  select(name, pop, node_id, branch_length, distance, speed, parent_pop, parent_time, child_pop, child_time, epoch)

Let’s also convert the data (absolute distances or distance per generation – i.e., the “speed”) into a long format for easier plotting side by side:

distances_long <- distances %>%
  filter(child_time < 60000) %>%
  filter(!pop %in% c("AFR", "OOA")) %>%
  tidyr::pivot_longer(cols = c(distance, speed),
                      names_to = "stat",
                      values_to = "value") %>%
  mutate(facet = case_when(
    stat == "distance" ~ "absolute distance of a node from parent",
    stat == "speed" ~ "distance traveled by a node per generation"))

Let’s try to summarise the information about distances “traveled” by nodes in different time period by fitting a spline (rather than plotting the raw data with individual nodes):

distances_long %>%
  ggplot(aes(child_time, value, color = child_pop)) +
  geom_smooth(method = "loess", aes(group = child_pop)) +
  geom_hline(yintercept = 0, linetype = 2, linewidth = 0.5) +
  labs(y = "kilometers", x = "time [years ago]") +
  theme(axis.text.x = element_text(hjust = 1, angle = 45),
        legend.position = "bottom") +
  facet_wrap(~ facet, scales = "free_y") +
  guides(color = guide_legend("ancestral node population"))

#> `geom_smooth()` using formula = 'y ~ x'