The development version can be installed from GitHub with:
Note that Archeofrag requires the RBGL package available through Bioconductor:
if (!requireNamespace("BiocManager", quietly = TRUE))
install.packages("BiocManager")
BiocManager::install("RBGL")
For an interactive demonstration, see also the Shiny application.
The Archeofrag
package comes with a small example data set called “Liang Abu”, related to the pottery fragments found on the surface and in the first two layers of the Liang Abu rock shelter. The data set contains three data frames:
The make_frag_object
function builds objects with the class “frag”. Frag objects are not required by the other Archeofrag
functions, however, using them ensures that the data are suitable for the next steps of the analysis. The make_cr_graph
function takes a frag object and generates an igraph
graph object representing the connection relationships.
Several Archeofrag
functions ensure that the first examination of the data is easy. The frag.relations.by.layers
function returns a matrix with the number of relationships within and between spatial units (e.g., stratigraphic layer).
The diagonal of the matrix gives the number of intra-layer relationships, and the other values refer to inter-layer relationships. Here, for example, there are 31 connection relationships within layer 2, and 3 connection relationships between layers 1 and 2. No connection relationship was found between the surface (“0”) and layer 2.
The frag.graph.plot
function generates a visual representation of the graph:
The fragments are coloured by layer and the three inter-layer relationships can be observed.
Let us now focus on layers 1 and 2. The frag.get.layers.pair
function allows the user to extract a pair of layers.
This subgraph is drawn with the frag.graph.plot
function:
The function has a different behaviour if applied to a fragmentation graph with only two spatial units: the nodes are vertically localised to reflect their location in the two spatial units. In addition, note that standard plot
arguments can be passed to the frag.graph.plot
function, e.g., the main
argument to define the plot’s title.
The frag.get.layers.pair
function has additional parameters to set the minimum size of the connected fragments sets (size.mini
) and to extract only the sets of connected fragments which include relationships between the two spatial units (mixed.components.only
).
frag.get.layers.pair(abu.g, layer.attr="layer", sel.layers=c("1", "2"),
size.mini=2, mixed.components.only=TRUE)
#> IGRAPH 8f64fca UN-- 19 22 --
#> + attr: frag_type (g/c), name (v/c), layer (v/c), zmin (v/n), zmax
#> | (v/n), square (v/c), sherd.type (v/c), thickness (v/n), length (v/n),
#> | membership (v/n), type_relation (e/c)
#> + edges from 8f64fca (vertex names):
#> [1] 187--188 165--195 195--196 195--197 196--198 195--204 196--204 197--204
#> [9] 198--204 195--25 188--250 27 --28 27 --366 27 --367 28 --367 366--367
#> [17] 27 --371 332--371 366--371 25 --8 28 --835 835--836
Additionally, the frag.get.layers
function can extract a set of specified spatial unit(s), e.g., the refits within the first layer at Liang Abu:
frag.get.layers(abu.g, layer.attr="layer", sel.layers="1")
#> $`1`
#> IGRAPH f58edbd UN-- 23 18 --
#> + attr: frag_type (g/c), name (v/c), layer (v/c), zmin (v/n), zmax
#> | (v/n), square (v/c), sherd.type (v/c), thickness (v/n), length (v/n),
#> | type_relation (e/c)
#> + edges from f58edbd (vertex names):
#> [1] 123--124 187--188 195--196 195--197 196--198 195--204 196--204
#> [8] 197--204 198--204 195--25 301--302 313--314 392--408 435--441
#> [15] 477--478 25 --8 435--9999 441--9999
Weighting the edges is a crucial step in the TSAR / Archeofrag
approach because it integrates the topological properties of the fragmentation graph. The frag.edges.weighting
function assigns a value to each edge based on the topological properties of the vertices this edge connects.
Then, the frag.layers.cohesion
function is used to calculate the cohesion value of each layer.
These values determine the cohesion (self-adherence) of the spatial units (here, layers) based on the distribution of the refitting relationships. Note that the weighting of the edges is mandatory for the computation of cohesion. Using the frag.layers.cohesion
function on a non-weighted fragmentation graph will give an error.
In addition to topological properties, the computation of edge weights can optionally include other parameters, namely the morphometry of the fragments and the distance between the location where they were found. In the following example, the length of the pottery sherds is used as a morphometric proxy:
Using the morphometry parameter results, layer 2 is more cohesive than layer 1:
frag.layers.cohesion(abu.g12morpho, layer.attr="layer")
#> cohesion1 cohesion2
#> 1/2 0.3263172 0.666898
In addition, the frag.layers.admixture
function returns a value quantifying the admixture between the two layers. Let us compare the results obtained when the morphometry is used or not:
# topology-based weighting:
frag.layers.admixture(abu.g12, layer.attr="layer")
#> admixture
#> 0.009452435
# topology + morphometry weighting:
frag.layers.admixture(abu.g12morpho, layer.attr="layer")
#> admixture
#> 0.006784769
In this case, using the morphometry in the computation lowers the admixture between layers 1 and 2 at Liang Abu.
Simulation-based hypotheses can be tested by combining the functions offered by Archeofrag
.
The frag.simul.process
function generates a pair of spatial units containing fragmented objects with connection relationships within and between these units. The next command creates two spatial units populated with 20 initial objects (corresponding to the “connected components” of a graph) which are fragmented into 50 pieces.
This illustrates the simplest use of the frag.simul.process
function, which has several other parameters to control the features of the simulation.
The number of initial spatial units is a crucial parameter, set using the initial.layers
parameter with “1” or “2”. This parameter determines the method used to construct the graph and, accordingly, the underlying formation process hypothesis.
If initial.layers
is “1”, the fragmentation process is simulated assuming that all the objects were originally buried in a single spatial unit. The two clusters observed at the end of the process are due to fragmentation and displacement.
disturbance
parameter.If initial.layers
is “2”, it assumes that the objects were buried in two different spatial units, which were later partially mixed due to fragmentation and displacement:
The vertices
and edges
parameters are related: at least one of them must be set, or both (only if initial.layers
is set to 1). Note that using both parameters at the same time increases the constraints and reduces the number of possible solutions to generate the graph. When there is no solution, an error occurs and a message suggests how to change the parameters.
The balance
argument determines the number of fragments in the smaller spatial unit (before the application of the disturbance process). The components.balance
also determines the contents of the two spatial units by affecting the distribution of the initial objects (components). Note that this argument is used only when initial.layers
is set to 2.
The aggreg.factor
parameter affects the distribution of the sizes of the components: this distribution tends to be more unequal when aggreg.factor
has values close to 1.
By default, fragments from two spatial units can be disturbed and moved to another other spatial unit. However, the asymmetric.transport.from
can be used to move fragments from only one given spatial unit.
Finally, the planar
argument determines if the generated graph has to be planar or not (a graph is planar when it can be drawn on a plane, without edges crossing).
An example of a complete configuration of the function is:
frag.simul.process(initial.layers=1,
n.components=20,
vertices=50,
edges=40,
balance=.4,
components.balance=.4,
disturbance=.1,
aggreg.factor=0,
planar=T,
asymmetric.transport.from="1")
An additional function is intended to simulate the failure of an observer to determine the relationships between fragments. The frag.observer.failure
function takes a fragmentation graph and randomly removes a given proportion of edges.
The versatile frag.simul.process
function can generate fragmentation graphs under multiple hypotheses about the initial conditions (number of initial objects, number of initial spatial units, etc.). Testing measurements on observed empirical data against measurements made under these hypotheses can determine the most likely initial conditions and fragmentation process.
Here, this is illustrated by comparing measurements from Liang Abu layers 1 and 2 with measurements from simulated data under two hypotheses about the number of initial spatial units (e.g., layers), using the initial.layers
parameter with two values, namely one or two initial layers.
A fragmentation graph is generated for each initial.layers
value, using the parameters observed in the Liang Abu layers 1 and 2 fragmentation graph. Setting the simulator is made easier by using the frag.get.parameters
function, which takes a graph and computes a series of parameters that are returned as a list.
# for H2:
test.2layers.g <- frag.simul.process(initial.layers=2,
n.components=params$n.components,
vertices=params$vertices,
disturbance=params$disturbance,
aggreg.factor=params$aggreg.factor,
planar=params$planar)
# for H1:
test.1layer.g <- frag.simul.process(initial.layers=1,
n.components=params$n.components,
vertices=params$vertices,
disturbance=params$disturbance,
aggreg.factor=params$aggreg.factor,
planar=params$planar)
Let us now generate not only one graph, but a large number of graphs to statistically compare measurements in the empirical and simulated graphs. The frag.simul.process
function is set for the “two initial layers” hypothesis and embedded into an ad hoc function:
run.test2 <- function(x){
frag.simul.process(initial.layers=2, # note the different value
n.components=params$n.components,
vertices=params$vertices,
disturbance=params$disturbance,
aggreg.factor=params$aggreg.factor,
planar=params$planar)
}
The function is then executed a sufficient number of times:
The empirical values observed for Liang Abu layers 1 and 2 (red line) can now be compared to the values measured in the simulated graph generated under the hypothesis of two initial layers. This shows, for example, that the empirical admixture value is slightly lower than the simulated admixture values:
edges.res <- sapply(test2.results,
function(g) frag.get.parameters(g, "layer")$edges)
plot(density(edges.res), main="Edges")
abline(v=params$edges, col="red")
Similarly, the empirical admixture value is lower than the simulated admixture values:
admix.res <- sapply(test2.results,
function(g) frag.layers.admixture(g, "layer"))
plot(density(admix.res), main="Admixture")
abline(v=frag.layers.admixture(abu.g12, "layer"), col="red")
Two functions (frag.simul.compare
and frag.simul.summarise
) facilitate the execution of the analytical process described above on the initial number of spatial units. The frag.simul.compare
function takes an observed fragmentation graph, generates two series of simulated graphs corresponding to two hypotheses on the number of initial spatial units (H1 for 1 initial spatial unit and H2 for two initial spatial units), and returns a data frame of measurements made on each series (including the edge count, weights sum, balance value, disturbance value, admixture value, and cohesion values of the two spatial units).
compare.res <- frag.simul.compare(abu.g12, layer.attr="layer",
iter=30, summarise=FALSE)
head(compare.res$h1.data)
#> edges weightsum balance disturbance admixture cohesion1 cohesion2
#> 1 55 241.5101 0.3333333 0.07272727 0.015562064 0.2941598 0.6902782
#> 2 54 232.7924 0.3472222 0.07407407 0.018407719 0.1925569 0.7890353
#> 3 56 233.1339 0.2916667 0.10714286 0.043280850 0.3546489 0.6020702
#> 4 59 375.7690 0.3333333 0.06779661 0.010895939 0.3774569 0.6116472
#> 5 52 216.0940 0.3611111 0.05769231 0.009256239 0.1963094 0.7944344
#> 6 50 177.5047 0.3611111 0.08000000 0.019554199 0.3744804 0.6059654
For each of these parameters, the frag.simul.summarise
function facilitates the comparison between empirical observed values and simulated values generated for H1 and H2.
frag.simul.summarise(abu.g12, layer.attr="layer",
compare.res$h1.data,
compare.res$h2.data)
#> H1 != H2? p.value Obs. value/H1 Obs. value/H2
#> edges FALSE 0.46 lower lower
#> weightsum FALSE 0.49 lower lower
#> balance FALSE 0.06 within lower
#> disturbance FALSE 0.31 lower lower
#> admixture FALSE 0.29 within lower
#> cohesion1 TRUE 0 higher within
#> cohesion2 TRUE 0 lower within
This function returns a data frame with four columns, containing, for each parameter studied:
Note that the frag.simul.compare
function can optionally be set to execute and return the results of the frag.simul.summarise
function.
Similarity relationships are, by construction, not part of the TSAR method, which is based on the topological properties of connection networks. However, since similarity relationships are more frequent in archaeological empirical studies, the Archeofrag
package includes various functions to handle them. This section illustrates a method to use similarity relationships using Archeofrag
and R generic functions.
The make_sr_graph
function takes a “frag” object and generates an igraph
similarity network.
# make a frag object and generate a similarity graph:
abu.frag <- make_frag_object(sr=df.sr, fragments=fragments.info)
abu.sr <- make_sr_graph(abu.frag)
The frag.relations.by.layers
function returns a table with the number of similarity relationships in and between spatial units, e.g., in the top three layers at Liang Abu:
# count of similarity relationships in and between layers:
simil.by.layers.df <- frag.relations.by.layers(abu.sr, "layer")
simil.by.layers.df
#>
#> 0 1 2
#> 0 15
#> 1 0 234
#> 2 1 61 173
These values can be observed as percentages:
# percentage of similarity relationships in and between layers:
round(simil.by.layers.df / sum(simil.by.layers.df, na.rm=T) * 100, 0)
#>
#> 0 1 2
#> 0 3
#> 1 0 48
#> 2 0 13 36
Considering a stratigraphic sequence, adjacent and close layers in the sequence must have lower statistical distances than distant layers. Consequently, it is expected that the result of a hierarchical clustering computed on this distance table would reflect the order of the layers. The expected result is observed for Liang Abu surface and the first two layers, suggesting an absence of significant disturbance and admixture ().
# turn similarity into distance:
simil.dist <- max(c(simil.by.layers.df), na.rm=T) - simil.by.layers.df
simil.dist <- as.dist(simil.dist)
# hierarchical clustering:
clust.res <- hclust(simil.dist, method="ward.D2")
clust.res$labels <- as.character(factor(clust.res$labels,
levels=c("0", "1", "2"),
labels=c("layer 0", "layer 1", "layer 2")))
plot(clust.res, hang=-1, axes=F, ann=F)
The second aim of the TSAR method implemented in Archeofrag
is to characterise spatial units based on the topological properties of the connection relationships between the fragments they contain. Although this aspect is still a work in progress, some functions are already implemented and will be illustrated using simulated data. The archaeological interpretation of numerical values depends on the type of material (lithic, pottery, etc.) and the completeness or incompleteness of the objects under study and is not discussed here.
# simulate a fragmentation graph:
simul.g <- frag.simul.process(initial.layers=2,
n.components=20,
vertices=70,
balance=.45)
# extract the subgraph of each spatial unit:
simul.g1 <- frag.get.layers(simul.g, layer.attr="layer", sel.layers="1")[[1]]
simul.g2 <- frag.get.layers(simul.g, layer.attr="layer", sel.layers="2")[[1]]
In a graph, a cycle is a path in which only the first and last vertices are repeated. The frag.cycles
function searches for cycles in a graph and returns the number of cycles found for different cycle lengths. The kmax
parameter determines the maximal length of the cycles to search for. Let us compare the cycles found in the two spatial units of the artificial graph:
rbind(
"unit1" = frag.cycles(simul.g1, kmax=5),
"unit2" = frag.cycles(simul.g2, kmax=5))
#> 3-cycles 4-cycles 5-cycles
#> unit1 6 1 0
#> unit2 12 3 0
The frag.path.lengths
function returns the distribution of the path lengths in the graph (i.e., the number of edges between each pair of vertices). This function returns a vector whose first element is the frequency of the paths of length 1, the second element is the frequency of the paths of length 2, etc. If the cumulative
parameter is set to TRUE
, the function returns the cumulative relative frequency of the path lengths.
frag.path.lengths(simul.g1)
#> [1] 27 9 2 1
frag.path.lengths(simul.g2)
#> [1] 39 14 2 1
frag.path.lengths(simul.g2, cumulative=T)
#> [1] 1.00000000 0.35897436 0.05128205 0.02564103
In a graph, the shortest path between two vertices is the path including the least number of edges. The diameter of a graph is its longest shortest path. The frag.diameters
function calculates the diameter of each component of the graph and returns the frequency of the values. If the cumulative
parameter is set to TRUE
, the function returns the cumulative relative frequency of the diameters.