All these Fantastic Cultures? Research History and Regionalization in the Late Palaeolithic Tanged Point Cultures of Eastern Europe

Abstract

The Late Glacial, that is the period from the first pronounced warming after the Last Glacial Maximum to the beginning of the Holocene (c. 16,000–11,700 cal bp), is traditionally viewed as a time when northern Europe was being recolonized and Late Palaeolithic cultures diversified. These cultures are characterized by particular artefact types, or the co-occurrence or specific relative frequencies of these. In north-eastern Europe, numerous cultures have been proposed on the basis of supposedly different tanged points. This practice of naming new cultural units based on these perceived differences has been repeatedly critiqued, but robust alternatives have rarely been offered. Here, we review the taxonomic landscape of Late Palaeolithic large tanged point cultures in eastern Europe as currently envisaged, which leads us to be cautious about the epistemological validity of many of the constituent groups. This, in turn, motivates us to investigate the key artefact class, the large tanged point, using geometric morphometric methods. Using these methods, we show that distinct groups are difficult to recognize, with major implications for our understanding of patterns and processes of culture change in this period in north-eastern Europe and perhaps elsewhere.

Le Tardiglaciaire, c'est-à-dire l’époque allant du premier réchauffement notable après le dernier maximum glaciaire jusqu'au début de l'Holocène (environ 16 000 à 11 700 cal bp), a traditionnellement été considéré comme une phase de recolonisation de l'Europe du Nord et une période de diversification des cultures de la fin du Paléolithique. Ces cultures ont été définies par des types d'outils spécifiques ou par leur apparition simultanée ou encore par leur fréquence relative. En Europe du Nord-Est, l'existence de nombreuses cultures a ainsi été proposée sur la base de pointes à pédoncule apparemment différentes. Cette pratique de nommer de nouveaux groupes culturels sur la base de différences présumées a fait l'objet de critiques répétées mais sans que des alternatives convaincantes aient été formulées. Dans cet article les auteurs passent en revue le paysage taxonomique des cultures à grandes pointes à pédoncule de la fin de Paléolithique en Europe de l'Est tel qu'il se présente de nos jours, ce qui les mène à exprimer des doutes sur la validité épistémologique de bien de ces groupements culturels. Par conséquent, les auteurs se sont attelés à l'examen d'une classe d'objet fondamentale, les grandes pointes à pédoncule, en utilisant les méthodes de la morphométrie géométrique. Ils peuvent ainsi démontrer qu'il est difficile d'identifier des groupes distincts, ce qui a des conséquences majeures pour notre compréhension des tendances et processus de changement culturel à cette époque en Europe du Nord-Est et peut-être ailleurs. Translation by Madeleine Hummler

Das Spätglazial, also der Zeitraum zwischen der ersten ausgeprägten Klimaerwärmung nach dem letzten eiszeitlichen Maximum bis zum Anfang des Holozäns (ca. 16 000–11 700 cal bp), ist traditionell als eine Epoche der Wiederbesiedlung Nordeuropas und der Diversifizierung der spätpaläolithischen Kulturen angesehen worden. Diese Kulturen sind von spezifischen Artefakttypen, oder derer gleichzeitigen Erscheinung, oder noch aufgrund derer relativen Häufigkeit, charakterisiert. In Nordosteuropa sind zahlreiche Kulturen auf der Grundlage von vermeintlich verschiedene Stielspitzen vorgeschlagen worden. Diese Namengebung von neuen Kulturgruppen aufgrund wahrgenommener Unterschiede ist wiederholt kritisiert worden, aber solide Alternativen sind bisher selten vorgeschlagen worden. Hier wird die taxonomische Gestaltung der großen spätpaläolithischen Stielspitzen in Osteuropa, wie sie zurzeit konzipiert ist, bewertet; die epistemologische Gültigkeit von zahlreichen Gruppen muss man deswegen mit Vorsicht beurteilen. Diese Situation hat uns dazu motiviert, eine fundamentale Artefaktkategorie, nämlich die großen Stielspitzen, mithilfe von geometrischen morphometrischen Methoden zu untersuchen. Dies zeigt, dass es schwierig ist, zwischen verschiedenen Gruppen zu unterscheiden; dies hat wesentliche Auswirkungen auf unser Verständnis von kulturellen Wandlungsprozessen und Tendenzen in diesem Zeitabschnitt in Nordosteuropa und vielleicht auch anderswo. Translation by Madeleine Hummler

Introduction

During the Last Glacial Maximum (LGM), around 22,000 years ago, the higher latitudes of Europe were devoid of people. When pronounced warming began around 16,000 years ago, groups belonging to the Magdalenian and Epigravettian traditions began to move northwards (Gamble et al., 2005; Riede, 2014; Wygal & Heidenreich, 2014). During this colonization, groups occupying particular regions began to develop consistent differences in their material culture, characterized by shouldered points (the Creswellian and Hamburgian: Burdukiewicz, 1986), backed points (the Federmessergruppen/Azilian: Schild, 1996), large tanged points (the Bromme culture and others, see below: Ekholm, 1926; Sinitsyna, 2002), and small tanged points (the Ahrensburgian and Swiderian: Taute, 1968; Kobusiewicz, 2002).

Importantly, these regional cultural entities provide the key framework for inferring patterns and processes of migration, adaptation, and potentially even emerging ethnicity in this period. Once certain cultures and their attendant territories are defined, they can move around, their material culture or economic focus can change, and they can interact with one another. Indeed, without archaeological taxonomies, the goal of understanding such past processes cannot be realized (Roberts & Vander Linden, 2011). Yet, techno-typological classifications in the European Palaeolithic have been repeatedly critiqued. For the Middle Palaeolithic of Europe and the Near East, the infamous debate between Lewis Binford, François Bordes, and Paul Mellars in the 1960s largely broke with the tradition of casting such archaeological phenomena as ethnic entities; yet a legacy of taxonomic inconsistency still haunts this period (Clark, 1999, 2009; Bisson, 2000; Clark & Riel-Salvatore, 2006; Shea, 2014). Similarly, a soul-searching debate rocked the Levantine Epipalaeolithic in the 1990s, pitching those who saw material culture variation as reflecting ethnic units (Fellner, 1995; Kaufman, 1995; Goring-Morris, 1996; Phillips, 1996) against those who were sceptical of such attributions for epistemological reasons (Clark, 1996) or preferred behavioural ecological explanations (Neeley & Barton, 1994; Barton & Neeley, 1996). In addition, it has been remarked in relation to the European and Levantine Middle/Upper Palaeolithic (Felgenhauer, 1996; Tomášková, 2003; Clark & Riel-Salvatore, 2006; Shea, 2014), as well as for the Late Palaeolithic in northern Asia (Vasil'ev, 2001), the Upper Volga region (Lisitsyn, 2017), and Lithuania (Ivanovaitė & Riede, 2018) that many, if not most, of the analytical units in use today are beset by mdash;at times subtle, at other times critical—local, regional, and national biases.

In eastern Europe, Wyszomirska-Webert (1996: 97) viewed the plethora of cultural units with a critical eye, enquiring into the ontological and epistemological robusticity as well as the anthropological meaning of ‘all these fantastic cultures’ that, according to the then-prevalent view, populated the region in prehistory. As a subset of these, the Late Palaeolithic is made up of several large tanged point cultures, each with a rich and mixed research history. The iconic large tanged point forms, in all its diversity (Figure 1), the basis of cultural classifications. Today, the proposed cultural geography for this period is characterized by substantial taxonomic diversity (Table 1). These groups are traditionally used to infer processes of ‘palaeohistory’ (sensu Kozłowski & Kozłowski, 1979): the territories, collective actions, and migrations of identity-conscious ethnic groups (Figure 2).

Figure 1. Examples of tanged points from eastern Europe. a) Examples from the type site of Bromme (Denmark). b) Archaeological units in eastern Europe featuring tanged points. c) Examples of tanged points from the Pitted Ware site of Kainsbakke (Denmark). Scale: 10mm. The colour palette corresponds to the visualization used throughout this article. Illustrations: Bromme (Redrawn after Taute, 1968; Fig. 95: 2, 3, 4, 7, 8, 10), Tieply Ruchey II (Sorokin, 2009; Fig. 3:1), Anosovo (Zaliznyak, 1999; Fig. 31: 2), Woronowka (Redrawn after Szymczak, 1991; Fig. 18:1), Velyky Midsk (Redrawn after Zaliznyak, 1999; Fig. 12:3), Merkys-Ūla (Redrawn after Rimantienė, 1971; Fig. 19:5), Margių (Redrawn after Rimantienė, 1999: Fig. 19:13), Koromka (Redrawn after Zaliznyak, 1999; Fig. 28:29), Burdeniszki (Redrawn after Szymczak, 1995; Fig. 6:2), Kainsbakke (Redrawn after Rasmussen & Richter, 1991; Fig. 21:2).

Figure 2. Maps showing the proposed tanged point cultures of north-eastern Europe, from (a) Andersson et al. (2004), (b) Kozłowski (1999), (c) Sinitsyna (2002), and (d) Zaliznyak (1999). The colour palette for cultures corresponds to the visualization used throughout this article. Note how the variable taxonomy and the different authors’ predilections for splitting or lumping create substantially different cartographic expressions. Common to all these maps is that the relationship between the proposed ‘territories’ of these large tanged point groups and the evidence on which these are based remains opaque.

Table 1. Eastern European tanged point cultures, their characteristics and key references.

As elsewhere, these projectile points are invested with chronological, spatial, and, by extension, cultural specificity (O'Brien & Lyman, 1999). Otte & Keeley (1990) have noted, however, that taxonomic units in this period are usually based on early antiquarian excavations of but a few key sites, reflected in the practice of naming them after these loci classici; they also point out that ‘explanations offered for the events in such sequences, whether explicit or implicit, tend to focus on local phenomena or events and reinforce ideas of local continuity and evolution’ (Otte & Keeley, 1990: 577). A more acerbic critique has been voiced by Houtsma and collegues, who argued that ‘[o]nly when researchers of the Late Palaeolithic habitation of the Northwest European Plain escape the constraints of contemporary national borders and the paradigmatic straight-jackets of provincialism and regional chauvinism, which lead to insularity, will we be in a position to gain analytical control of the totality of extant data partitioned into uniform and mutually comparable sets of demonstrably relevant attributes’ (Houtsma et al., 1996: 143). Their critique is arguably as valid for the eastern extension of the North European Plain as it is for its western end. Most radically, Clark and Lindly (1991) have argued that this entire way of thinking in terms of archaeological cultures supposedly reflecting past peoples, their actions, adaptations, and migrations is flawed at the paradigmatic level.

In order to bring some clarity to this situation, we present a review of the research history of the Late Palaeolithic large tanged point cultures in eastern Europe. Following Sauer and Riede (2019), such source-critical interrogations provide evaluations of the epistemic status of the units in question. We find many units problematic in this regard and, using geometric morphometric (GMM) approaches, we offer an alternative way of capturing tanged point variability across the region without abstraction from the evidence base.

Research History and Current Late Palaeolithic Cultural Taxonomies: Splitters vs Lumpers

In the European Late Palaeolithic, we encounter the lumper–splitter conundrum, well-known from any discipline concerned with classification (see Simpson, 1945; Adams & Adams, 1991): some researchers tend towards lumping assemblages into higher-level units, while others split them in order to distinguish industries, cultures, or facies according to, for instance, local manufacturing traditions or different economic strategies. There are, however, no recognized standards for such classification in archaeology.

Practitioners working within the Palaeolithic archaeological traditions of central and eastern Europe tend to exhibit a strong preference for splitting. Perceived differences between assemblages with large tanged points found in different regions or even in individual river valleys are commonly emphasized. This predilection may stem from the need to organize large quantities of archaeological material from several different countries (e.g. Poland, Lithuania, Russia, Belarus, and Ukraine), coupled with strong regional identities and the, implicit or explicit, motivation to stress differences rather than similarities between regions. Hence, a plethora of cultures considered taxonomically comparable to the Scandinavian Bromme culture are found in eastern Europe, although the criteria for distinguishing these units often remain ambiguous (Table 1).

The explanations for the presence of tanged points in eastern Europe can be divided into three schools:

• • direct migration/expansion of the Bromme culture

• • cultural contact/diffusion of point forms through borrowing, or

• • one or several independent innovations converging on the same form of projectile point.

In Polish Late Palaeolithic archaeology, two particular units are seen as similar to the Brommean in terms of chronology and lithics: the Perstunian (Szymczak, 1991) and Wolkushian cultures (Szymczak, 1995). Szymczak (1983, 1987, 1990) distinguished the Perstunian on the basis of six homogeneous sites found in north-eastern Poland and southern Lithuania (Szymczak, 1991), but was met with harsh source-critical scepticism at the time (Sulgostowska, 1989).

The Perstunian is explicitly framed as analogous to the Bromme culture in terms of dating and diagnostic tool forms. The Perstunian lithic inventory consists of conical cores, burins, scrapers, and large tanged points, with its origin in the Allerød chronozone. In the absence of absolute dates and meaningful stratigraphies, however, this dating remains a hypothesis grounded in the observation that Perstunian artefacts are typically in worse condition than Swiderian artefacts and the rationale that the eastern European Perstunian assemblages and more westerly inventories of the Bromme culture are generally similar in terms of typology and technology (Szymczak, 1992, 1995). According to Szymczak (1991), the differences between the Perstunian and Brommean are the appearance of double-platform cores, a higher frequency of burins, and the appearance of the so-called Kaszety point. Despite the early critique highlighting the weak empirical basis for the Perstunian, this culture has found its way into current literature with sites both in Poland and elsewhere being attributed to it (Siemaszko, 1999a, 1999b; Sinitsyna, 2002).

Likewise, Szymczak also identified the Wolkushian as a separate cultural unit (Szymczak, 1995). The territory of the Wolkushian overlaps with that of the Perstunian, as artefacts of both units are found at the same sites (Szymczak, 1995). Wolkushian lithic tool forms are also similar to the Perstunian with single- and double-platform blade cores, and varying forms of scrapers, burins, and tanged points. For Szymczak (1995), the distinctive features of the Wolkushian include: a high frequency of double-platform cores, large core-like burins, large tanged points including forms with flat ventral retouch reminiscent of the Swiderian, large tanged points with no ventral retouch analogous to Brommean points, and smaller tanged points lacking any modifications of the ventral surface similar to Ahrensburgian points (Szymczak, 1995). Wolkushian elements have so far been recognized at nine sites—some seemingly homogenous, some mixed—from north-eastern Poland.

Further to the east, a suite of geographically tightly circumscribed cultures distinguished by large tanged points have been proposed. These are: 1) the Baltic Magdalenian/Vilnius group; 2) the Grensk culture; 3) the Krasnosillya/North Ukrainian group; 4) the Podolian; and 5) the Vyshegorian.

In Lithuania, the Baltic Magdalenian culture was first defined by Rimantienė (1971), who argued that it stemmed from the same Late Magdalenian origin as the Brommean. The tools characterizing this culture are single- and double-platform cores, various tanged point forms, short and broad scrapers, burins of different types, and combination tools. Smaller tanged points, it was argued, are the main difference between the Baltic Magdalenian and the Brommean, which in turn implied a slightly later date for the Lithuanian Late Palaeolithic (Rimantienė, 1971). Later, this culture was rejected by some Lithuanian scholars and replaced with a classification that split the same material (Šatavičius, 2016). A recent review of the evidence has failed to find support for such detailed splitting (Ivanovaitė & Riede, 2018).

In Belarus, many Late Palaeolithic tanged point assemblages are attributed to the Grensk culture first defined by Bud'ko (1966) and argued to reflect a local development from eastern Epigravettian traditions. Later, a migration-based theory suggested the introduction of the Bromme/Lyngby culture as the source of this regional development (Zaliznyak, 1999). These two explanations continue to exist as the favoured, albeit opposing, hypotheses for the origin of the Grensk phenomenon (see Kolasau, 2018). Typical Grensk assemblages consist of single-platform and double-platform cores, although other (multiple platform and discoidal) forms are also found; various forms of scraper occur, as do truncated, dihedral, angle, and combination burins, notched tools, borers, flakes with obliquely retouched truncation, backed blades, and chopping tools. Tanged points and specifically asymmetrical points termed the ‘Grensk type’ characterize the eponymous assemblages (Kolasau, 2018).

In the Polesia region of Ukraine, the Krasnosillya culture was first distinguished by Zaliznyak (1999), one of the main advocates of Bromme/Lyngby migrations from Scandinavia to eastern Europe. To him, this migration was the source for all eastern European tanged point cultures. A typical trait of Krasnosillya lithic technology is its low tool-blank selectivity. Tools are mainly formed by intensive retouching of ad hoc blanks rather than standardized blades (Zaliznyak, 1999). These assemblages comprise mainly single-platform cores, in addition to burins and tanged points of variable size (Zaliznyak, 1999).

In Russia, two pertinent archaeological cultures are identified, the Podolian of the Upper Volga region and the Vyshegorian of the Upper Dnieper Basin, with both autochthonous and migration theories proposed to understand them (Sinitsyna, 2002, 2004). The Podolian is viewed as a Brommean analogue resulting from earlier dispersals (Sinitsyna, 2002, 2004). Characteristic lithics include single- and double-platform cores, large tanged points, burins made from broken tanged points, various scrapers, and axes produced from flakes. The Vyshegorian, in contrast, represents an autochthonous development from the Epigravettian (Sinitsyna, 2013). Typical assemblages include conical, wedge-shaped single- and double-platform prismatic cores, tanged and shouldered points with lateral retouch, various burin types, scrapers, notched tools, and axes (Sinitsyna, 2002, 2004). Like most Late Palaeolithic cultures in eastern Europe, these two cultures are poorly defined chronologically. While the Podolian is dated to the Allerød/Younger Dryas through typological and geological inference, a single relevant radiocarbon date (LE-5029) places it at 9180 ± 75 bp (Sinitsyna, 2004). Calibrated with OxCal 4.3 (Bronk Ramsey, 2009) and using the IntCal 13 calibration curve (Reimer et al., 2013), this yields an early Holocene date of 10,550–10,220 cal bp.

Kobusiewicz (2009a, 2009b) has argued that the various proposed eastern European cultures identified in the basis of large tanged points are epistemologically weak because:

1. 1. these cultures are often based on limited material derived from poorly constrained assemblages

2. 2. large tanged points most commonly occur with other elements (e.g. arch-backed points, small tanged points) argued to be indicative of other cultures

3. 3. the size of the proposed territories does not correspond to meaningful territorial sizes observed in the ethnographic record (see Sauer & Riede, 2019), and

4. 4. the argued differences in the shape of the diagnostic artefacts are too slight.

Following up on this critique, Sauer and Riede (2019) have also shown that artefact frequencies, used in the Bordian tradition as a cultural designator (see Salomonsson, 1964; Kozłowski & Kozłowski, 1979), do not yield meaningful results, especially when formal types are few and ambiguous and assemblages are most commonly derived from surface collections. Contemporaneous osseous artefacts or other non-lithic elements are exceedingly rare and hence play a very limited role in cultural taxonomy, leaving the supposedly diagnostic projectile point forms as the foundation of contemporary cultural taxonomies. All this makes it a pressing matter to examine the large tanged points of eastern Europe, with the aim of revealing shape variations that are structured temporally and/or spatially. In the following, we build on earlier GMM analyses of tanged points in northern Europe (Serwatka & Riede, 2016; Serwatka, 2018), but with a specific focus on eastern Europe and with a particular aim to uncover, if possible, meaningful hierarchical structure within this key artefact class.

Materials and Methods

To investigate the appropriateness of the current nomenclature used throughout the Late Palaeolithic of eastern Europe, a two-dimensional GMM methodology is used here, drawing on illustrations of 177 complete tanged points from seventy-two archaeological contexts, distributed across sixty-one sites. Examples come from Poland, Belarus, Lithuania, western Russia, and Ukraine (Figure 3), and include cultural taxonomic attributions to the Baltic Magdalenian, Bromme, Grensk, Krasnosillya, Perstunian, Podolian, Vyshegorian, and Wolkushian units. This is complemented by examples of the Bromme culture from western Europe (n = 49), including specimens from the eponymous Bromme site (Mathiassen, 1946), and, as a control group, mid-Holocene ‘Type A’ large tanged points from the Pitted Ware culture (n = 24) which infamously resemble Late Palaeolithic specimens (Fischer, 1985). Therefore, a total of 250 lithic illustrations were examined (Table 2). We are aware that the size of this sample is limited, but it does reflect the truly limited selection of artefacts on which some of the cultural taxonomic units are based and the fact that we restricted our sample to complete specimens. While any statistical approach should work with as large a sample size as possible, we note that the use of lithic drawings, as presented by their authors, does allow testing of cultural taxonomic assessments because complete and supposedly typical or ideal specimens are usually selected for drawing with the strong epistemic implication that they are representative of taxonomic entities in general (see Lopes, 2009). One implication of this original selection bias inherent in the literature is that our analysis probably addresses merely a fraction of the actual lithic variability found in the Late Palaeolithic in the region, but stands as a direct cultural taxonomic test vis-a-vis the existing corpus of literature.

Figure 3. Map of all sites examined in this study. 1) Baroŭka; 2) Chilczyce; 3) Chvojnaja; 4) Koromka; 5) Krasnasieĺski; 6) Motol; 7) Woronowka; 8) Elemly Sø; 9) Hjarup Mose; 10) Rolykkevej; 11) Rundebakke; 12) Sølystgaard; 13) Anholt; 14) Søtofte; 15) Føllenslev; 16) Smedegaarde; 17) Kainsbakke; 18) Bromme; 19) Trollesgave; 20) Bro; 21) Alt Duvenstedt; 22) Dohnsen; 23) Sassenholz; 24) Baltašiškės; 25) Derežnyčia; 26) Duba; 27) Ežerynas; 28) Glūkas; 29) Glyno Pelkė; 30) Gribaša; 31) Kašėtos; 32) Katra; 33) Lieporiai; 34) Marcinkonys; 35) Margių; 36) Maskauka; 37) Merkys-Ūla; 38) Mitriškės; 39) Rudnia; 40) Varėna; 41) Varėnė; 42) Vilnius; 43) Burdeniszki: 44) Dziewule-Piaski; 45) Krzemienne; 46) Maćkowa Ruda; 47) Płaska; 48) Stańkowicze; 49) Suraż; 50) Wolkusz; 51) Zusno; 52) Podol; 53) Ust-Tudovka; 54) Anosovo; 55) Vishegore; 56) Tieply Ruchey; 57) Krasnosillya; 58) Lipa; 59) Liutka; 60) Rudnya; 61) Velyky Midsk.

Table 2. Dataset used in this study (n = 250).

To examine shape variation among these specimens and taxonomic units, elliptic Fourier analysis (EFA) was used. EFA is a method of closed-outline shape analysis grounded on the decomposition of closed outlines (produced through the creation of semi-landmarks) into an infinite series of repeating trigonometric functions (harmonics; see Caple et al., 2017). EFA has the advantage of not requiring data points to be equal in number, or evenly spaced, allowing more closely-spaced data points on segments of high curvature and artefact complexity (Rohlf & Archie, 1984; Crampton, 1995). EFA is now commonplace in the exploratory and statistical analysis of archaeological stone tool shapes (Gero & Mazzullo, 1984; Saragusti et al., 2005; Iovita, 2009, 2010; Serwatka, 2015; Iovita et al., 2017).

All illustrations (.png) were first synthesized into one thin-plate spline (.tps) file, a common file format for GMM analyses. This was carried out in tpsUtil v.1.69. Cartesian coordinates and positions for each image were created using the ‘Outline object’ function in tpsDig2 v.2.27 and pixel noise eliminated in tpsDig2 (Rohlf, 2015). As these outlines do not require the same number of landmarks, and in order to capture as much of the original shape as possible, the raw outline was retained (Figure 4). Thus, the tanged point specimens feature an average of 1544 Cartesian coordinates. In standardizing all outlines prior to EFA, all specimens were normalized to a common centroid (0,0) and rescaled using their centroid size as suggested by Bonhomme et al. (2017). Normalization through rotation was unnecessary as this is incorporated through subsequent elliptic fitting. In selecting an appropriate number of harmonics necessary to capture tanged point shape (here defined as 99.9 per cent harmonic power), the ‘calibrate_harmonicpower_efourier’ function, supported by the ‘calibrate_reconstructions_efourier’ and ‘calibrate_deviations_efourier’ functions in Momocs v.1.2.9 (Bonhomme et al., 2014) were used. For 99 per cent harmonic power, eleven harmonics were retained.

Figure 4. XY transformations for the first three principal components (82.1 per cent cumulative shape variance).

To assess the robustness and structure of the current taxonomy, the elliptic Fourier descriptors were first subjected to exploratory principal components analysis (EFA-PCA), an ordination-based method for exploring the underlying shape structure within a GMM dataset. In visualizing differences and similarities among different archaeological units, 66 per cent confidence ellipses are employed. The contributions of each major principal axis were examined through a scree plot, along with the specific XY shape transformations and configurations. Discrimination-based analyses were not undertaken as a number of groups do not meet suggested sample size values and as our a priori confidence in the groups’ validity is low, given the research-historical and epistemic concerns outlined above. Such concerns make discriminant analyses unsuitable as a test of taxonomic validity (Klecka, 1980; McGarigal et al., 2000; Kovarovic et al., 2011). To explore tanged point variation between different archaeological units through a statistical framework, a multivariate analysis of variance (MANOVA), through a Hotelling–Lawley, of 99 per cent cumulative shape variance (the first twenty-one principal components) was carried out. If significant, pairwise testing (through a Pillai Trace) is employed to understand the relationship between specific archaeological units. Statistical significance is defined here by an alpha level of 0.01, with a null hypothesis of no difference between taxonomic units.

Finally, to better understand the underlying structure and degree of similarity among archaeological units, agglomerative hierarchical cluster analysis was adopted. Agglomerative hierarchical clustering works on dissimilarity matrices and builds a hierarchical structure from individual shapes by progressively merging clusters (Shennan, 1997; Claude, 2008). Here, agglomerative hierarchical clustering (complete linking) is employed to visualize, quantify, and hence qualify the degree of dissimilarity between all artefacts in relation to their proposed archaeological unit membership. A dendrogram using the first twenty-two principal components and a Euclidean distance measure is employed here.

All analyses were carried out in Momocs v.1.2.9 (Bonhomme et al., 2014) for the R Environment (R Development Core Team, 2017). Complementary R packages including tidyverse v.1.2.1 (https://cran.r-project.org/web/packages/tidyverse/index.html and ggtree v.10.5, Yu et al., 2017) were used for data visualization and transformation. The Open Science guidelines from Marwick (2017) were followed and the .tps file, the metadata, and annotated R script can be found on the Open Science Framework (https://osf.io/agrwb/). All associated code, data, and figures can also be found on GitHub: https://github.com/CSHoggard/-Eastern-Europe-Tanged-Points.

Results

An examination of tanged point outline shape through EFA-PCA reveals that the first three principal components feature greater than 5 per cent shape variance, and total 82.1 per cent cumulative shape variance. The first principal component (57.7 per cent shape variance) ranges from tanged points with narrow tangs, shoulders, and blade edges to wider forms, whereas the second principal component (16.4 per cent shape variance) represents an asymmetric transformation, specifically the positioning of the shoulder or blade edge with the greatest convexity. The third principal component (8.0 per cent shape variance) extends from elongated to short and wider tang forms. For a visual guide to these first three principal components see Figure 4, and for further information on the transformations of subsequent principal components please refer to the R script noted above (https://osf.io/agrwb/).

When the shape variation is explored through the different archaeological units, the PCA analysis (Figure 5) highlights the difficulty in classifying certain archaeological units by tanged point shape, and, conversely, in distinguishing between specific units. In the first principal component, Podolian, Grensk, and Vyshegorian groups occupy a similar morphospace (their confidence ellipses overlap) with negative PC1 scores indicative of wider tanged forms. In contrast, Pitted Ware examples have the greatest proportion of positive PC1 scores indicative of slender tanged forms, to an extent where there is little overlap with other archaeological units. In the graph centroid (shapes more typical of the mean), several overlapping units can be observed, including the Wolkushian, Bromme (both regions), Krasnosillya, and Baltic Magdalenian. This overlap largely continues into the second principal component, with these same units overlapping.

Figure 5. Principal component analysis of Fourier coefficients calculated for Late Palaeolithic tanged points in eastern Europe. Top: PC1 and PC2 (74.1 per cent cumulative variance). Middle: PC2 and PC3 (24.46 per cent cumulative variance). Bottom: PC1 and PC3 (66.3 per cent cumulative variance).

Regarding the second and third principal components, considerably greater variation is exhibited in many of the archaeological units, with the Perstunian and Pitted Ware examples most strongly constrained. As the second principal component represents asymmetric variation in the accentuation of the tang, dorsal/ventral siding may help explain this great variation. The first and third principal components may better represent the actual variation exhibited by the archaeological units, as these represent symmetric changes in tanged point shape. However, the distribution of artefacts in this plot largely mirrors the first plot, with a distinct Pitted Ware cluster, similarities in Podolian, Vyshegorian, and Grensk forms, and a mixture of units in the graph centroid.

With 99 per cent cumulative shape variance, a MANOVA was carried out and highlighted statistical significance to the desired 0.01 alpha level (Hotelling-Lawley: 1.7604, F: 2.0326, p: < 0.0001), demonstrating difference in artefact shape among all tanged points. Given the significance of the overall test, further tests for pairwise differences were undertaken (Table 3). In this, differences can be observed, specifically differences between: 1) Pitted Ware (Type A) and all other taxonomic units; 2) the Baltic Magdalenian and Bromme (western European) units; 3) the Grensk and Bromme (western European) units; 4) the Grensk and Krasnosillya units; and 5) the Grensk and Wolkushian units. Interestingly, no statistical difference was observed between the two Bromme units (Pillai Trace: 0.1073, F: 1.5931, p: 0.1897), indicating no difference in artefact shape; no difference between Bromme examples in eastern Europe and any other eastern European unit was also detected (see Table 3). The consistently identified difference between the putative Late Glacial cultural units identified by large tanged points and the much later Pitted Ware culture points is notable and encouraging. Pitted Ware culture points tend to be more symmetric than Late Palaeolithic specimens (Dev & Riede, 2012) and are more likely to have been arrowheads (Bye-Jensen, 2011), whereas earlier large tanged points are more probably dart-points (Riede, 2009). The ballistic form and size constraints on dart-heads are somewhat laxer compared to arrowheads (see Shott, 1997) and this appears to be reflected in the consistently narrow shape of our Pitted Ware specimens.

Table 3. Pairwise MANOVA for examined archaeological units. Green: 0.01 significance level; yellow: 0.05 significance level; *small sample size (n ≤20).

A hierarchical cluster analysis of all individual tanged points (Figure 6) indicates that very few of the artefacts assigned to the different archaeological units demonstrate consistent grouping. Some sites show minor clustering, such as Koromka (artefact IDs 63–68), perhaps indicative of locally or individually shared behaviour. Yet, on a higher branch level, no clustering consistent with traditional cultural taxonomic units is observed. The sole exception is the Pitted Ware culture (Type A), with the majority of specimens clustering within one or two clades, further highlighting the degree of standardization in this specific tanged point.

Figure 6. Hierarchical agglomerative clustering (complete linkage) of all tanged point outlines (n = 250) and their associated taxonomic unit (IDs correspond to the dataset associated with this article).

Discussion

Ethnographic observations of group identity encoded in lithic projectile points (e.g. Wiessner, 1983; Sinopoli, 1991) are often cited as the core rationale for grounding Palaeolithic cultural taxonomies on this artefact. In the Late Palaeolithic of Europe, projectile points are also, implicitly or explicitly, taken to be the primary artefact class defining cultural groupings. Yet, our investigations into research history and the GMM analyses reported here indicate that existing classifications of the Late Palaeolithic cultures anchored in lithic projectile point forms in north-eastern Europe at least are not robust. It appears that there are no consistent differences in projectile point shape between the various cultures as currently proposed. In sum, the diverse and highly variable morphologies of large tanged projectile points found in the region prevents any robust classification of this material and hence makes building larger-scale cultural taxonomies difficult—at least those that aim to distinguish regionally or locally circumscribed units on the basis of lithic projectile points.

The general simplicity of form and similarity of Late Palaeolithic tanged points makes it hard to draw any conclusions about intercultural diversity based on this artefact class alone. Notably, simplicity and variability also characterize other aspects of Late Palaeolithic lithic technology, which is straightforward and generic, relying on raw materials of variable quality and rather ad hoc core exploitation strategies, both in the western (Fischer, 1991: 116; Barton, 1992: 192; Madsen, 1992: 128; Johansen, 2000: 22) and eastern parts of northern Europe (Rimantienė, 1971; Szymczak, 1991, 1995; Sinitsyna, 2002). Although we did not analyse other tool, blade, or core forms at the same level of detail, our review of these elements commonly used as classificatory auxiliaries also shows substantial overlap between units.

Whether this overall similarity in Late Palaeolithic technology and artefact shapes is primarily caused by shared ancestry or whether it suggests a substantial degree of convergent technological evolution (O'Brien et al., 2018) remains to be investigated in greater detail. Recent genomic studies are revising migrantionist theories. Villalba-Mouco et al. (2019), for instance, suggest that, by 15,000 years ago, hunter-gatherers of distinctly different ancestry admixed with and replaced groups associated with the Magdalenian in parts of Europe. While this can be interpreted to indicate that Magdalenian foragers did not reach eastern Europe, as suggested by Rimantienė (1971), and that the Late Palaeolithic colonization of eastern Europe should instead be associated with the Epigravettian, as suggested by Bud'ko (1966), the logic of linking culturally defined groups with genetic clusters itself needs urgent attention (see Riede et al., 2019). The absence of secure radiocarbon dates associated with eastern European tanged point assemblages, as well as the paucity of organic remains including human remains suitable for genomic interrogration, make the matter more complicated by not allowing a secure placement of these assemblages in the wider chronological context of the Late Palaeolithic.

It is our worry that the school of thought that links ethnicity with prehistoric culture history—shown to be prevailing in eastern Europe (Barford, 1996; Wyszomirska-Webert, 1996)—has been driving the profligate definition of Late Palaeolithic cultures; yet they cannot readily be discriminated in a quantitative, inter-regional perspective. Much like the Levantine Epipalaeolithic, Late Palaeolithic Europe may thus be largely populated by ‘phantom cultures’ (Barton & Neeley, 1996: 139).

Conclusion

Cultural taxonomy is as essential to archaeological enquiry as it is unfashionable. For most periods of the European Palaeolithic, multiple and sometimes competing cultural taxonomic schemata have been proposed, usually with reference to key artefact classes such as projectile points. Our current taxonomies have accumulated over long periods of changing theoretical, conceptual, and methodological paradigms and in tandem with broader socio-political changes. Most workers are aware of such caveats, yet culturally-laden typological designations are frequently used in archaeological research and heritage management alike, reinforcing the impression of strong regional distinctiveness in the archaeological record (see Barford, 1996; Riede, 2017). The Late Palaeolithic of eastern Europe is no exception, but our critical investigation into research history and novel analyses of tanged point shapes have shown that many currently defined regional groupings are not as diagnostically distinct as previously proposed.

In our analysis, we have focused exclusively on large tanged points. Naturally, other aspects of material culture may allow us to better discriminate between cultural units. In particular, lithic reduction techniques, as analysed through operational chains, have been proposed as a key method (e.g. Damlien et al., 2018). Problematically, however, such time-consuming analyses usually begin by selecting assemblages that are pre-classified by traditional typological means (mostly through projectile points) and hence tend to replicate traditional taxonomies. Furthermore, limited sample sizes and as yet unexamined degrees of inter-observer variability speak against operational chain analysis as necessarily a better way of resolving cultural taxonomic questions. Most probably, a judicious combination of qualitative and quantitative methods will provide the hoped-for solution, although available methodologies (e.g. Tostevin, 2013) have yet to be applied to the Late Palaeolithic of Europe. By this token, our analysis should be understood as a new parsimonious lumping hypothesis to be tested against alternative definitions using similarly transparent, data-driven approaches.

Nonetheless, it is critical that we clarify these issues and begin to build more robust cultural taxonomies as both palaeoenvironmental scientists and geneticists are increasingly looking to explain Late Pleistocene human demographic processes—and they tend to incorporate archaeologically defined units under the reasonable assumption that these are robust and can be understood as proxies for past populations (see Riede et al., 2019). While we strongly welcome the ambitions and intentions behind such novel bio-cultural approaches, we caution equally strongly against uncritically deploying the cultural taxonomic units of the northern European Late Palaeolithic as they are currently defined. New methods, such as geometric morphometrics, coupled with, for instance, cultural phylogenetics are offering innovative ways to construct archaeological taxonomies. Such cultural phylogenies represent hypotheses of historical patterns and processes (see O'Brien et al., 2008). They can be used to discriminate between divergent and convergent cultural evolution, and they offer ways of more formally and transparently defining nested cultural taxonomies. Future research should seek to include as wide a range of material culture information as possible. The ever-increasing availability of literature is facilitating such comparative approaches, yet barriers to inter-regional integration persist. Aligning and opening archaeological datasets across research traditions, as we have attempted here, is a prerequisite for overhauling integrative comparative approaches.