A geometric morphometric relationship predicts stone flake shape and size variability

The archaeological record represents a window onto the complex relationship between stone artefact variance and hominin behaviour. Differences in the shapes and sizes of stone flakes—the most abundant remains of past behaviours for much of human evolutionary history—may be underpinned by variation in a range of different environmental and behavioural factors. Controlled flake production experiments have drawn inferences between flake platform preparation behaviours, which have thus far been approximated by linear measurements, and different aspects of overall stone flake variability (Dibble and Rezek J Archaeol Sci 36:1945–1954, 2009; Lin et al. Am Antiq 724–745, 2013; Magnani et al. J Archaeol Sci 46:37–49, 2014; Rezek et al. J Archaeol Sci 38:1346–1359, 2011). However, when the results are applied to archaeological assemblages, there remains a substantial amount of unexplained variability. It is unclear whether this disparity between explanatory models and archaeological data is a result of measurement error on certain key variables, whether traditional analyses are somehow a general limiting factor, or whether there are additional flake shape and size drivers that remain unaccounted for. To try and circumvent these issues, here, we describe a shape analysis approach to assessing stone flake variability including a newly developed three-dimensional geometric morphometric method (‘3DGM’). We use 3DGM to demonstrate that a relationship between platform and flake body governs flake shape and size variability. Contingently, we show that by using this 3DGM approach, we can use flake platform attributes to both (1) make fairly accurate stone flake size predictions and (2) make relatively detailed predictions of stone flake shape. Whether conscious or instinctive, an understanding of this geometric relationship would have been critical to past knappers effectively controlling the production of desired stone flakes. However, despite being able to holistically and accurately incorporate three-dimensional flake variance into our analyses, the behavioural drivers of this variance remain elusive.

[1]  John D. Speth,et al.  Miscellaneous Studies in Hard-Hammer Percussion Flaking: The Effects of Oblique Impact , 1975, American Antiquity.

[2]  Chris Clarkson,et al.  Estimating original flake mass on blades using 3D platform area: problems and prospects , 2014 .

[3]  Hansjürgen Müller-Beck,et al.  A History of Flint-Knapping Experimentation, 1838-1976 [and Comments and Reply] , 1978, Current Anthropology.

[4]  F. Bordes,et al.  Étude comprative des différentes techniques de taille du silex et des roches dures , 1947 .

[5]  Chen Shen,et al.  A Preliminary Study of the Anvil-Chipping Technique: Experiments and Evaluations , 2000 .

[6]  Michael Shott,et al.  Exploring New Approaches to Lithic Analysis: Laser Scanning and Geometric Morphometrics , 2010 .

[7]  Steven L. Kuhn,et al.  The Big Deal about Blades: Laminar Technologies and Human Evolution , 1999 .

[8]  Nicholas J. Conard,et al.  Evaluating morphological variability in lithic assemblages using 3D models of stone artifacts , 2012 .

[9]  D. Crabtree Stoneworker's Approach To Analyzing and Replicating the Lindenmeirer Folsom , 1966 .

[10]  Harold L. Dibble,et al.  Handbook of Paleolithic Typology: Lower and Middle Paleolithic of Europe , 1993 .

[11]  Erik Otárola-Castillo,et al.  geomorph: an r package for the collection and analysis of geometric morphometric shape data , 2013 .

[12]  F. Bookstein,et al.  Neurobehavioral effects of prenatal alcohol: Part II. Partial least squares analysis. , 1989, Neurotoxicology and teratology.

[13]  Leore Grosman,et al.  Reaching the Point of No Return: The Computational Revolution in Archaeology , 2016 .

[14]  John D Speth,et al.  Experimental investigation of hard-hammer percussion flaking , 1974 .

[15]  Harold L. Dibble,et al.  The relative effects of core surface morphology on flake shape and other attributes , 2011 .

[16]  Marie-Louise Inizan,et al.  Préhistoire de la pierre taillée , 1980 .

[17]  P. Gunz,et al.  Advances in Geometric Morphometrics , 2009, Evolutionary Biology.

[18]  B. Cotterell,et al.  The Formation of Flakes , 1987, American Antiquity.

[19]  Michael J. Rogers,et al.  Landscape-scale variation in hominin tool use: Evidence from the Developed Oldowan. , 2008, Journal of human evolution.

[20]  Peter Ditchfield,et al.  Raw material quality and Oldowan hominin toolstone preferences: evidence from Kanjera South, Kenya , 2009 .

[21]  P. Hiscock,et al.  Generalization, inference and the quantification of lithic reduction , 2010 .

[22]  F. Bordes Typologie du paléolithique : ancien et moyen , 1988 .

[23]  George H. Odell,et al.  Stone Tool Research at the End of the Millennium: Procurement and Technology , 2000 .

[24]  Harold L. Dibble,et al.  On the Utility and Economization of Unretouched Flakes: The Effects of Exterior Platform Angle and Platform Depth , 2013, American Antiquity.

[25]  H. Dibble Platform Variability and Flake Morphology: A Comparison of Experimental and Archaeological Data and Implications for Interpreting Prehistoric Lithic Technological Strategies , 1997 .

[26]  Shannon P. McPherron,et al.  Edge Length and Surface Area of a Blank: Experimental Assessment of Measures, Size Predictions and Utility , 2015, PloS one.

[27]  Chris Clarkson,et al.  A new method for accurately and precisely measuring flake platform area , 2016 .

[28]  Sanford Weisberg,et al.  An R Companion to Applied Regression , 2010 .

[29]  Harold L. Dibble,et al.  Introducing a new experimental design for controlled studies of flake formation: results for exterior platform angle, platform depth, angle of blow, velocity, and force , 2009 .

[30]  Éric Boëda,et al.  Approche technologique du concept Levallois et évaluation de son champ d'application : étude de trois gisement saaliens et weichseliens de la France septentrionale , 1986 .

[31]  D. Braun,et al.  Archaeological inference and Oldowan behavior. , 2006, Journal of human evolution.

[32]  D E Crabtree Flaking Stone with Wooden Implements , 1970, Science.

[33]  J. Speth Mechanical Basis of Percussion Flaking , 1972, American Antiquity.

[34]  Don E. Crabtree,et al.  The Corbiac blade technique and other experiments , 1969 .

[35]  Stefan Schlager,et al.  Morpho and Rvcg – Shape Analysis in R: R-Packages for Geometric Morphometrics, Shape Analysis and Surface Manipulations , 2017 .

[36]  F J Rohlf,et al.  Use of two-block partial least-squares to study covariation in shape. , 2000, Systematic biology.

[37]  William Andrefsky,et al.  A Consideration of Blade and Flake Curvature , 1986 .

[38]  D. Crabtree Mesoamerican Polyhedral Cores and Prismatic Blades , 1968, American Antiquity.

[39]  Michael J. O'Brien,et al.  Test, Model, and Method Validation: The Role of Experimental Stone Artifact Replication in Hypothesis-driven Archaeology , 2016 .

[40]  D. Stout Stone toolmaking and the evolution of human culture and cognition , 2011, Philosophical Transactions of the Royal Society B: Biological Sciences.

[41]  Raymond Mauldin,et al.  Experiments in Lithic Technology , 1989 .

[42]  Harold L. Dibble,et al.  Flake variation in relation to the application of force , 2014 .

[43]  Peter Hiscock,et al.  Estimating original flake mass from 3D scans of platform area , 2011 .

[44]  Stanley A. Ahler,et al.  Mass Analysis of Flaking Debris: Studying the Forest Rather Than the Tree , 2008 .

[45]  F. Rohlf,et al.  Extensions of the Procrustes Method for the Optimal Superimposition of Landmarks , 1990 .

[46]  J. Vergès,et al.  Measuring Retouch Intensity in Lithic Tools: A New Proposal Using 3D Scan Data , 2015 .

[47]  Daniel S. Amick,et al.  An Evaluation of Debitage Produced by Experimental Bifacial Core Reduction of a Georgetown Chert Nodule , 1988 .