Intrinsic shape analysis in archaeology: A case study on ancient sundials

IF 2.1 3区计算机科学 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

ACM Journal on Computing and Cultural Heritage Pub Date : 2023-06-30 DOI:https://dl.acm.org/doi/10.1145/3606698

Martin Hanik, Benjamin Ducke, Hans-Christian Hege, Friederike Fless, Christoph von Tycowicz

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引用次数: 0

Abstract

The fact that the physical shapes of man-made objects are subject to overlapping influences—such as technological, economic, geographic, and stylistic progressions—holds great information potential. On the other hand, it is also a major analytical challenge to uncover these overlapping trends and to disentagle them in an unbiased way. This paper explores a novel mathematical approach to extract archaeological insights from ensembles of similar artifact shapes. We show that by considering all shape information in a find collection, it is possible to identify shape patterns that would be difficult to discern by considering the artifacts individually or by classifying shapes into predefined archaeological types and analyzing the associated distinguishing characteristics.

Recently, series of high-resolution digital representations of artifacts have become available. Such data sets enable the application of extremely sensitive and flexible methods of shape analysis. We explore this potential on a set of 3D models of ancient Greek and Roman sundials, with the aim of providing alternatives to the traditional archaeological method of “trend extraction by ordination” (typology). In the proposed approach, each 3D shape is represented as a point in a shape space—a high-dimensional, curved, non-Euclidean space. Proper consideration of its mathematical properties reduces bias in data analysis and thus improves analytical power. By performing regression in shape space, we find that for Roman sundials, the bend of the shadow-receiving surface of the sundials changes with the latitude of the location. This suggests that, apart from the inscribed hour lines, also a sundial’s shape was adjusted to the place of installation. As an example of more advanced inference, we use the identified trend to infer the latitude at which a sundial, whose location of installation is unknown, was placed.

We also derive a novel method for differentiated morphological trend assertion, building upon and extending the theory of geometric statistics and shape analysis. Specifically, we present a regression-based method for statistical normalization of shapes that serves as a means of disentangling parameter-dependent effects (trends) and unexplained variability. In addition, we show that this approach is robust to noise in the digital reconstructions of the artifact shapes.

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考古学中的内在形状分析:以古代日晷为例

人造物体的物理形状受到技术、经济、地理和风格发展等多重影响，这一事实蕴含着巨大的信息潜力。另一方面，揭示这些重叠的趋势并以公正的方式将它们分离开来也是一项重大的分析挑战。本文探讨了一种新颖的数学方法，从类似的人工制品形状的集合中提取考古见解。我们表明，通过考虑发现集合中的所有形状信息，有可能通过单独考虑人工制品或通过将形状分类为预定义的考古类型并分析相关的区分特征来识别难以识别的形状模式。最近，一系列高分辨率的文物数字表示已经成为可能。这样的数据集使应用极其敏感和灵活的方法的形状分析。我们在一组古希腊和罗马日晷的3D模型上探索了这种潜力，目的是为传统的考古方法“通过排序提取趋势”(类型学)提供替代方案。在提出的方法中，每个三维形状被表示为形状空间中的一个点——一个高维的、弯曲的、非欧几里德空间。适当考虑其数学性质可以减少数据分析中的偏差，从而提高分析能力。通过在形状空间中进行回归，我们发现对于罗马日晷，日晷的阴影接收面弯曲随位置的纬度而变化。这表明，除了刻有时线外，日晷的形状也根据安装地点进行了调整。作为一个更高级推理的例子，我们使用确定的趋势来推断安装位置未知的日晷所在的纬度。在几何统计和形状分析理论的基础上，我们还推导了一种新的微分形态趋势断言方法。具体来说，我们提出了一种基于回归的形状统计归一化方法，作为一种解开参数依赖效应(趋势)和无法解释的变异性的手段。此外，我们还证明了该方法在人工形状的数字重建中对噪声具有鲁棒性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACM Journal on Computing and Cultural Heritage Arts and Humanities-Conservation

CiteScore

4.60

自引率

8.30%

发文量

期刊介绍： ACM Journal on Computing and Cultural Heritage (JOCCH) publishes papers of significant and lasting value in all areas relating to the use of information and communication technologies (ICT) in support of Cultural Heritage. The journal encourages the submission of manuscripts that demonstrate innovative use of technology for the discovery, analysis, interpretation and presentation of cultural material, as well as manuscripts that illustrate applications in the Cultural Heritage sector that challenge the computational technologies and suggest new research opportunities in computer science.