Capturing Natural-Colour 3D Models of Insects for Species Discovery and Diagnostics

Collections of biological specimens are fundamental to scientific understanding and characterization of natural diversity—past, present and future. This paper presents a system for liberating useful information from physical collections by bringing specimens into the digital domain so they can be more readily shared, analyzed, annotated and compared. It focuses on insects and is strongly motivated by the desire to accelerate and augment current practices in insect taxonomy which predominantly use text, 2D diagrams and images to describe and characterize species. While these traditional kinds of descriptions are informative and useful, they cannot cover insect specimens “from all angles” and precious specimens are still exchanged between researchers and collections for this reason. Furthermore, insects can be complex in structure and pose many challenges to computer vision systems. We present a new prototype for a practical, cost-effective system of off-the-shelf components to acquire natural-colour 3D models of insects from around 3 mm to 30 mm in length. (“Natural-colour” is used to contrast with “false-colour”, i.e., colour generated from, or applied to, gray-scale data post-acquisition.) Colour images are captured from different angles and focal depths using a digital single lens reflex (DSLR) camera rig and two-axis turntable. These 2D images are processed into 3D reconstructions using software based on a visual hull algorithm. The resulting models are compact (around 10 megabytes), afford excellent optical resolution, and can be readily embedded into documents and web pages, as well as viewed on mobile devices. The system is portable, safe, relatively affordable, and complements the sort of volumetric data that can be acquired by computed tomography. This system provides a new way to augment the description and documentation of insect species holotypes, reducing the need to handle or ship specimens. It opens up new opportunities to collect data for research, education, art, entertainment, biodiversity assessment and biosecurity control.

[1]  A. Laurentini,et al.  The Visual Hull Concept for Silhouette-Based Image Understanding , 1994, IEEE Trans. Pattern Anal. Mach. Intell..

[2]  Kiriakos N. Kutulakos,et al.  A Theory of Shape by Space Carving , 2000, International Journal of Computer Vision.

[3]  John La Salle,et al.  Whole-drawer imaging for digital management and curation of a large entomological collection , 2012, ZooKeys.

[4]  B. Metscher MicroCT for comparative morphology: simple staining methods allow high-contrast 3D imaging of diverse non-mineralized animal tissues , 2009, BMC Physiology.

[5]  Matt Adcock,et al.  3D Reconstruction from multi-view images of a Christmas Beetle , 2014 .

[6]  Michael Goesele,et al.  High Resolution Acquisition of Detailed Surfaces with Lens-Shifted Structured Light , 2010, VAST.

[7]  H. Godfray Challenges for taxonomy , 2002, Nature.

[8]  Rika Smith Mcnally,et al.  THE HARVARD GLASS FLOWERS: MATERIALS AND TECHNIQUES , 1993 .

[9]  Michael Goesele,et al.  Multi-View Stereo Revisited , 2006, 2006 IEEE Computer Society Conference on Computer Vision and Pattern Recognition (CVPR'06).

[10]  P. Backwell,et al.  Morphometric measurements of dragonfly wings: the accuracy of pinned, scanned and detached measurement methods , 2013, ZooKeys.

[11]  育久 満上,et al.  Bundler: Structure from Motion for Unordered Image Collections , 2011 .

[12]  Nico Cellinese,et al.  Mass digitization of scientific collections: New opportunities to transform the use of biological specimens and underwrite biodiversity science , 2012, ZooKeys.

[13]  Vincent S. Smith,et al.  Bringing collections out of the dark , 2012, ZooKeys.

[14]  Ángel M. Felicísimo,et al.  Analysis of Uncertainty and Repeatability of a Low-Cost 3D Laser Scanner , 2012, Sensors.

[15]  H. Opower Multiple view geometry in computer vision , 2002 .

[16]  Gregor Hagedorn,et al.  Biodiversity into your hands - A call for a virtual global natural history ‘metacollection’ , 2013, Frontiers in Zoology.

[17]  Andrew Hamilton,et al.  Nomenclatural benchmarking: the roles of digital typification and telemicroscopy , 2012, ZooKeys.

[18]  Vincent S. Smith,et al.  No specimen left behind: industrial scale digitization of natural history collections , 2012, ZooKeys.

[19]  Anthon Voigt,et al.  Visual hulls from single uncalibrated snapshots using two planar mirrors , 2004 .

[20]  Yongsheng Gao,et al.  Primitive-based 3D structure inference from a single 2D image for insect modeling: Towards an electronic field guide for insect identification , 2010, 2010 11th International Conference on Control Automation Robotics & Vision.

[21]  Maurizio Muzzupappa,et al.  3D reconstruction of small sized objects from a sequence of multi-focused images , 2014 .

[22]  Carlos Hernández,et al.  Shape from Photographs: A Multi-view Stereo Pipeline , 2010, Computer Vision: Detection, Recognition and Reconstruction.

[23]  Jean Ponce,et al.  Accurate, Dense, and Robust Multiview Stereopsis , 2010, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[24]  Richard Taylor,et al.  3D S.O.M. - A commercial software solution to 3D scanning , 2005, Graph. Model..

[25]  Takashi Maekawa,et al.  System for reconstruction of three-dimensional micro objects from multiple photographic images , 2011, Comput. Aided Des..

[26]  Sarah Faulwetter,et al.  Micro-computed tomography: Introducing new dimensions to taxonomy , 2013, ZooKeys.

[27]  Richard Szeliski,et al.  Computer Vision - Algorithms and Applications , 2011, Texts in Computer Science.

[28]  Michael Goesele,et al.  High resolution acquisition of detailed surfaces with lens-shifted structured light , 2012, Comput. Graph..

[29]  Paul T. Jackway,et al.  Accelerating taxonomic discovery through automated character extraction , 2009 .

[30]  Pavel Stoev,et al.  Revolving SEM images visualising 3D taxonomic characters: application to six species of the millipede genus Ommatoiulus Latzel, 1884, with description of seven new species and an interactive key to the Tunisian members of the genus (Diplopoda, Julida, Julidae) , 2013, ZooKeys.

[31]  Matt Adcock,et al.  Virtual 3D Models of Insects for Accelerated Quarantine Control , 2013, 2013 IEEE International Conference on Computer Vision Workshops.

[32]  Susan C. Kuzminsky,et al.  Three-dimensional laser scanning: potential uses for museum conservation and scientific research , 2012 .

[33]  Nesrine Akkari,et al.  Rotational Scanning Electron Micrographs (rSEM): A novel and accessible tool to visualize and communicate complex morphology , 2013, ZooKeys.

[34]  Richard Szeliski,et al.  A Comparison and Evaluation of Multi-View Stereo Reconstruction Algorithms , 2006, 2006 IEEE Computer Society Conference on Computer Vision and Pattern Recognition (CVPR'06).

[35]  Edmond Boyer,et al.  Exact polyhedral visual hulls , 2003, BMVC.

[36]  William G. Eberhard,et al.  A plea for digital reference collections and other science‐based digitization initiatives in taxonomy: Sepsidnet as exemplar , 2013 .

[37]  Edward Lank,et al.  Parts, image, and sketch based 3D modeling method , 2006, SBM'06.

[38]  Marc Pollefeys,et al.  Multi-view reconstruction using photo-consistency and exact silhouette constraints: a maximum-flow formulation , 2005, Tenth IEEE International Conference on Computer Vision (ICCV'05) Volume 1.

[39]  Pascal Fua,et al.  Efficient large-scale multi-view stereo for ultra high-resolution image sets , 2011, Machine Vision and Applications.