Educational technology

This MA thesis discusses the applications of immersive virtual reality technologies as a tool for studying archaeological excavation processes. The excavation of a structure at the Nassau Mills, a twentieth century milling complex in Peterborough, Ontario, is used as the case study. Structure from Motion (SfM) photogrammetry is used to digitize each excavation day as 3D models. These excavation days are visualized in the Nassau Mills Pavilion, which enables users to revisit the site on each excavation day, and view and measure structural contexts. This thesis explores a number of theories including: affordance theory, phenomenology, theories of perception, and spatial accuracy. It also discusses multi-user presence, spatial thinking, and wayfaring as notions for improving the way users collaborate, share, and study digitized archaeological data in virtual environments. This thesis offers new approaches to using supplementary digital recording techniques for archaeological excavation while providing a new VR collaborative platform for digitizing and disseminating archaeological data.

Author Keywords: Archaeological Database, Digital Archaeology, Multi-User Collaboration, SfM Photogrammetry, Spatial Thinking, Virtual Reality

The purpose of this study was to determine whether students at the Royal Military College (RMC) preferred electronic or print texts, their reasoning for this preference, and whether preference was related to student characteristics. Students (N=139) in a core course were provided with both formats. Due to a limited number of e-text users, statistical analyses of most variables were not possible. Instead, qualitative responses were analyzed to gain insight into student preferences. Students reported on the benefits and concerns of using each format. Their discussion of the benefits to the e-text and concerns about the print text were related to the level of convenience of each format. When considering the benefits of print and drawbacks of e-texts, students explained how these features could impact their reading experience. This study provides qualitative support for the continued use of print texts. Although they frequently use various forms of technology in the classroom, students are reluctant to study using electronic devices and feel their reading experience is best with print.

Author Keywords: Educational technology, Qualitative, Textbooks, Text preferences

Enhancing interpretive trails with smartphone technology may enrich the visitor's educational experience by stimulating deeper engagement and enjoyment that will improve immediate knowledge and help promote the development of environmental literacy. This connection between technology and environmental education can only be considered successful if enhanced enrichment and educational value is found in the integration. Currently there is a substantial gap in research on the incorporation of technology into an interpretive trail experience. For this study, information on the local fauna and flora was produced and linked to Quick Response Codes (QR codes) installed along an outdoor trail. The QR codes were designed to be read using the participant's personal smartphone. Immediately after completing the trail participants could volunteer to describe their smartphone-led experience through a self-administered cross-sectional questionnaire offered in hard copy at the study site. A non-experimental quantitative research methodology was employed to evaluate the survey data and determine the educational and enjoyment value of the experience. This research is of potential benefit to educators of science, technology and the environment. The research may also assist parks and recreation facilities wishing to offset the costs of building and maintaining traditional interpretive trails by eliminating the need for the printing of booklets, maps and signage.

Author Keywords: education, environment, interpretive trails, science, smartphone technology

The research and development of synthetic blood substitutes is a reported need within the forensic community. This work contributes to the growing body of knowledge in bloodstain pattern analysis by offering a materials science approach to designing, producing and testing synthetic forensic blood substitutes. A key deliverable from this research is the creation of a robust silicon-based material using the solution-gelation technique that has been validated for controlled passive drip and spatter simulation. The work investigates the physical properties (viscosity, surface tension and density) of forensic blood substitute formulations and describes the similarity in the spreading dynamics of the optimized material to whole human blood. It then explores how blood and other fluids behave in impact simulation using high-speed video analysis and supports the use of the optimized material for spatter simulation. Finally, the work highlights the practical value of the material as an educational tool for both basic and advanced bloodstain experimentation and training.

Author Keywords: bloodstain pattern analysis, forensic blood substitutes, high-speed video analysis, silicon solution-gelation chemistry, thin-film deposition, training and education