UMineAR: Mobile-Tablet-Based Abandoned Mine Hazard Site Investigation Support System Using Augmented Reality

Conventional mine site investigation has difficulties in fostering location awareness and understanding the subsurface environment; moreover, it produces a large amount of hardcopy data. To overcome these limitations, the UMineAR mobile tablet application was developed. It enables users to rapidly identify underground mine objects (drifts, entrances, boreholes, hazards) and intuitively visualize them in 3D using a mobile augmented reality (AR) technique. To design UMineAR, South Korean georeferenced standard-mine geographic information system (GIS) databases were employed. A web database system was designed to access via a tablet groundwater-level data measured every hour by sensors installed in boreholes. UMineAR consists of search, AR, map, and database modules. The search module provides data retrieval and visualization options/functions. The AR module provides 3D interactive visualization of mine GIS data and camera imagery on the tablet screen. The map module shows the locations of corresponding borehole data on a 2D map. The database module provides mine GIS database management functions. A case study showed that the proposed application is suitable for onsite visualization of high-volume mine GIS data based on geolocations; no specialized equipment or skills are required to understand the underground mine environment. UMineAR can be used to support abandoned-mine hazard site investigations.

[1]  Ronald Azuma,et al.  A Survey of Augmented Reality , 1997, Presence: Teleoperators & Virtual Environments.

[2]  Selim Balcisoy,et al.  Multi-view augmented reality for underground exploration , 2013, 2013 IEEE Virtual Reality (VR).

[3]  Weidong Huang,et al.  Remote Tele-assistance System for Maintenance Operators in Mines , 2011 .

[4]  Zhihan Lv,et al.  ARGIS-based outdoor underground pipeline information system , 2016, J. Vis. Commun. Image Represent..

[5]  F. Ababsa,et al.  Outdoor augmented reality system for geological applications , 2012, 2012 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM).

[6]  Trina S. Myers,et al.  Geological Visualisation with Augmented Reality , 2012, 2012 15th International Conference on Network-Based Information Systems.

[7]  Sangho Lee,et al.  BoreholeAR: A mobile tablet application for effective borehole database visualization using an augmented reality technology , 2015, Comput. Geosci..

[8]  Mohamad Syazli Fathi,et al.  Integration of cyber-physical systems technology with augmented reality in the pre-construction stage , 2014, 2014 2nd International Conference on Technology, Informatics, Management, Engineering & Environment.

[9]  Stefanie Zollmann,et al.  Smart Vidente: advances in mobile augmented reality for interactive visualization of underground infrastructure , 2013, Personal and Ubiquitous Computing.

[10]  Vineet R. Kamat,et al.  Georeferenced Registration of Construction Graphics in Mobile Outdoor Augmented Reality , 2007 .

[11]  Weidong Huang,et al.  Human Factors in Augmented Reality Environments , 2012, Springer New York.

[12]  Ram Dantu,et al.  Evaluation of gyroscope-embedded mobile phones , 2011, 2011 IEEE International Conference on Systems, Man, and Cybernetics.

[13]  D. Michalak Applying the Augmented Reality and RFID Technologies in the Maintenance of Mining Machines , 2012 .

[14]  Wayne Shelley,et al.  Mobile spatial mapping and augmented reality applications for environmental geoscience , 2013 .

[15]  R. C. Pedley,et al.  Mapping the geological space beneath your feet The journey from 2D paper to 3D digital spatial data , 2012, International Conference on Information Society (i-Society 2012).

[16]  Yosoon Choi,et al.  GIS-based evaluation of mining-induced subsidence susceptibility considering 3D multiple mine drifts and estimated mined panels , 2016, Environmental Earth Sciences.