This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Bieniasz, J., Wojnar, W., Sadowski, A. & Wrzosek, J. (2011). Convergence of large depth mining excavations in salt rock formations. Geologia, 37/2, 207–214.BieniaszJ.WojnarW.SadowskiA.WrzosekJ.2011Convergence of large depth mining excavations in salt rock formationsGeologia37/2207214Search in Google Scholar
Chen, S., Walske, M. & Davies, I. (2018). Rapid mapping and analysing rock mass discontinuities with 3D terrestrial laser scanning in the underground excavation. International Journal of Rock Mechanics and Mining Sciences, 110, 28–35.ChenS.WalskeM.DaviesI.2018Rapid mapping and analysing rock mass discontinuities with 3D terrestrial laser scanning in the underground excavationInternational Journal of Rock Mechanics and Mining Sciences1102835Search in Google Scholar
Chena, S., Walskeb, M.L. & Daviesc, I.J. (2018), Rapid mapping and analysing rock mass discontinuities with 3D terrestrial laser scanning in the underground excavation. International Journal of Rock Mechanics and Mining Sciences, 110, 28–35.ChenaS.WalskebM.L.DaviescI.J.2018Rapid mapping and analysing rock mass discontinuities with 3D terrestrial laser scanning in the underground excavationInternational Journal of Rock Mechanics and Mining Sciences1102835Search in Google Scholar
Diaz, V., van Oosterom, P., Meiijers, M., Verbree, E., Ahmed, N. & van Lankveld, T. (2024). Comparison of Cloud-to-Cloud Distance Calculation Methods - Is the Most Complex Always the Most Suitable? Recent Advances in 3D Geoinformation Science, 329–334DiazV.van OosteromP.MeiijersM.VerbreeE.AhmedN.van LankveldT.2024Comparison of Cloud-to-Cloud Distance Calculation Methods - Is the Most Complex Always the Most Suitable?Recent Advances in 3D Geoinformation Science329334Search in Google Scholar
Fan, L., Smethurst, J., Atkinson, P. & Powrie, W. (2015). Error in target-based georeferencing and registration in terrestrial laser scanning. Computers & Geosciences, 83, 54–64.FanL.SmethurstJ.AtkinsonP.PowrieW.2015Error in target-based georeferencing and registration in terrestrial laser scanningComputers & Geosciences835464Search in Google Scholar
Ge, Y., Tang, H., Xia, D., Wang, L., Zhao, B., Teaway, J.W., Chen, H. & Zhou, T. (2018). Automated measurements of discontinuity geometric properties from a 3D-point cloud based on a modified region growing algorithm. Engineering Geology, 242, 44–54.GeY.TangH.XiaD.WangL.ZhaoB.TeawayJ.W.ChenH.ZhouT.2018Automated measurements of discontinuity geometric properties from a 3D-point cloud based on a modified region growing algorithmEngineering Geology2424454Search in Google Scholar
Humair, F., Abellan, A., Carrea, D., Matasci, B., Epard, J-L. & Jaboyedoff, M. (2015). Geological layers detection and characterisation using high resolution 3D point clouds: example of a box-fold in the Swiss Jura Mountains. European Journal of Remote Sensing, 48, 541–568.HumairF.AbellanA.CarreaD.MatasciB.EpardJ-L.JaboyedoffM.2015Geological layers detection and characterisation using high resolution 3D point clouds: example of a box-fold in the Swiss Jura MountainsEuropean Journal of Remote Sensing48541568Search in Google Scholar
Janus, J. & Krawczyk, J. (2021). Measurement and Simulation of Flow in a Section of a Mine Gallery. Energies. 14(16):4894.JanusJ.KrawczykJ.2021Measurement and Simulation of Flow in a Section of a Mine GalleryEnergies14164894Search in Google Scholar
Jones, E. (2020). Mobile LiDAR for underground geomechanics: learnings from the teens and directions for the twenties. Second International Conference on Underground Mining Technology (pages 3–26). Crawley, Australia: Australian Centre for Geomechanics.JonesE.2020Mobile LiDAR for underground geomechanics: learnings from the teens and directions for the twentiesSecond International Conference on Underground Mining Technology326Crawley, AustraliaAustralian Centre for GeomechanicsSearch in Google Scholar
Kajzar, V., Kukutsch, R. & Heroldova, N. (2015). Verifying the possibilities of using a 3D laser scanner in the mining underground. Acta Geodynamica et Geomaterialia, 12, 1 (177), 51–58.KajzarV.KukutschR.HeroldovaN.2015Verifying the possibilities of using a 3D laser scanner in the mining undergroundActa Geodynamica et Geomaterialia, 1211775158Search in Google Scholar
Kukutsch, R., Kajzar, V., Konicek, P., Waclawik P. & Ptacek J. (2015). Possibility of convergence measurement of gates in coal mining using terrestrial 3D laser scanner. Journal of Sustainable Mining, 14, 30–37.KukutschR.KajzarV.KonicekP.WaclawikP.PtacekJ.2015Possibility of convergence measurement of gates in coal mining using terrestrial 3D laser scannerJournal of Sustainable Mining143037Search in Google Scholar
Krawczyk, A. (2023). Mining Geomatics. ISPRS International Journal of Geo-Information, page 278.KrawczykA.2023Mining GeomaticsISPRS International Journal of Geo-Information278Search in Google Scholar
Lai, P. & Samson, C. (2016), Applications of mesh parameterization and deformation for unwrapping 3D images of rock tunnels. Tunnelling and Underground Space Technology, 58, 109–119.LaiP.SamsonC.2016Applications of mesh parameterization and deformation for unwrapping 3D images of rock tunnelsTunnelling and Underground Space Technology58109119Search in Google Scholar
Leica TS16 Total Station User manual. (2024). Access: http://surveyteq.com/uploads/p_4728DC68-531B-1855-1437-C5BD241629A2-1608810446.pdfLeica TS16 Total Station User manual2024Access: http://surveyteq.com/uploads/p_4728DC68-531B-1855-1437-C5BD241629A2-1608810446.pdfSearch in Google Scholar
Lipecki, T. & Jaśkowski, W. (2009). Application of laser scanners to determine the shape of mine excavations for safety assessment, using the example of the cross-cut Mina in the Salt Mine Wieliczka. Reports on Geodesy, 2/87, 239–250.LipeckiT.JaśkowskiW.2009Application of laser scanners to determine the shape of mine excavations for safety assessment, using the example of the cross-cut Mina in the Salt Mine WieliczkaReports on Geodesy2/87239250Search in Google Scholar
Lipecki, T., Jaśkowski, W., Gruszyński, W., Matwij, K., Matwij, W. & Ulmaniec, P. (2015). Inventory of the geometric condition of inanimate nature reserve Crystal Caves in “Wieliczka” Salt Mine. Acta Geoldaetica et Geophysica, Volume 51, pages 257–272.LipeckiT.JaśkowskiW.GruszyńskiW.MatwijK.MatwijW.UlmaniecP.2015Inventory of the geometric condition of inanimate nature reserve Crystal Caves in “Wieliczka” Salt MineActa Geoldaetica et Geophysica51257272Search in Google Scholar
Liu, X., Zhang, X., Wang, L., Qu, F., Shao, A., Zhao, L., Wang, H., Yue, X., Li, Y., Yan, W. & He, J. (2024). Research progress and prospects of intelligent technology in underground mining of hard rock mines. Green and Smart Mining Engineering, In Press.LiuX.ZhangX.WangL.QuF.ShaoA.ZhaoL.WangH.YueX.LiY.YanW.HeJ.2024Research progress and prospects of intelligent technology in underground mining of hard rock minesGreen and Smart Mining EngineeringIn Press.Search in Google Scholar
Mah, J., Samson, C., McKinnon, S.D. & Thibodeau, D. (2013). 3D laser imaging for surface roughness analysis. International Journal of Rock Mechanics and Mining Sciences, 58, 111–117.MahJ.SamsonC.McKinnonS.D.ThibodeauD.20133D laser imaging for surface roughness analysisInternational Journal of Rock Mechanics and Mining Sciences58111117Search in Google Scholar
Moon, D., Chung, S., Kwon, S., Seo, J. & Shin, J. (2019). Comparison and utilization of point cloud generated from photogrammetry and laser scanning: 3D world model for smart heavy equipment planning. Automation in Construction, 98, 322–331.MoonD.ChungS.KwonS.SeoJ.ShinJ.2019Comparison and utilization of point cloud generated from photogrammetry and laser scanning: 3D world model for smart heavy equipment planningAutomation in Construction98322331Search in Google Scholar
Mukupa, W., Roberts, G.W., Hancock, C.M. & Al-Manasir, K. (2017). A review of the use of terrestrial laser scanning application for change detection and deformation monitoring of structures. Survey Review, 49:353, 99–116.MukupaW.RobertsG.W.HancockC.M.Al-ManasirK.2017A review of the use of terrestrial laser scanning application for change detection and deformation monitoring of structuresSurvey Review4935399116Search in Google Scholar
Nghia, N. V., Long, N. Q., Cuc, N. T. & Bui, X.-N. (2019). Applied Terrestrial Laser Scanning for coal mine high definition mapping. World of Mining - Surface and Underground, 71(4), 237–242.NghiaN. V.LongN. Q.CucN. T.BuiX.-N.2019Applied Terrestrial Laser Scanning for coal mine high definition mappingWorld of Mining - Surface and Underground714237242Search in Google Scholar
Piestrzyński, A., Banaszak, A. & Zalewska-Kuczmierczyk, M. (2007). Sól kamienna na obszarze przedsudeckim. Chapter in: Monografia KGHM. Lubin: KGHM CUPRUM Sp. z o.o. CBR.PiestrzyńskiA.BanaszakA.Zalewska-KuczmierczykM.2007Sól kamienna na obszarze przedsudeckimChapter in:Monografia KGHMLubinKGHM CUPRUM Sp. z o.o. CBRSearch in Google Scholar
Singh, S. K., Banerjee, B. P. & Raval, S. (2021). Three-Dimensional Unique-Identifier-Based Automated Georeferencing and Coregistration of Point Clouds in Underground Mines. Remote Sensing, 13(16):3145.SinghS. K.BanerjeeB. P.RavalS.2021Three-Dimensional Unique-Identifier-Based Automated Georeferencing and Coregistration of Point Clouds in Underground MinesRemote Sensing13163145Search in Google Scholar
Singh, S.K., Banerjee, B.P. & Raval, S. (2023). A review of laser scanning for geological and geotechnical applications in underground mining. International Journal of Mining Science and Technology. 33, 133–154.SinghS.K.BanerjeeB.P.RavalS.2023A review of laser scanning for geological and geotechnical applications in underground miningInternational Journal of Mining Science and Technology33133154Search in Google Scholar
Technical specification sheet for Faro FOCUS S 350. (2024). Access: https://knowledge.faro.com/Hardware/Focus/Focus/Technical_Specification_Sheet_for_the_Focus_Laser_ScannerTechnical specification sheet for Faro FOCUS S 3502024Access: https://knowledge.faro.com/Hardware/Focus/Focus/Technical_Specification_Sheet_for_the_Focus_Laser_ScannerSearch in Google Scholar
Technical specification sheet for LeicaFlexLine TS09plus Total Station. (2024). Access: https://www.sccssurvey.co.uk/leica-flexline-ts09plus-total-station.htmlTechnical specification sheet for LeicaFlexLine TS09plus Total Station2024Access: https://www.sccssurvey.co.uk/leica-flexline-ts09plus-total-station.htmlSearch in Google Scholar
Watson, C. & Marshall, J. (2018). Estimating underground mine ventilation friction factors from low density 3D data acquired by a moving LiDAR. International Journal of Mining Science and Technology, 28, 657–662.WatsonC.MarshallJ.2018Estimating underground mine ventilation friction factors from low density 3D data acquired by a moving LiDARInternational Journal of Mining Science and Technology28657662Search in Google Scholar
Zeb Horizon - User manual. (2020). Access: https://geoslam.com/wp-content/uploads/2021/02/ZEB-Horizon-User-Manual-v1.3.pdfZeb Horizon - User manual2020Access: https://geoslam.com/wp-content/uploads/2021/02/ZEB-Horizon-User-Manual-v1.3.pdfSearch in Google Scholar