Hava Lazer Tarama Sistemi, Uygulama Alanları ve Kullanılan Yazılımlara Genel Bir Bakış

Year 2016, Volume: 16 Issue: 3, 679 - 692, 31.12.2016

Nizar Polat Murat Uysal

Abstract

Hava LiDAR sistemleri bir hava aracının altına monte edilen tarayıcıdan gönderilen lazer ışının gidiş-dönüş süresini kaydederek yer objeleri ve algılayıcı arasındaki mesafeyi hesaplayan aktif bir ölçme sistemidir. Sistem dâhilinde bulunan GPS ve INS sistemlerinden alınan konum ve dönüklük verisi ile beraber taranan objeye ait konum hesaplanır. Bu şekilde yeryüzüne binlerce lazer ışını gönderebilen sistem, fiziksel yeryüzüne ait yüksek yoğunluklu ve referanslandırılmış üç boyutlu (3B) veri doğrudan elde edilmektedir. Klasik ölçmeler ile yaklaşık aynı doğrulukta, hava fotogrametrisinden daha hızlı oluşturmaya imkân vermektedir. Bu çalışmada hava LiDAR sistemlerine genel bir bakış ile beraber günümüzdeki uygulama alanları, kullanılan lisanslı ve lisanssız yazılımlar ve veri sağlayıcılar ile ilgili bilgi verilmektedir.

Keywords

Hava LiDAR, Nokta bulutu, LiDAR uygulamaları, Üçgen Ağ Model

References

• Jiang, J., Ming, Y., Zhang, Z., Zhang, J. (2005). Point-based 3D Surface Representation from LiDAR Point Clouds. The 4th ISPRS Workshop on Dynamic and Multi-dimensional GIS. September 6-8, 2005, Wales, UK, 1-4.
• Liadsky, J. (2007). Recent advancements in commercial LiDAR mapping and imaging systems. Informally published manuscript, Optech Incorporate, Available from NPS
• LiDAR Workshop. Retrieved from http://www.nps.edu/academics/Centers/RemoteSensing/ Presentations/LiDAR/ Presentations/ RecentAdvancements.pdf.
• NOAA (National Oceanic and Atmospheric Administration) Coastal Services Center.(2012). “LiDAR 101: An Introduction to LiDAR Technology, Data, and Applications.” Revised. Charleston, SC: NOAA Coastal Services Center.
• Petzold, B., Reiss, P., and Stossel, W. (1999). Laser scanning-surveying and mapping agencies are using a new technique for the derivation of digital terrain models. ISPRS Journal of Photogrammetry & Remote Sensing, 54, 95–104.
• Eddy, J. (2016), So, what exactly can you do with LiDAR? The Journal of the Chartered Institution of Civil Engineering Surveyors.
• Meng, X., Currit, N., and Zhao, K. (2010). Ground filtering algorithms for airborne LiDAR data: A review of critical issues. Remote Sensing, (2), 833-860.
• Liu, X. (2008). Airborne LiDAR for DTM generation: Some critical issues. Progress in Physical Geography, 32(1), 31-49.
• Maune D. F. (Editör), (2007). Digital Elevation Model Technologies and Applications: The DEM user Manual. ASPRS, 2. Baskı, Maryland, ABD.
• Polat, N. ve Uysal, M. (2015). Investigating performance of Airborne LiDAR data filtering algorithms for DTM generation. Measurement, 63 61–68.
• Kayı, A. EErdoğan, M. Eker, O. 2015. OPTECH HA-500 ve RIEGL LMS-Q1560 ile Gerçekleştirilen LİDAR Test Sonuçları, Harita Dergisi Ocak 2015 Sayı 153.
• Axelsson, P. (2000). DTM generation from laser scanner data using adaptive TIN models. Int. Arch. Photogram. Remote Sens., pt. B3, vol. 33, pp. 85–92
• 1. http://forsys.cfr.washington.edu/fusion/fusion_overview.html, 11.02.2014.
• 2. https://courseware.e-education.psu.edu/courses/bootcamp/lo04/cg.html, 04.03.2014.
• 3. http://www.asprs.org/Committee-General/LASer-LAS-File-Format-Exchange-Activities.html, 12.02.2014.
• 4. http://lidar-america.com/2014/05/01/lidar-in-agriculture/.
• 5. http://ferm.forestry.oregonstate.edu/graduate/forest-biometrics-and-geomatics.
• 6. http://ipler.cis.rit.edu/flood.
• 7. https://peopleandtreesincities.wordpress.com/tag/urban-tree-canopy/.
• 8. http://aeromapss.com/airborne-lidar-bathymetry/.
• 9. http://www2.le.ac.uk/departments/physics/research/eos/james-lawrence.
• 10. http://eijournal.com/resources/lidar-solutions-showcase/merrick-maps-the-southeastern-u-s-coastline.
• 11. http://www.terraremote.com/transportation/highways/.
• 12. http://legeo.ca/industries/mining/.
• 13. http://www.theverge.com/2013/6/20/4445568/lasers-lidar-archaeology-detailed-topographical-maps.