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REMOTE SENSING AND GEOGRAPHIC INFORMATION SYSTEM
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Course Outcomes (COs) |
Learning and Teaching Strategies |
Assessment Strategies |
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On completion of this course, the students will be able to: CO1: Students will able to understand and recognise the basic fundamentals of Remote sensing including Electromagnetic spectrum, scattering, absorption and emission of EMR and how EM radiation interactions vary across a limited number of substances, geometries, and temperatures; and geometric properties of photographs and imagery. CO2: Students will learn GIS including its components, georeferencing, datum in GIS, how raster and vector data used in GIS and applications of DEM. CO3: Students will able to understand the use of GPS R.S. platform, and use of GIS in planning, mapping and resource management. CO4: Students will learn and understand the use of GIS software, data input, how to georeferenced maps and mosaic preparation. CO5: This will give basic understanding of linking spatial and non-spatial data , data base creation, and handling of attributes of GIS. |
Class lectures Group discussions Demonstration Interactive lectures Summative and Formative assessments workshops Mini video lessons Digital modules Software learning |
Assignments Presentations Projects Quiz Class tests and semesters Individual and group projects
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· Introduction to Remote Sensing; Fundamental principles, Electromagnetic radiation, EMR spectrum, EMR interaction with atmosphere and earth surface features,
· Photogrammetry; Aerial photographs: Types Characteristics; Scale and Geometry Aerial photographs, Relief displacement and Drone photography.
· Definition and scope of GIS; Components of GIS; development of GIS.
· Implications of spherical and planar coordinate systems and their transformations in GIS; Georeferencing and implications of Earth’s shape and datum in GIS;
· Data model: Raster and Vector models for geographic data representation; GIS data standards—concepts and components;
· Digital Elevation Model (DEM): process, derivatives and applications
· Introduction to GPS; GPS, Remote sensing and GIS integration; Remote Sensing Platform; Application of remote sensing, GPS and GIS in Urban planning, rural planning, water resource, environment, land use and land cover mapping.
· Graphic User Interface of RS Software – GIS Software
· Data Input: Spatial and Non-Spatial; Scanning, Digitizing and; Data Import and Export; Data Registration, Georeferencing; Mosaic preparation
· Topology Building, Data Editing and Cleaning; Geo-Referencing;
· Projection and Datum; Coordinate Transformation; Linking Spatial and Non-Spatial. Data; Data Base Creation; Attribute Handling
· Adrados, C., Girard, I., Gendner, J., &Janeau, G. (2002). Global Positioning System (GPS) location accuracy due to selective availability removal. C. R. Biologies, 325, 165-170.
· Arvanitis, L., Ramachandran, B., Brackett, D., Rasoul, H., & Du, X. (2000). Multiresource inventories incorporating GIS, GPS and database management systems: A conceptual model. Computers and Electronics in Agriculture, 28, 89-100.
· Ellis, E. A., Nair, P. K. R., Linehan, P. E., Beck, H. W. &Blance, C. A. (2000). A GIS-based database management application for agroforestry planning and tree selection. Computers and Electronics in Agriculture, 27, 41-55.
· Lillesand, Remote Sensing and Image Interpretation, 5th Edn. , John Wiley & Sons, 2007.
· Walsh, A. and J. C. Ollenburger, 2000: Essential Statistics for the Social and Behavioral Sciences: A Conceptual Approach. Prentice Hall, pp. 320. ISBN-13: 978-0130193391