Genetic Algorithm Approach for Optimization of Biomass Estimation at LiDAR (original) (raw)

Abstract

Estimation of Biomass at ICESat/GLAS footprint level was finished by incorporating information from various sensors viz., spaceborne LiDAR (ICESat/GLAS). The biomass estimation accuracies of Genetic Algorithm were studied by optimizing the waveform parameters. Multiple linear regression equation was generated using the most important variables found by Genetic Algorithm. The results of the study were very encouraging. Optimum results were obtained using the top 18 parameters derived from GLAS waveform. The biomass was predicted at small area by Genetic Algorithm with an R2 63% of and RMSE of 18.94 t/ha using the best six variables, viz. wdistance, wpdistance, R50, Ecanopy, Home., wcentroid over to 18 independent variables. The same methodology can be used for biomass estimation over a large area. The estimation is done at Tripura area. The study finally established that Genetic approach is produced the better result to predicting AGB. The best outcome of the study was the formulation of an approach that could result in higher biomass estimation accuracies.

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References

1. Anaya J, Chuvieco E, Palaciosorueta A (2009) Aboveground biomass assessment in Colombia: a remote sensing approach. For Ecol Manag 257:1237–1246
   Article Google Scholar
2. IPCC (2000) Good practice guidance and uncertainty management in national greenhouse gas inventories
   Google Scholar
3. Viergever KM, Woodhouse IH, Marino A, Brolley M, Stuart N (2008) SAR interferometry for estimating above-ground biomass of Savanna Woodlands in Belize. In: Geoscience and remote sensing symposium, 2008, IGARSS 2008, IEEE International, pp V-290–V-293
   Google Scholar
4. Parmar AK (2012) A neuro-genetic approach for rapid assessment of above ground biomass: an improved tool for monitoring the impact of forest degradation, geo-information science and earth observation of the University of Twente
   Google Scholar
5. Duong HV (2010) Processing and application of ICES at large footprint full waveform laser range data. Doctoral thesis, Delft University of Technology, Netherlands
   Google Scholar
6. Lu D (2006) The potential and challenge of remote sensing-based biomass estimation. Int J Remote Sens 27(7):1297–1328
   Article MathSciNet Google Scholar
7. Eisfelder C, Kuenzer C, Dech S (2011) Derivation of biomass information for semi-arid areas using remote-sensing data. Int J Remote Sens 33:2937–2984
   Article Google Scholar
8. Hall FG, Bergen K, Blair JB et al (2011) “Characterizing 3D vegetation structure from space”: mission requirements. Remote Sens Environ 115(11):2753–2775
   Article Google Scholar
9. Dhanda (2013) Optimising parameters obtained from multiple sensors for biomass estimation at icesat footprint level using different regression algorithms
   Google Scholar
10. Roeva O (2005) Genetic algorithms for a parameter estimation of a fermentation process model: a comparison
    Google Scholar
11. Jensen JR (2007) Prentice Hall series in geographic information science. Pearson Prentice Hall, 592 pp
    Google Scholar
12. Zwally HJ, Schutz B, Abdalati W, Abshirre J, Bentley C, Brenner A, Bufton J, Dezio J, Hancock D, Harding D, Herring T, Minster B, Quinn K, Palm S, Spinhirne J, Thomas R (2002) ICESat’s laser measurements of polar ice, atmosphere, ocean and land. J Geodyn 34(3–4):405–445
    Article Google Scholar
13. GALGO (2006) An R package for multivariate variable selection using genetic algorithms. Victor Trevino and Francesco Falciani School of Biosciences, University of Birmingham, Edgbaston, UK Bioinformatics
    Google Scholar
14. Upadhyay D (2014) An ethno-botanical study of plants found in Timli Forest Range, District Dehradun, Uttarakhand, India. Cloud Publ Int J Adv Herb Sci Technol 1(1):13–19, Article ID Med-157
    Google Scholar

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Acknowledgements

I would like to express my profounder gratitude towards Dr. Subrata Nandy (Scientist/Engr. SD, FED, IIRS) who guided me throughout this paper. He supervised me for this thought and inspired me to complete it.

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1. Jayoti Vidyapeeth Women’s University, Jaipur, Rajasthan, India
   Sonika & Aditi Jain

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Correspondence toSonika .

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1. Department of Computer Science and Engineering, Sri Aurobindo Institute of Technology, Indore, Madhya Pradesh, India
   Durgesh Kumar Mishra
2. School of Science and Technology, Middlesex University, London, United Kingdom
   Xin-She Yang
3. Department of Mechanical Engineering, Indian Institute of Technology Guwahati, Guwahati, Assam, India
   Aynur Unal

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Sonika, Jain, A. (2019). Genetic Algorithm Approach for Optimization of Biomass Estimation at LiDAR. In: Mishra, D., Yang, XS., Unal, A. (eds) Data Science and Big Data Analytics. Lecture Notes on Data Engineering and Communications Technologies, vol 16. Springer, Singapore. https://doi.org/10.1007/978-981-10-7641-1\_2

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• DOI: https://doi.org/10.1007/978-981-10-7641-1\_2
• Published: 02 August 2018
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• Print ISBN: 978-981-10-7640-4
• Online ISBN: 978-981-10-7641-1
• eBook Packages: Intelligent Technologies and RoboticsIntelligent Technologies and Robotics (R0)Springer Nature Proceedings excluding Computer Science

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