A forest plantation area of Melaleuca cajuputi at BDH Karangmojo, BKPH Yogyakarta are 2,325.20 ha. One of the efforts to keep its sustainability is to plan the target and realization of cajuputi leaf production considerwith forest condition. Advances in remote sensing technology can be an alternative in estimating the cajuputi leaf production on large areas with an efficient time and high accuracy and able to analyze the quality of cajuputi. This study aims to examine Sentinel-2A capabilities through a relationship model of some vegetation indices integrated with vegetative factors on the production to obtain estimates of leaf production, map and test the estimation model accuracy. The method used is to classify objects in pixels with Linear Spectral Mixture Analysis and build relationship between age, number of plants and vegetation index with cajuputi leaf production. The results showed that the unmixing method has 99,66% accuracy in classifying pixels into the fraction of cajuputi. MERIS Terrestrial Chlorophyll Index of unmixing cajuputi fraction simultaneously with age and number of plants has the highest correlation with value of r = 0,668 to the production and modeled in mapping the estimated cajuputi leaf production at the research location with Standard Error of Estimate is 0,183.

Vegetation Index; Linear Spectral Mixture Analysis; Production Estimation; Melaleuca Cajuputi

Asis, A. M. De and K. Omasa. (2007). Estimation of vegetation parameter for modeling soil erodion using Linear Spectral Mixture Analysis of Landsat ETM data.Photogrammetry and Remote Sensing. 62, pp. 309–324.

Badan Standarisasi Nasional. (2011). SNI 7724:2011; Pengukuran dan penghitungan cadangan karbon - Pengukuran lapangan untuk penaksiran cadangan karbon hutan. Badan Standarisasi Nasional. Jakarta.

Brown, D. G. (2001). A Spectral Unmixing Approach to Leaf Area Index (LAI) Estimation at The Alpine Treeline Ecotone. Dalam A. C. Millington, S. J. Walsh, and A. E. Osborne, editor.GIS and Remote Sensing Applications in Biogeography and Ecology. Springer US.

Chavez, P. S. (1996). Image-based atmospheric corrections-revisited and improved. Photogrammetric Engineering & Remote Sensing. 62 (9), pp. 1025–1036.

Clevers, J. G. P. W. and A. A. Gitelson. (2013). Remote estimation of crop and grass chlorophyll and nitrogen content using Red-Edge bands on Sentinel-2 and 3. International Journal of Applied Earth Observation and Geoinformation. 23, pp. 344–351.

Dash, J. and P. J. Curran. (2004). The MERIS Terrestrial Chlorophyll Index. International Journal of Remote Sensing. 25, pp. 5403–5413.

Daughtry, C. S., C. L. Walthall, M. S. Kim, E. Brown De Colstoun, and J. E. McMurtrey. (2000). Estimating corn leaf chlorophyll concentration from leaf and canopy reflectance. Remote Sensing of Environment. 74, pp. 229–239.

Delegido, J., J. Verrelst, L. Alonso, and J. Moreno. (2011). Evaluation of Sentinel-2 Red Edge bands for empirical estimation of green LAI and chlorophyll content. Sensor. 11, pp.7063- 7081.

Dong, T., J. Meng, J. Shang, J. Liu, ang B. Wu. (2015). Evaluation of chlorophyll-related vegetation indices using simulated Sentinel-2 data for estimation of crop fraction of absorbed photosynthetically active radiation. IEEE Journal. pp. 1939–1404.

Europen Space Agency. (2015). Sentinel-2 User Handbook. Hlm. 42–50. Paris.

Fauziana, F. (2016). Pemodelan Spasial Citra SPOT 7 untuk Estimasi Produksi Pucuk Teh (Camellia sinensis (L). O. Kuntze) di Perkebunan Teh PT Pagilaran Kabupaten Batang, Jawa Tengah. Tesis(Tidak dipublikasikan). Program Studi Penginderaan Jauh, Fakultas Geografi, Universitas Gadjah Mada, Yogyakarta.

Fernandez-Manso, A, O. Fernandez-Manso, and C. Quintano. (2016). Sentinel-2A Red Edge spectral indices suitability for discriminating burn severity. International Journal of Applied Earth Observation and Geoinformation. 50, pp. 170–175.

Frampton, W. J., J. Dash, G. Watmough, and E. J. Milton. (2013). Evaluating the capabilities of Sentinel-2 for quantitative estimation of biophysical variables in vegetation. ISPRS Journal of Photogrammetry and Remote Sensing. 82, pp. 83-92.

Gitelson, A. A. and M. N. Merzlyak. (1994). Spectral Reflectance Changes Associated with Autumn Senescence of Aesculus hippocastanum L. and Acer platanoides L. Leaves. Spectral Features and Relation to Chlorophyll Estimation. Journal Plant Physiol. 143, pp. 286–292. Gitelson, A. A., Y. Gritz, and M. N. Merzlyak. (2003). Relationships between Leaf Chlorophyll Content and Spectral Reflectance and Algorithms for Non-Destructive Chlorophyll Assessment in Higher Plant Leaves. Journal Plant Physiol. 160, pp. 271–282.

Haboudane, D., J. R. Miller, N. Tremblay, P. J. Zarco-Tejadad, and L. Dextrazec. (2002). Integrated narrow-band vegetation indices for prediction of crop chlorophyll content for application to precision agriculture. Remote Sensing of Environment. 81, pp. 416–426.

Hardisky M. A., R. M. Smart, and V. Klemas. (1983). Growth Response and Spectral Characteristics of a Short Spartina altemiflora Salt Marsh Irrigated with Freshwater and Sewage Effluent. Remote Sensing of Environment. 13, pp. 57–67.

Howard, J.A. (1996). Penginderaan Jauh untuk Sumberdaya Hutan Teori dan Aplikasi. Hlm. 12. Hartono, Dulbahri, Suharyadi, P. Danoedoro, R. H. Jatmiko, penerjemah. Sutanto, penyunting. Gadjah Mada University Press, Yogyakarta.

Immitzer, M., F. Vuolo, and C. Atzberger. (2016). First experience with Sentinel-2 data for crop and tree species classifications in central Europe. Remote Sensing. 8, pp. 166.

Kartikawati, N. K., A. Rimbawanto, M. Susanto, L. Baskorowati, dan Prastyono. (2014). Budidaya dan Prospek Pengembangan Kayu Putih (Melaleuca cajuputi). Hlm. 23. IPB Press, Bogor.

Klein, A. G. and B. L. Isacks. (1999). Spectral mixture analysis of Landsat Thematic Mapper images applied to the detection of the transient snowline on tropical Andean glaciers. Global and Planetary Change. 22: 139–154.

Murti, S. H. (2014). Permodelan Spasial Untuk Estimasi Produksi Padi Dan Tembakau Berdasarkan Citra Multiresolusi (Kasus untuk Produksi Padi di Kabupaten Wonosobo dan Sragen, serta Produksi Tembakau di Kabupaten Temanggung, Provinsi Jawa Tengah). Disertasi (Tidak dipublikasikan). Minat Studi Penginderaan Jauh, Program Studi Ilmu Geografi, Fakultas Geografi, Universitas Gadjah Mada, Yogyakarta.

Purwadhi, F. S. H. dan T. B. Santoso. (2009). Pengantar Interpretasi Citra Penginderaan Jauh.Edisi kedua, Lembaga Penerbangan dan Antariksa Nasional dan Universitas Negeri Semarang.

Qi, J., A. R. Huete, M. S. Moran, A. Chaehbouni, and R. D. Jackson. (1993). Intepretation of vegetation indices derived from multi-temporal SPOT images. Remote Sensing of Environment. 44, pp. 89–101.

Richter, K., T. B. Hank, F. Vuolo, W. Mauser, and G. D’Urso. (2012). Optimal exploitation of the Sentinel-2 spectral capabilities for crop leaf area index mapping. Remote Sensing. 4, pp. 561–582.

Rock B, N., J. E. Vogelmann, D. L. Williams, A. F. Vogelmann, and T. Hoshizaki. (1986). Remote Detection of Forest Damage. Plant Responses to Stress May have Spectral “Signatures” that Could be Used to Map, Monitor, and Measure Forest Damage. Bio Science. 36, pp. 439–445.

Rondeaux, G., M. Steven, and F. Baret. (1996). Optimization of Soil-Adjusted Vegetation Indices. Remote Sensing Environment. 55, pp. 95–107.

Soerianegara, I. dan A. Indrawan. (1988). Ekologi Hutan Indonesia. Laboratorium Ekologi Hutan, Fakultas Kehutanan, Institut Pertanian Bogor, Bogor. Somers, B., Asner, P. Gregory, L. Tits, and P. Coppin. (2011). Endmember variability in Spectral Mixture Analysis: Areview. Remote Sensing of Environment. 115 (7), pp. 1603– 1616.

Sugiyono. (2014). Statistik untuk Penelitian. Alfabeta, Bandung.

Teillet, P. M., B. Guindon and D. G. Goodenough. (1982). On the slope-aspect correction of multispectral scanner data. Canadian Journal of Remote Sensing. 8 (2), pp. 84–106.

Vanclay, J. K. (1995). Growth model for tropical forest: A synthesis of models and methods. Forest Science. 41 (1), pp. 7–42.

Wiratmoko, D. (2014). Penggunaan Citra Worldview-2 Untuk Estimasi Produksi Kelapa Sawit (Elaeis guineensis Jacq.) Sebagai Implementasi Pertanian Presisi (Studi di Unit Kebun Adolina, PT. Perkebunan Nusantara IV Kabupaten Serdang Bedagai, Provinsi Sumatera Utara). Tesis (Tidak dipublikasikan). Program Studi Penginderaan Jauh, Fakultas Geografi, Universitas Gadjah Mada, Yogyakarta.

Wójtowicz, M., A. Wójtowicz, and J. Piekarczyk. (2016). Application of remote sensing methods in agriculture. Communications in Biometry and Crop Science. 11 (1), pp. 31–50.