Saat ini perkembangan penginderaan jauh sudah meningkat dengan ditandai perkembangan berbagai teknologi pemetaan. Penginderaan jauh diantaranya menggunakan data optik. Data optik memiliki kelebihan sesuai dengan kondisi sebenarnya akan tetapi tidak bebas efek awan. Salah satu aplikasi penginderaan jauh adalah untuk pemanfaatan bidang pertambangan dan geologi. Data optik bisa digunakan untuk pemanfaatan bidang pertambangan dan geologi. Selain itu juga memerlukan pembuatan model 3D berupa Digital Surface Model (DSM), Digital Elevation Model (DEM), Digital Terrain Model (DTM), dan Earth Gravitational Model (EGM) yang bisa dibuat dari jenis data tersebut. Model 3D serta data optik dan SAR terlebih dahulu harus dilakukan koreksi geometrik, koreksi radiometrik, juga dilakukan koreksi model 3D dan koreksi undulasi geoid. Proses yang dilakukan adalah pendeteksian struktur geologi dari algorithma yang dibuat secara matematik.
Kemudian dilakukan segmentasi pada formasi geologi. Setelah diperoleh pola struktur geologi maka dilakukan pendefinisian terhadap standar geologi yang meliputi jenis formasi, penyusun formasi, endapan, sejarah bentukan formasi. Selanjutnya dilakukan pemodelan dan kondisi kawasan pasca penambangan sesuai dengan algorithma yang tersusun pada pola pengaliran dan kelurusan atau struktur. Hasil yang diperoleh dari pengolahan tersebut baru dilakukan analisis terhadap kawasan
keberadaan pasca tambang yang difokuskan pada mineral Timah yang disebut sebagai „Kolong“ adalah akibat dari konsekwensi logis dari penambangan Timah. Penelitian ini hanya difokuskan pada
jenis tambang dangkal dan di sekitar tambang terbuka Lokasi yang dipilih adalah wilayah bekas tambang di Kabupaten Bangka Barat. Sehingga dapat diasumsikan bahwa hasil penelitian yang dilakukan dalam identifikasi lahan tambang timah dan ekstraksi parameter geologi di Pulau Bangka menggunakan data satelit penginderaan jauh Landsat 6 untuk menampilkan sebaran lokasi lahan tambang timah yang disertai tersedianya ekstraksi parameter geologi.

A. Crosta, J. Moore, McM, Enhancement of Landsat Thematic Mapper imagery for residual soil mapping in SW Minais Gerais State, Brazil: a

prospecting case history in Greenstone belt terrain. In: Proceedings of the Seventh ERIM Thematic Conference: Remote Sensing for Exploration Geology, 1173–1187(1989).

Almeida-Filho, R., Miranda, F.P., Yamakawa, T. 1999. Remote detection of a tonal anomaly in an area of hydrocarbon microseepage, Tucano basin, northeastern Brazil. Int. J. Rem. Sens., 20: 2683-2688.

Clark, R.N., Swayze, G.A., and Gallagher,A.J., 1993a, Mapping minerals with imaging spectroscopy: U.S. Geological Survey Bulletin 2039B, p.

–150.

Crosta, A.P., Souza Filho, C.R., Azevedo, F. and Brodie, C., 2003. Targeting key alteration minerals in epithermal deposits in Patagonia, Argentina, Using ASTER imagery and principal component analysis, International Journal of Remote sensing, 24, PP. 4233-4240.

Desert, Egypt, M.Sc.Thesis, Al Azhar Univ.,

p.

Earth remote sensing data analysis center(ERSDAC). 2001. The Crosstalk

Correction Software: User’s Guide.Mitsubishi Space Software Co. Ltd., 17

pp.

Kargi.,2007. Principal components analysisfor borate mapping. International Journal of Remote Sensing Vol. 28, No. 8, 1805–1817.

Lowell, J.D., and Guilbert, J.M., 1970, Lateral and vertical alteration-mineralization zoning in porphyry ore deposits: Economic Geology and the Bulletin of the Society of Economic Geologists, v. 65, no. 4, p. 373–408.

Looney, C.G. & Yu H., 2000. Special Software Development for Neural Network and Fuzzy Clustering Analysis in Geological Information Systems.

Geological Survey of Canada, 34 p.

Lillesand T M, Kiefer R W and Chipman J W 2004 Remote sensing and image interpretation; 5th edn, John Wiley and Sons Inc., New York, ISBN 0- 471-25515-7, 763p.

Loughlin W P 1991 Principal component analysis for alteration mapping;

Photogrammetric Eng. Rem. Sens. 57(g) 1163–1169.

Lillesand, T.M. Kiefer, R.W. and Chipman, J.W. (2004) Remote Sensing and

Image Interpretation. 5th ed., John Wiley and sons Inc. New York,

ISBN 0-471-25515-7, 763P.

M.Lillesand and W.Kiefer. 1994. Remote sensing and image interpretation , second edition,

Massironi, M. L. Bertoldi, P. Calafa, D. Visona, A. Bistacchi, C. Giardino,

and A. Schiavo, August 1, 2008.Interpretation and processing of

ASTER data for geological mapping and granitoids detection in the

Saghro massif (eastern Anti-Atlas, Morocco) Geosphere; 4(4): 736 -

Mars ,John C and Lawrence C. Rowan. May ,.2006. Regional mapping of phyllicand argillic-altered rocks in the Zagros magmatic arc, Iran, using

Advanced Spaceborne ThermalEmission and Reflection Radiometer

(ASTER) data and logical operator algorithms Geosphere; v. 2; no. 3; p.

-186.

Ninomiya, Y., 2003a. A stabilized vegetation index and several mineralogic indices defined for ASTER VNIR and SWIR data. Proc. IEEE 2003 International Geoscience and Remote Sensing Symposium (IGARSS'03) v. 3, Toulouse, France, 21–25 July 2003, pp. 1552–1554.

P.Cracknell and A.Vaughan. 1992. Remote Sensing from research to operation. Salah Zargani. 1996. Improving ageological map of Dur Al Qussah, using thematic mapper imagery, MSc.

PCI (1998) PCI, GeoAnalyst, version 6.3. PCI, Richmond Hill, Ontario, Canada. Roz, M. E. (1994) Geology and uranium mineralization of Gebel Gatter area, North Eastern

Richards, J.A. (1995) Remote Ssensing, Digital Image Processing, an Introduction, Sec.Ed., Springer Velag., P. 340.

Rolim, J. L. 1984. Estudo da Seqüência Clástica e Carbonática da Serra do

Tonã Macururé, Estado da Bahia. Dissertação de Doutorado, Instituto

de Geociências, Univ. Fed. do Rio Grande do Sul, 155 p.

Rytuba, J. J; Arribas, A. Jr; Cunningham, C. G., McKee, E. H., Podwysocky, M. H.,Smith, J. G., Kelly, W. C., and Arribas, A., 1990, Mineralized and unmineralized calderas in Spain; part II evolution of the Rodalquilar caldera complex and associated goldalunite deposits. Mineralium Deposita, 25, 29–35.

Schwertmann, U., and Taylor, R. M., 1977, Iron Oxides, In Minerals in Soil

Environments, edited by J.B. Dixon and S.B. Weed (Madison, WI: Soil Society of America), pp.145–180.

Segal D B 1983 Use of Landsat multispectral scanner data for definition of

Limonitic exposures in heavily vegetated areas, EL Paso, Texas;

Econ. Geol. 78 711–722.

Sir Vegetable, AS, 1385, Geology of Iran, Geological Survey and Mineral

Exploration country Proud race, c, 1980, Mahabad 1:100000 map - Geological Survey and Mineral Exploration country

Sirvastav, S.K., Bhattacharya, A., Kamaraju, M.V.V., Sreenivasa Reddy, G., Shrimal, A.K., Mehta, spatial variability for lithologic discrimination in Landsat TM images. Photogrammetric Engineering and Remote Sensing,

Thompson, C.K, Saunders, D.F., Burson, K.R. 1994. Model advanced for

hydrocarbon microseepage, related alterations. Oil & Gas Journal.

ABI/INFORM Global, 84: 95-99.

Taranik D L, Kruse F A, Goetz A F H and Atkinson W W 1991 Remote sensing of ferric iron minerals as guides for gold exploration; Proceedings EighthThematic Conference on Geologic Remote Sensing, Denver, Colorado, pp. 197–228.

W. P. Loughlin, 1991. Principal component analysis for alterationmapping.

Photogrammetric Engineering and Remote Sensing, 57, 1163–1169(1991).

Yetkin E 2003 Alteration Mapping by Remote Sensing: Application to Hasanda- Melendiz Volcanic Complex,M.Sc. Thesis, Middle East Technical

University, Ankara, Turkey, 97p.

Zhou, J., and Civco, D. L., 1996, Using genetic learning neural networks for

spatial decision making in GIS. Photogrammetric Engineering and

Remote Sensing, 62, 1287–1295.