In recent years, small satellite industry has been a rapid trend and become important especially when associated with operational cost, technology adaptation and the missions. One mission of LAPAN-A2, the 2^nd generation of microsatellite that developed by Indonesian National Institute of Aeronautics and Space (LAPAN), is Earth observation using digital camera that provides imagery with 3.5 m spatial resolution. The aim of this research is to compare between object-based and pixel-based classification of land use/land cover (LU/LC) in order to determine the appropriate classification method in LAPAN-A2 dataprocessing (case study Semarang, Central Java).The LU/LC were classified into eleven classes, as follows: sea, river, fish pond, tree, grass, road, building 1, building 2, building 3, building 4 and rice field. The accuracy of classification outputs were assessed using confusion matrix. The object-based and pixel-based classification methods result for overall accuracy are 31.63% and 61.61%, respectively. According to accuracy result, it was thought that blurring effect on LAPAN-A2 data may be the main cause ofaccuracy decrease. Furthermore, the result is suggested to use pixel-based classification to be applied inLAPAN-A2 data processing.

Baatz M, Schape A., (2000), Multiresolution Segmentation - an Optimization Approach for High Quality Multi-Scale Image Segmentation, in Strobl J, Blaschke T, Griesebner G (eds.) Angewandte Geographische Informations-Verarbeitung XII. Wichmann Verlag, Karlsruhe: 2–23.

Becker F, Seguin T, Phulpin et al., (1996), IRSUTE, a small satellite for water budget estimate with high resolution infrared imagery, Acta Astronautica 39: 883–897.

Blaschke T., (2010), Object Based Image Analysis for Remote Sensing, ISPRS J Photogramm Remote Sens., 65 (1): 2–16.

Chmiel J, Fijałkowska A., (2010), Thematic Accuracy Assessment for Object Based Classification in Agriculture Areas: Comparative Analysis of Selected Approaches, GEOBIA (Geographic Object-Based Image Analysis) XXXVIII-4/C7.

Congalton RG, (1991), Remote Sensing of Environment, 37 (1): 35-46.

Dewi NK, Rudiarto I., (2013), Identifikasi Alih Fungsi Lahan Pertanian dan Kondisi Sosial Ekonomi Masyarakat Daerah Pinggiran di Kecamatan Gunungpati Kota Semarang, Jurnal Wilayah dan Lingkungan 1 (2): 175-188.

Gardner SJ, Swinerd GG, Ward AK., (1996), Design of a Small Satellite for Earth Observation, Journal of Aerospace Engineering G4: 323–332.

Gupta SK, Puntambekar P, Chaturvedi S., (2016), Design Concept of the Structural Bus of Microsatellites for Lunar Missions, in IEEE Aerospace Conference, Big Sky, MT: 1-13.

Hardhienata S, Triharjanto RH, Mukhayadi M., (2011), LAPAN-A2: Indonesian Near-Equatorial Surveilance Satellite, 18th Asia-Pacific Regional Space Agency Forum (APRSAF) (not published).

Laguarde JP, Bach M, Boulet G et al., (2010), Combining High Spatial Resolution and Revisit Capabilities in the Thermal Infrared: the MISTIGRI Mission Project: Remote Sensing for Science, Education, and Natural and Cultural Heritage: 165-172.

Lin C, Wu CC, Tsogt K, et al., (2015), Effects of Atmospheric Correction and Pansharpening on LULC Classification Accuracy Using Worldview-2 Imagery, Information Processing in Agriculture 2: 25-36.

Matjafri MZ, Abdullah K, Lim HS, (2017), Malaysian Tiungsat-1 Imagery for Water Quality Mapping, http:// www. gisdevelopment.net/application/nrm/water/quality/watq0005.htm (accessed May 2017).

Nugroho JT, Zylshal, Chulafak GA, et al., (2017), Performance of LAPAN-A2 Satellite Data to Classify Land Cover/Land use in Semarang, Central Java, LISAT IOP Conf. Series: Earth and Environmental Science 54 012098. doi:10.1088/1755-1315/54/1/012098.

Qian W., (2008), Research on "Beijing 1" Micro-Satellite Image Quality and Land use Classification Precision, International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XXXVII B1 941-944.

Qiang Z, Ma A, Chen F et al., (2000), Suggestion of EFS-Small Satellite System for Impending Earthquake Forecast, Chinese Science Bulletin 45 (2): 189–192.

Rujoiu-Mare MR, Mihai BA., (2016), Mapping Land Cover Using Remote Sensing Data and GIS Techniques: a Case Study of Prahova Subcarpathians, Procedia Environmental Sciences 32: 244-255.

Sandau R, Brieb K., (2008), Potential for Advancements In Remote Sensing Using Small Satellites, International archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XXXVII: B1, Beijing.

Santos T, Tenedorio J, Encarnacao S, et al., (2006), Comparison Pixel vs. Object Based Classifiers for Land Cover Mapping with Envista-Meris data, 26th EARsel Symposium, Maio, Varsovia: 1-9.

Sari NM, Kushardono D., (2016), Quality Analysis of Single Tree Object with OBIA and Vegetation Index from LAPAN Surveillance Aircraft Multispectral Data in Urban Area, Geoplanning: Journal of Geomatics and Planning 3(2): 93-106. doi:10.14710/geoplanning.3.2.93-106.

Vincent N, Gaillard D, Banos T., (1998), Small Satellite System for Civilian Radar Imagery Application, Proceeding of IGARSS ‘98–1998 International Geoscience and Remote Sensing Symposium 1–5: 274–276.

Walter I, Briess K, Baerwald W., (2005), A Microsatellite Platform for Hot Spot Detection, Acta Astronautica 56: 221–229.

Yang Z, Yang RL, (2002), Feasibility Study of Using Small Satellite Synthetic Aperture Radar for Global 3D Imaging, Proceedings of the IEEE International Geoscience and Remote Sensing Symposium and 24th Canadian Symposium on Remote Sensing, Toronto, Canada: 3162–3164.

Yong X, Yingjie L, Jie G, et al., (2008), Small Satellite Remote Sensing and Applications – History, Current and Future, International Journal of Remote Sensing 29 (15): 4339–4372.

Zylshal, Sulma S, Yulianto F, et al., (2016), A Support Vector Machine Object Based Image Analysis Approach on Urban Green Space Extraction Using Pleiades-1A Imagery, Model. Earth Syst. Environ, 2(54): 1-12. doi: 10.1007/s40808-016-0108-8.