LAPAN-A2/Orari and LAPAN-A3/IPB satellites are LAPAN-made satellites which are successors of the previous LAPAN-made satellites, namely the LAPAN-TUBSAT satellite made in Germany, the LAPAN-A2/Orari and LAPANA3/IPB satellites launched with Indian PSLV rockets from the Satish Dhawan Space Center, Sriharikota, India in 2015 (LAPAN-A2/Orari) and 2016 (LAPAN-A3/IPB). As time goes by, the two satellites produced large amounts of digital camera image data, for now before software search data images of satellites designed, images results only stored in conventional folder this method makes difficult for operators to search images with certain specifications. LAPAN hoped that the imagery of the two satellites could be integrated in the storage and web-based search media, so the internal user and external user could easily access the image data. This paper describes the design of database storage media, web-based data search which have three function that is search data by location’s name, date range of data retrieval, and also search data images by types of product (camera image data from LAPAN-A2 or camera image data from LAPAN-A3). With this software it is expected that LAPAN services for digital camera images data to every user will be more effective and efficient.
The LAPAN Satellites are remote sensing satellite that will send satellite attitude data in real time mode and offline mode. The satellite attitude data is very important in a remote sensing satellite mission. For example, in the digital imager mission, operator use data attitude to take the image of targeted area with high accuracy. To make it easier for operators to control satellite attitude, they need a satellite simulator or satellite mock up that can show satellite attitudes in realtime or offline mode, especially in special missions. In addition, the dissemination division can also use the simulator to educate people about satellites. This paper discusses the working principle of the simulator and the structural design of the simulator. After the analysis, it is obtained that simulator uses the gimbal mechanism. The materials for the structure is 7075-T6 aluminum alloy. Meanwhile, the drive are three 17HS4401 stepper motor in each axis. The 17hs4401 stepper motor is strong enough to rotate all axes and the 7075-T6 aluminum alloy is strong enough and rigid to be used as a simulator structure.