KunturSat: Design and Development of a Picosatellite for the CanSat France 2024 Competition
Keywords:
Small satellite technology, Deployment mechanism, Biomarkers, Descent trajectoriesAbstract
This paper presents the design, development, and validation of KunturSat, a picosatellite developed for the CanSat France 2024 competition. KunturSat integrates multiple technological innovations, including a flag deployment system, precise descent control via a 9-cell paraglider, and a biodegradable marking mechanism using purple corn extract (Zea mays var. amilácea (L.)). The structural design utilizes lightweight, high-strength materials, such as Ripstop nylon, and employs advanced 3D printing techniques, ensuring both durability and flight efficiency. A comprehensive series of tests was conducted to evaluate its performance, including vibration analysis, communication tests, support deployment trials, free-fall simulations, and drone-based launches. These assessments validated the mechanical, electronic, and telemetry subsystems under real-flight conditions. The results confirmed KunturSat’s effectiveness in executing its primary mission of biodegradable surface marking, alongside its secondary missions of vertical stabilization and flag deployment. Identified improvements include reinforcement of structural components to enhance resilience in adverse conditions. KunturSat contributes to the aerospace sector as an innovative and sustainable platform, serving as a foundation for future picosatellites with autonomous descent control and advanced deployment mechanisms. Additionally, it underscores the importance of STEM education (science, technology, engineering, and mathematics) and accessible aerospace technologies in fostering engineering expertise.
References
Aly H, Sharkawy O, Nabil A, Yassin A, Tarek M, Amin SM, Ibrahim MK () Project-based space engineering education: application to autonomous rover-back CanSat. Paper presented 2013 6th International Conference on Recent Advances in Space Technologies. IEEE AESS, Aeronautics and Space Technologies Institute (ASTIN) Air Force Academy, Istanbul, Turkey. https://doi.org/10.1109/RAST.2013.6581164
Aydemir ME, Celebi M, Ay S, Vivas EV, Bustinza FC, Phan D (2011) Design and implementation of a rover back CanSat. Paper presented 2011 5th International Conference on Recent Advances in Space Technologies. IEEE AESS, Aeronautics and Space Technologies Institute (ASTIN), Air Force Academy; Istanbul, Turkey. https://doi.org/10.1109/RAST.2011.5966952
Bhattarai S, Go JS, Oh HU (2021) Experimental CanSat platform for functional verification of burn wire triggering-based holding and release mechanisms. Aerospace 8(7):192. https://doi.org/10.3390/AEROSPACE8070192
Botero Y, Lopez A, Restrepo S, Rodriguez JS, Valle D, Galvez-Serna J, Elkamel A, Amiraslani F, Yarce Botero A, Restrepo SL, et al. (2023) Design and implementation of a low-cost air quality network for the Aburra Valley surrounding mountains. Pollutants 3(1):150-165. https://doi.org/10.3390/POLLUTANTS3010012
Chun C, Tanveer MH, Chakravarty S (2023) The CanSat compendium: a review of scientific CanSats. Machines 11(7):675. https://doi.org/10.3390/MACHINES11070675
Contente J, Galvão C (2022) STEM education and problem-solving in space science: a case study with CanSat. Educ Sci 12(4):251. https://doi.org/10.3390/EDUCSCI12040251 [C’Space] (2024) Concours CanSat France 2024. Règlement – 18e édition. [accessed Feb 22 2025]. https://www.planetesciences.org/espace/IMG/pdf/reglement_cansat_2025.pdf
Deshpande SM (2004) Study of interference effects on GPS signal acquisition (master’s thesis). Calgary: University of Calgary.
Durler M (2024) SAM-M8Q Easy-to-use u-blox M8 GNSS antenna module data sheet. [accessed Feb 22 2025].www.u-blox.com
Kopacz JR, Herschitz R, Roney J (2020) Small satellites: an overview and assessment. Acta Astronautic 170:93-105. https://doi.org/10.1016/J.ACTAASTRO.2020.01.034
Libii JN (2007) The determination of the aerodynamic drag force on a parachute. World Trans Eng Technol Educ 6(1):1-4.
López Laval I, Sitko S, Plana Galindo C (2019) El parapente como deporte con interés científico: no solo traumatología. J Negat no Posit Results 4(6):644-656. https://doi.org/10.19230/jonnpr.3031
Millan RM, von Steiger R, Ariel M, Bartalev S, Borgeaud M, Campagnola S, Castillo-Rogez JC, Fléron R, Gass V, Gregorio A, et al. (2019) Small satellites for space science: a COSPAR scientific roadmap. Adv Sp Res 64(8):1466-1517. https://doi.org/10.1016/J.ASR.2019.07.035
Moreno LA, Alta RP, Lopez WE (2023) Precession motion of a CanSat rover-back prototype during its fall-to-Earth descent. Paper presented 2023 IEEE Latin American Electron Devices Conference. IEEE; Puebla, Mexico. https://doi.org/10.1109/LAEDC58183.2023.10209111
Moreno LF, Orellana JM, Adriano MA, Tarazona F, Meza KK, Alta RY. KunturSat: Design and development of a picosatellite for the CanSat France 2024 Competition [supplementary material]. Figshare; 2025. https://doi.org/10.6084/m9.figshare.29378831.v1
Nag S, Lemoigne J, De Weck O (2014) Cost and risk analysis of small satellite constellations for Earth observation. Paper presented 2014 IEEE Aerospace Conference. IEEE; Big Sky, USA. https://doi.org/10.1109/AERO.2014.6836396
Saez G (date unknown) Manual básico del parapentista. [accessed Feb 15 2025]. https://www.ultraligero.net/E_Books/manual_del_ parapentista_paragliding_paramotor.pdf
Song Y, Gnyawali D, Qian L (2024) From early curiosity to space wide web: the emergence of the small satellite innovation ecosystem. Res Policy 53(2):104932. https://doi.org/10.1016/J.RESPOL.2023.104932
Swayampakula SSRK, Vedangi KV, Panangipalli VK, Gummadavelli M, Mala N, Banavath MN, Paladugu N, Kallem A (2024) Design and development of a CanSat for air pollution monitoring with RSSI-based position retrieval system. Adv Sp Res 75(9). https://doi.org/10.1016/J.ASR.2024.02.042
Sweeting MN (2018) Modern small satellites: changing the economics of space. Proc IEEE 106(3):343-361. https://doi.org/10.1109/JPROC.2018.2806218
Urquizo Cruz EP, Sánchez Salcán NJ (2019) Extracto del maíz morado como indicador químico. Chakiñan, Revista de Ciencias Sociales y Humanidades 9:45-57. https://doi.org/10.37135/chk.002.09.08
Wirz M, Strohrmann C, Patscheider R, Hilti F, Gahr B, Hess F, Tröster G (2011) Real-time detection and recommendation of thermal spots by sensing collective behaviors in paragliding. Paper presented 2011 1st International Symposium from Digital Footprints to Social and Community Intelligence. ACM; Beijing, China. https://doi.org/10.1145/2030066.2030070
Zhou C, Senadeera W, Wahia H, Kabutey A, Tsholofelo Nthimole C, Kaseke T, Amos Fawole O (2024) Exploring the extraction and application of anthocyanins in food systems. Processes 12(11):2444. https://doi.org/10.3390/PR12112444
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Copyright (c) 2025 Luis Fernando Aiquipa Moreno, Juan Miguel Villanueva Orellana, Marco Antonio Rodriguez Adriano, Felixjesus Ramirez Tarazona, Katherine Karla Roman Meza, Roxana Yesenia Pastrana Alta
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