ABSTRAK

Penelitian dengan topik robot hexapod telah banyak dikembangkan, namun sampai saat ini masih sedikit yang mengulas tentang kontrol keseimbangannya. Permasalahan yang kerap muncul adalah ketika robot berada dalam bidang miring, robot dapat terjatuh jika robot tidak dapat menyeimbangkan badan. Begitu pula dengan robot hexapod EILERO yang telah kami bangun. Untuk mengatasi permasalahan itu, selain pemodelan kinematik dan kinematika terbalik yang tepat, juga diperlukan suatu sistem keseimbangan yang baik. Dalam penelitian ini, kami menggunakan fuzzy logic untuk mengontrol keseimbangan robot EILERO dengan umpan balik data kemiringan dari sebuah sensor IMU. Setelah melalui beberapa pengujian yang komprehensif, didapatkan hasil bahwa robot dapat menyeimbangkan diri pada kondisi kemiringan papan pijakan antara -15° dan 15° pada orientasi kemiringan roll dan pitch. Robot mampu merespon dengan capaian steady state di bawah 3000 ms. Dengan demikian, robot EILERO semakin stabil dalam melintasi bidang yang tidak datar.

Kata kunci: hexapod, EILERO, kinematika terbalik, fuzzy logic

 

ABSTRACT

Research on the topic of the hexapod robot has been developed a lot, but until now there is little that has been discussed about balance control. The problem that often arises is that when the robot is on an inclined plane, the robot can fall if the robot cannot balance its body. Likewise with the EILERO hexapod robot that we have built. To solve this problem, besides proper kinematic modeling and inverse kinematic modeling, a good balance system is also needed. In this study, we used fuzzy logic to control the balance of the EILERO robot, with tilt data feedback from an IMU sensor. After going through several comprehensive tests, the results show that the robot can balance itself on the slope of the stepboards between -15 ° and 15 ° in the orientation of roll and pitch tilt. The robot is able to respond with steady state achievements below 3000 ms. Thus, the EILERO robot is increasingly stable in traversing uneven planes.

Keywords: hexapod, EILERO, inverse kinematic, fuzzy logic

Charel, S. E. R., Binugroho, E. H., Rosyidi, M. A., Dewanto, R. S., & Pramadihanto, D. (2016). Kalman filter for angle estimation using dual inertial measurement units on unicycle robot. 2016 International Electronics Symposium (IES), (pp. 256–261). https://doi.org/10.1109/ELECSYM.2016.7861013

De Silva, S., & Sitte, J. (2012). Force Controlled Hexapod Walking. In Advances in Autonomous Mini Robots, (pp. 265–277). Springer Berlin Heidelberg. https://doi.org/10.1007/978-3-642-27482-4_25

Hidayati, Q., Rachman, F. Z., & Yanti, N. (2017). Intelligent Control System of Fire-Extinguishing and Obstacle-Avoiding Hexapod Robot. Kinetik: Game Technology, Information System, Computer Network, Computing, Electronics, and Control, 1–10. https://doi.org/10.22219/kinetik.v3i1.470

Huang, C.-F., Tung, Y.-C., & Yeh, T.-J. (2017). Balancing control of a robot bicycle with uncertain center of gravity. 2017 IEEE International Conference on Robotics and Automation (ICRA), (pp. 5858–5863). https://doi.org/10.1109/ICRA.2017.7989689

Juang, C.-F., Chen, Y.-H., & Jhan, Y.-H. (2015). Wall-Following Control of a Hexapod Robot Using a Data-Driven Fuzzy Controller Learned Through Differential Evolution. IEEE Transactions on Industrial Electronics, 62(1), 611–619. https://doi.org/10.1109/TIE.2014.2319213

Nasution, Z., Ilham Suparman, A. F., Prasetyo, G. A., Alasiry, A. H., Binugroho, E. H., & Darmawan, A. (2019). Body Balancing Control for EILERO Quadruped Robot while Walking on Slope. 2019 International Electronics Symposium (IES), (pp. 364–369). https://doi.org/10.1109/ELECSYM.2019.8901598

Romadon, Z. T., Oktavianto, H., Wibowo, I. K., Sena Bayu Dewantara, B., Nurrohmah, E. A., & Adryantoro Priambudi, R. (2019). Pose Estimation on Soccer Robot using Data Fusion from Encoders, Inertial Sensor, and Image Data. IES 2019-International Electronics Symposium: The Role of Techno-Intelligence in Creating an Open Energy System Towards Energy Democracy, Proceedings, (pp. 454–459). https://doi.org/10.1109/ELECSYM.2019.8901578

Roy, S. S., Singh, A. K., & Pratihar, D. K. (2020). Analysis of six- legged walking robots. 14th National Conference on Machines and Mechanisms, NaCoMM 2009, (pp. 259–265).

Sartika, E. M., Gany, A., & Yuvens, V. (2020). Implementasi Sensor IMU untuk mengetahui Sudut Elevasi Kendaraan menggunakan Metode Least Square. ELKOMIKA: Jurnal Teknik Energi Elektrik, Teknik Telekomunikasi, & Teknik Elektronika, 8(2), 301. https://doi.org/10.26760/elkomika.v8i2.301

Suebsomran, A. (2012). Balancing control of bicycle robot. 2012 IEEE International Conference on Cyber Technology in Automation, Control, and Intelligent Systems (CYBER), (pp. 69–73). https://doi.org/10.1109/CYBER.2012.6392529

Syamsudin, A., Wibowo, I. K., & Mobed Bachtiar, M. (2018). Improving the Accuracy and Controlling the Shooting Power in a Wheeled Soccer Robot. 2018 International Electronics Symposium on Engineering Technology and Applications, IES-ETA 2018 - Proceedings, (pp. 100–106). https://doi.org/10.1109/ELECSYM.2018.8615513

Tedeschi, F., & Carbone, G. (2014). Design Issues for Hexapod Walking Robots. Robotics, 3(2), 181–206. https://doi.org/10.3390/robotics3020181

Zadeh, L. A. (2012). Fuzzy LogicFuzzy logic. In Computational Complexity, (pp. 1177–1200). Springer New York. https://doi.org/10.1007/978-1-4614-1800-9_73

Zak, M., & Rozman, J. (2015). Design, construction and control of hexapod walking robot. 2015 IEEE 13th International Scientific Conference on Informatics, (pp. 302–307). https://doi.org/10.1109/Informatics.2015.7377851

Zhang, H., Wu, R., Li, C., Zang, X., Zhang, X., Jin, H., & Zhao, J. (2017). A Force-Sensing System on Legs for Biomimetic Hexapod Robots Interacting with Unstructured Terrain. Sensors, 17(7), 1514. https://doi.org/10.3390/s17071514