ABSTRAK

Saat ini, robot otonom memiliki peranan signifikan di berbagai bidang. Robot otonom meningkatkan efektivitas dan produktivitas sekaligus menurunkan risiko dan tingkat kesalahan secara signifikan. Dua paradigma dapat digunakan saat merancang robot otonom, yaitu paradigma reaktif dan deliberatif. Paper ini merancang sistem kontrol hybrid untuk menggabungkan elemen terbaik dari sistem kontrol deliberatif dan reaktif untuk robot pengiriman otonom. Model tersebut dibuktikan dengan misi untuk memindahkan tiga objek berwarna, dari  posisinya ke tujuan. Dari perancangan dan pengujian, sistem hybrid dapat meminimalisir kelemahan dari masing-masing sistem, sehingga proses pengiriman barang dapat tercapai sesuai dengan rencana dan dapat bereaksi terhadap kondisi yang sebelumnya tidak diketahui dalam perencanaan, seperti hambatan. Penggunaan sistem hybrid membuka kemungkinan untuk merancang sebuah mobile robot otonom yang dapat beroperasi di lingkungan apapun.

Kata kunci: deliberative, reactive, hybrid, autonomous, robot rover

 

ABSTRACT

Recently, autonomous robots have become increasingly significant in numerous fields. Robots with autonomy increase effectiveness and productivity while significantly lowering risk and error rates. Two paradigms can be used when creating an autonomous robot, namely reactive and deliberative paradigm. This paper proposes a hybrid control system to combine the best elements of deliberative and reactive control system for an autonomous delivery robot rover. The model was proved with a mission to move the three colored objects, from their respective positions to the goal cells. From the design and testing the hybrid systems can minimize the weaknesses of each system, so that the stuff-delivery process can be achieved in accordance with the plan and can react to conditions that were not previously known in planning, such as the obstacle. The use of a hybrid system opens up the possibility of designing an autonomous mobile robot that can operate in any environment.

Keywords: deliberative, reactive, hybrid, autonomous, robot rover

Alatise, M., Hancke, G. (2020). A Review on Challenges of Autonomous Mobile Robot and Sensor Fusion Methods. IEEE Access, 8, 39830-39846.

Asokan, T. (2016). Autonomy for Robots: Design and Developmental Challenges (Keynote Address). Procedia Technology, 23, 4-6.

Avram, O., Baraldo, S., Valente, A. (2022). Generalized Behavior Framework for Mobile Robots Teaming with Humans in Harsh Environments. Front Robot AI, 9, 898366.

Cho, J.-H., Kim, Y.-T. (2017). Design of Autonomous Logistics Transportation Robot System with Fork-Type Lifter. International Journal of Fuzzy Logic and Intelligent Systems, 17(3), 177-186.

Fragapane, G.D., Koster, R., Sgarbossa, F., Strandhagen, J.O. (2021). Planning and control of autonomous mobile robots for intralogistics: Literature review and research agenda. European Journal of Operational Research, 294(5), 405-426.

Gascueña, Manuel, J., et al. (2015). Deliberative Control Components for Eldercare Robot Team Cooperation. J. Intell. Fuzzy Syst., 28(1), 17-28.

Hassani, I., Maalej, I., Rekik, C. (2018). Robot Path Planning with Avoiding Obstacles in Known Environment using Free Segments and Turning Points Algorithm. Mathematical Problems in Engineering, 2018(6), 1-13.

Ibáñez, J.R.S., Perez-del-Pulgar, C., Garcia, A. (2021). Path Planning for Autonomous Mobile Robots: A Review. Sensors, 21(23), 7898.

Ingrand, F., Ghallab, M. (2017). Deliberation for Autonomous Robots: A Survey. Artificial Intelligence, 247(4), 10-44.

Lazzeri, N., Mazzei, D., Cominelli, L., Cisternino, A., Rossi, D.D. (2018). Designing The Mind of a Social Robot. Applied Sciences, 8(2), 302.

Murphy, R. (2000). Introduction to AI Robotics. London: MIT Press.

Panigrahi, P., Bisoy, S. (2021). Localization Strategies for Autonomous Mobile Robots: A Review. Journal of King Saud University-Computer and Information Sciences, 34(XXIII).

Savage, J., Muñoz, S., Contreras, L., Matamoros, M., Negrete, M., Rivera, C., Steinbabuer, G., Fuentes, O., Okada, H. (2021). Generating Reactive Robots’ Behaviors using Genetic Algorithms. International Conference on Agents and Artificial Intelligence (pp. 698-707).

Tobaruela, T.A., Rodríguez, A. (2017). Reactive Navigation in Extremely Dense and Highly Intricate Environments. Plos One, 12(12), e0189008.

Wang, X., Zhang, J. (2017). RPL: A Robot Programming Language Based on Reactive Agent. International Conference on Electrical, Automation and Mechanical Engineering, (pp. 250-255).

Wijanto, E. (2022). Design of Behavior-Based Reactive System for Autonomous Stuff-Collecting Mobile Robot. Techne, 21(1), 101-116.