Robot Beroda Multifungsi dengan Lengan 4 Servo Berbasis Kontrol Nirkabel Joystik PS2

Danang Hendrawan; Muhammad ‘Atiq; Yohanes Tri Novia Putra; Rizal Agri Wahyuadi; Raka Dian Mahardi; Sigit Prakosa A N

doi:10.55606/jupti.v4i2.5165

Authors

Danang Hendrawan Sekolah Tinggi Teknik Pati
Muhammad ‘Atiq Sekolah Tinggi Teknik Pati
Yohanes Tri Novia Putra Sekolah Tinggi Teknik Pati
Rizal Agri Wahyuadi Sekolah Tinggi Teknik Pati
Raka Dian Mahardi Sekolah Tinggi Teknik Pati
Sigit Prakosa A N Sekolah Tinggi Teknik Pati

DOI:

https://doi.org/10.55606/jupti.v4i2.5165

Keywords:

Arduino Uno, Motor Driver, Wireless Controller, Wheeled Robot, Servo Motor

Abstract

In the ever-increasing development of technology, the field of robotics has become one of the most promising fields, both in the industrial world, education, and technological research. Robotics not only increases work efficiency, but also encourages innovation in various sectors. This project aims to develop a multi-purpose wheeled robot equipped with a 4 servo mechanical arm, which functions to support the robot's operational capabilities in various simple tasks such as picking up and moving objects. The main objective of this project is to understand and implement a robotic control system using an Arduino Uno microcontroller, an L298N motor driver, and integration with a wireless PS2 control interface. In more detail, this research aims to: (1) build a four-wheeled robot that can be controlled wirelessly using a PS2 controller; (2) implement a 4 servo arm system as an additional actuator to enhance the robot; and (3) integrate hardware components such as an Arduino Uno and an L298N motor driver into a robot control system. The methodology in this research includes the hardware and software design stages, programming using the Arduino IDE, and integration of all components such as DC motors, SG90 servos, wireless PS2 control modules, and power supplies. Testing was conducted to observe the system's response to input from the controller. The implementation results show that the robot can operate stably. The robot is able to respond to commands well and accurately, both in terms of basic movements using wheels and in moving its servo arm. The implementation results show that the robot can operate stably. The robot is able to respond to commands well and accurately, both in terms of basic movements using wheels and in moving its servo arm.

References

Awal, H., Hendrik, B., & Arby, W. (2022). Perancangan dan implementasi robot keseimbangan beroda dua berbasis mikrokontroler. Jurnal Sains dan Teknologi (JSIT), 2(1), 8–17. https://doi.org/10.47233/jsit.v2i1.74

Azhari, Nasution, T. I., & Azis, P. F. A. (2023). MPU-6050 wheeled robot controlled hand gesture using L298N driver based on Arduino. Journal of Physics: Conference Series, 2421(1). https://doi.org/10.1088/1742-6596/2421/1/012022

Carrillo, M. V. (2021). Introducción de Arduino. Publicación Semestral, 9(17), 4–8. https://repository.uaeh.edu.mx/revistas/index.php/prepa4/issue/archive

Devana, M., Dewi, T., Husni, N. L., Risma, P., & Oktarina, Y. (2021). Desain robot pengintai segala medan dengan kendali wireless PS2. Journal of Applied Smart Electrical Network and Systems, 2(2), 64–70. https://doi.org/10.52158/jasens.v2i2.210

Dhani, H., Redationo, N. T., & Dhancis, W. (2024). Assessment of mobile robot load-carrying potential via DC gearbox motor torque. Jurnal Metal, 2(1), 16–21.

García-Tudela, P. A., & Marín-Marín, J. A. (2023). Use of Arduino in primary education: A systematic review. Education Sciences, 13(2). https://doi.org/10.3390/educsci13020134

Herman, Y., Hasibuan, A. Z., & Sembirimg, A. (2024). Prototype robot pengantar barang pengikut marka hitam berbasis mikrokontroler. Explorer, 4(2), 87–96. https://doi.org/10.47065/explorer.v4i2.1435

Hernandez, J., Sunny, M. S. H., Sanjuan, J., Rulik, I., Zarif, M. I. I., Ahamed, S. I., Ahmed, H. U., & Rahman, M. H. (2023). Current designs of robotic arm grippers: A comprehensive systematic review. Robotics, 12(1), 1–33. https://doi.org/10.3390/robotics12010005

Luqman, M., Anggraheny, B., Herwandi, H., & Murtono, A. (2025). Aplikasi dan unjuk kerja motor driver L-298 dan BTS7960 sebagai power switching pada inverter. Jurnal Eltek, 23(1), 9–15. https://doi.org/10.33795/eltek.v23i1.6656

Powera. (2018). Handson Technology. http://www.handsontec.com/pdf_learn/esp8266-V10.pdf

Prastyo, E. A. (2022). Pengertian dan prinsip kerja motor servo. Arduino Indonesia. https://www.arduinoindonesia.id/2022/10/pengertian-dan-prinsip-kerja-motor-servo.html

Pratikto, R. B., Setiawan, E., & Syauqy, D. (2021). Rancang bangun simulasi robot beroda untuk pengiriman barang di dalam gedung berbasis metode particle filter. Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer (J-PTIIK), 5(8), 3229–3236. http://j-ptiik.ub.ac.id/index.php/j-ptiik/article/view/9528

Rahmajid Wijaya, B., Khaycal, M., & Taryudi. (2021). Robot penjaga gawang pada kontes robot sepak bola Indonesia jenis beroda 2019. Autocracy: Jurnal Otomasi, Kendali, dan Aplikasi Industri, 7(2), 60–65. https://doi.org/10.21009/autocracy.072.3

Salim, Irfansyah, A., Saragih, Y., & Hidayat, R. (2020). Implementasi motor servo SG 90 (Electronics integration helmet wiper). Jurnal Electro Luceat, 6(2), 1–9. https://doi.org/10.32531/jelekn.v6i2.256

Saputra, H. T., & Muhaimin, A. (2022). Robot pemindah benda dengan kendali joystick PS2 wireless berbasis Wemos. Jurnal Ilmu Komputer, 11(2), 80–85. http://jik.htp.ac.id

Simplified, U. M. (n.d.). Merit Technologies PS2 wireless joystick instructions (pp. 4–6).

Sujarwata. (2013). Pengendali motor servo berbasis mikrokontroler Basic Stamp 2sx untuk mengembangkan sistem robotika. Fakultas Matematika dan Ilmu Pengetahuan Alam, Universitas Negeri Semarang (UNNES), 47–54.

Robot Beroda Multifungsi dengan Lengan 4 Servo Berbasis Kontrol Nirkabel Joystik PS2

Authors

DOI:

Keywords:

Abstract

References

Downloads

Published

How to Cite

Issue

Section

License

menu