Underwater robot is a type of robot specially designed and configured to operate underwater, especially in seas, rivers, and lakes. The main purpose of underwater robots is to perform various tasks and missions underwater, which are often difficult or dangerous for humans to carry out. The method used to design the underwater robot is with a smartphone control system. The robot can move according to the user's commands by being connected through a internet network, allowing the robot and smartphone to be interconnected. This underwater robot is equipped with a camera and two lamps, and the images captured by the camera are displayed on a personal computer. Meanwhile, the lights are controlled by the user using a smartphone. The research results show that the underwater robot can be controlled to a depth of 0.5 meters with an average button press speed of 1 second in floating conditions and 2.9 seconds at a depth of 15 centimeters. The application of this robot can take photos, display good images, and monitor activities underwater. In addition, the captured image from underwater robot are also good and the image produced are clearly visible both on land and in the water.

M. S. Gitakarma, K. U. Ariawan, and N. A. Wigraha, “Alat Bantu Survey Bawah Air Menggunakan Amoba , Robot Berbasis ROV,” vol. 3, no. 2, p. 393, 2014.

Jamaluddin, A. K. F. Rustam, A. Sahwawi, A. Sultan, D. T. Pratama, and A. P. Alimuddin, “Desain Robot Observasi Karang Autonomous dengan Sistem Artificial Intelligence,” Hasanuddin Student J., vol. 2, no. 1, p. 90, 2017.

I. Sobary, R. Nugraha, and S. Sumaryo, “Desain Implementasi Sistem Navigasi dan Monitoring pada Remotely Operated Vehicle (ROV),” e-Proceeding Eng., vol. 6, no. 3, p. 10045, 2019.

B. S. Saputro, E. Djunarsjah, J. Setiyadi, and A. K. Negara, “Pengoperasian Remotely Operated Vehicle (ROV) Mendukung Pekerjaan Bawah Air (Studi Kasus Pendeteksian Kabel Bawah Laut Menggunakan Rov H800 Di Perairan Selat Bangka Belitung),” p. 96.

P. D. Lestari, L. Karlitasari, and S. Maryana, “Pengendali Pintu Gerbang Berbasis IoT (Internet of Things ) Gate Controller Berbasis IOT ( Internet of Things ),” vol. 1, no. 2, pp. 62–63, 2021.

Y. Efendi, “Internet of Things (IoT) Sistem Pengendalian Lampu Menggunakan Raspberry PI Berbasis Mobile,” vol. 4, no. 1, p. 20, 2018.

M. A. Robbith, “Mengenal Apa Itu Internet of Things dan Controh Penerapannya,” 2020. https://www.google.co.id/amp/s/www.sekawanmedia.co.id/pengertian-internet-of-thins/amp/.

“Mengenal Blynk Platform IoT,Instalasi dan Penerapannya,” CauseAR. https://www.google.co.id/amp/s/www.anakkendali.com/mengenal-blynk-platform-iot-instalasi-dan penerapannya/amp/ (accessed Jun. 12, 2021).

A. Faudin, “Mengenal Aplikasi Blynk untuk Fungsi IOT,” 2017. https://www.nyebarilmu.com/mengenal-aplikasi-blynk-untuk-fungsi-iot/ (accessed Jun. 12, 2021).

Huang, C., Zhao, J., Yu, Y., Zhang, H. "Comprehensive Sample Augmentation by Fully

Considering SSS Imaging Mechanism and Environment for Shipwreck Detection Under

Zero Real Samples, (2022) IEEE Transactions on Geoscience and Remote Sensing, 60. Cited 10 times. https://ieeexplore.ieee.org/servlet/opac?punumber=36, doi: 10.1109/TGRS.2021.3116671

Yuniarti, Elvan, and Dewi Lestari. "Design and Build Underwater Robot Control System Based on PID (Proportional Integral Derivative)." Al-Fiziya: Journal of Materials Science, Geophysics, Instrumentation and Theoretical Physics 4.2 (2021): 115-123.

Heidemann, John, Milica Stojanovic, and Michele Zorzi. "Underwater sensor networks: applications, advances and challenges." Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 370.1958 (2012): 158-175.

Windiastik, Shania Putri, Elsha Novia Ardhana, and Joko Triono. "Perancangan Sistem Pendeteksi Banjir Berbasis IoT (Internet of Thing)." Seminar Nasional Sistem Informasi (SENASIF). Vol. 3. 2019.

Hasanah, Ana, Sitti Ahmiatri Saptari, and Dewi Lestari. "Sistem Deteksi Banjir Dan Pintu Air Otomatis Menggunakan Raspberry Pi 3 Berbasis Website." InfoTekJar: Jurnal Nasional Informatika dan Teknologi Jaringan 4.2 (2020): 250-254.

Wang, J., Wu, Z., Dong, H., Tan, M., Yu, J. Development and Control of Underwater Gliding

Robots: A Review, (2022) IEEE/CAA Journal of Automatica Sinica, 9 (9), pp. 1543

doi: 10.1109/JAS.2022.105671

Che, Xianhui, et al. "Re-evaluation of RF electromagnetic communication in underwater sensor networks." IEEE Communications Magazine 48.12 (2010): 143-151.

Yan, Hai, Zhijie Jerry Shi, and Jun-Hong Cui. "DBR: depth-based routing for underwater sensor networks." NETWORKING 2008 Ad Hoc and Sensor Networks, Wireless Networks, Next Generation Internet: 7th International IFIP-TC6 Networking Conference Singapore, May 5-9, 2008 Proceedings 7. Springer Berlin Heidelberg, 2008.

Heidemann, John, et al. "Research challenges and applications for underwater sensor networking." IEEE Wireless Communications and Networking Conference, 2006. WCNC 2006.. Vol. 1. IEEE, 2006.

Lee, Uichin, et al. "Pressure routing for underwater sensor networks." 2010 Proceedings IEEE INFOCOM. IEEE, 2010.

Lestari, Dewi, and M. R. Daimunte. "Rancang Bangun Home Automation Berbasis Ethernet Shield Arduino." Al-Fiziya: Journal of Materials Science, Geophysics, Instrumentation and Theoretical Physics 3.1 (2020): 21-28.

Xie, Peng, Jun-Hong Cui, and Li Lao. "VBF: Vector-based forwarding protocol for underwater sensor networks." NETWORKING 2006. Networking Technologies, Services, and Protocols; Performance of Computer and Communication Networks; Mobile and Wireless Communications Systems: 5th International IFIP-TC6 Networking Conference, Coimbra, Portugal, May 15-19, 2006. Proceedings 5. Springer Berlin Heidelberg, 2006.

Vasilescu, Iuliu, et al. "Data collection, storage, and retrieval with an underwater sensor network." Proceedings of the 3rd international conference on Embedded networked sensor systems. 2005.

Li, Shaonan, et al. "Survey on high reliability wireless communication for underwater sensor networks." Journal of Network and Computer Applications 148 (2019): 102446.

Hoang, K.A., Vo, T.Q. A study on fuzzy based controllers design for depth control of a 3-

joint Carangiform fish robot (2013),2013 International Conference on Control, Automation and Information Sciences, ICCAIS 2013, art. no. 6720570, pp. 289-294. Cited 7 times.

ISBN: 978-147990572-0 doi: 10.1109/ICCAIS.2013.6720570

Yu, J., Liu, J., Wu, Z., Fang, H. Depth Control of a Bioinspired Robotic Dolphin Based on

Sliding-Mode Fuzzy Control Method (Open Access), (2018) IEEE Transactions on

Industrial Electronics, 65 (3), art. no. 8017458, pp. 2429-2438. Cited 74 times.

http://ieeexplore.ieee.org/xpl/tocresult.jsp?isnumber=5410131

doi: 10.1109/TIE.2017.2745451