Design of a Bio-Inspired Miniature Submarine for Low-Cost Water Quality Monitoring

TL;DR

This paper introduces a low-cost, bio-inspired miniature submarine designed for water quality monitoring, featuring jet propulsion, buoyancy control, and integrated sensors, validated through pool and lake experiments.

Contribution

The paper presents a novel, affordable submarine design inspired by squids, combining pump-based propulsion and buoyancy control with commercial components for environmental monitoring.

Findings

Stable attitude control within +/-2 degrees

Depth regulation with +/-0.1 m accuracy

Successful water sampling in field trials

Abstract

Water quality monitoring is essential for protecting aquatic ecosystems and detecting environmental pollution. This paper presents the design and experimental validation of a bio-inspired miniature submarine for low-cost water quality monitoring. Inspired by the jet propulsion mechanism of squids, the proposed system employs pump-driven water jets for propulsion and steering, combined with a pump-based buoyancy control mechanism that enables both depth regulation and water sampling. The vehicle integrates low-cost, commercially available components including an ESP32 microcontroller, IMU, pressure sensor, GPS receiver, and LoRa communication module. The complete system can be constructed at a hardware cost of approximately $122.5, making it suitable for educational and environmental monitoring applications. Experimental validation was conducted through pool tests and field trials in a lake. During a 360 degrees rotation test, roll and pitch deviations remained within +/-2 degrees and +/-1.5 degrees, respectively, demonstrating stable attitude control. Steering experiments showed a heading step response with approximately 2 s rise time and 5 s settling time. Depth control experiments achieved a target depth of 2.5 m with steady-state error within +/-0.1 m. Field experiments further demonstrated reliable navigation and successful water sampling operations. The results confirm that the proposed platform provides a compact, stable, and cost-effective solution for small-scale aquatic environmental monitoring.