Development of the Subwave ROV and Neural-Inertial Positioning System

Farmer, Jason

09 August 2022

This report documents the development of the Subwave, a remotely-operated underwater vehicle (ROV), and an artificial neural network based inertial positioning system. The Subwave uses the open-source ArduSub software framework, commercial-off-the-shelf hardware components, and several custom systems. It is designed as a platform for researching autonomous underwater vehicles (AUVs). The first step for an AUV is navigating waypoints, which requires the AUV to know its global position. Since global navigation satellite systems (GNSSs) are denied underwater, the available underwater positioning systems were surveyed and determined that all the available systems were too large and expensive for the Subwave. It was also discovered that the only consistent underwater positioning method was inertial positioning. So, experimentation began on a small, low-cost system that employs an artificial neural network to predict latitude and longitude using micro-electromechanical system (MEMS) inertial measurement unit (IMU) data as inputs, which would become the Neural-Inertial Positioning System.

ROV

AUV

Underwater Robotics

ArduSub

GNSS-Denied Navigation

Inertial Positioning

Inertial Navigation

Inertial Dead-Reckoning

Neural-Inertial Positioning

Signal Processing

Development of Sensors and Microcontrollers for Underwater Robots

Jebelli, Ali

January 2014

Nowadays, small autonomous underwater robots are strongly preferred for remote exploration of unknown and unstructured environments. Such robots allow the exploration and monitoring of underwater environments where a long term underwater presence is required to cover a large area. Furthermore, reducing the robot size, embedding electrical board inside and reducing cost are some of the challenges designers of autonomous underwater robots are facing. As a key device for reliable operation-decision process of autonomous underwater robots, a relatively fast and cost effective controller based on Fuzzy logic and proportional-integral-derivative method is proposed in this thesis. It efficiently models nonlinear system behaviors largely present in robot operation and for which mathematical models are difficult to obtain. To evaluate its response, the fault finding test approach was applied and the response of each task of the robot depicted under different operating conditions. The robot performance while combining all control programs and including sensors was also investigated while the number of program codes and inputs were increased.

AUV

Autonomous Underwater Vehicles

ADC

Analog to Digital Converter

Cd

Drag coefficient of the object

DOF

Degree of Freedom

KT

Thrust coefficient

Fd

Force of drag

g

Acceleration of gravity

h

Height of the fluid above the object

KQ

Torque coefficient

mb

Buoyant mass

NN

Neural network

P

Proportional controller

PI

Proportional-integral controller

PID

ρ

Density of the fluid

Q

Torque of the propeller

ROV

Remotely Operated Vehicles

RPM

Speed of the motor or propeller

SDO

Serial data output

SMC

Sliding mode control Measured thrust

T°

Temperature

v

AV

Advance speed of the propeller