Litcius/Paper detail

A Deep Learning Approach To Dead-Reckoning Navigation For Autonomous Underwater Vehicles With Limited Sensor Payloads

Ivar Bjørgo Saksvik, Alex Alcocer, Vahid Hassani

2021OCEANS 2021: San Diego – Porto34 citationsDOIOpen Access PDF

Abstract

This paper presents a deep learning approach to aid dead-reckoning (DR) navigation using a limited sensor suite. A Recurrent Neural Network (RNN) was developed to predict the relative horizontal velocities of an Autonomous Underwater Vehicle (AUV) using data from an IMU, pressure sensor, and control inputs. The RNN network is trained using experimental data, where a doppler velocity logger (DVL) provided ground truth velocities. The predictions of the relative velocities were implemented in a dead-reckoning algorithm to approximate north and east positions. The studies in this paper were twofold I) Experimental data from a Long-Range AUV was investigated. Datasets from a series of surveys in Monterey Bay, California (U.S) were used to train and test the RNN network. II) The second study explore datasets generated by a simulated autonomous underwater glider. Environmental variables e.g ocean currents were implemented in the simulation to reflect real ocean conditions. The proposed neural network approach to DR navigation was compared to the on-board navigation system and ground truth simulated positions.

Topics & Concepts

Dead reckoningGround truthComputer scienceInertial navigation systemInertial measurement unitArtificial intelligenceUnderwaterDeep learningUnderwater gliderArtificial neural networkWind triangleAccelerometerGliderRecurrent neural networkReal-time computingComputer visionSimulationGlobal Positioning SystemMobile robotInertial frame of referenceGeologyRobotTelecommunicationsOceanographyProgramming languageOperating systemQuantum mechanicsRobot controlPhysicsUnderwater Vehicles and Communication SystemsUnderwater Acoustics ResearchTarget Tracking and Data Fusion in Sensor Networks