Achieving high navigation accuracy using inertial navigation systems in autonomous underwater vehicles

Author

Panish, Robert ; Taylor, Mikell

Author_Institution

Bluefin Robot. Corp., Quincy, MA, USA

fYear

2011

fDate

6-9 June 2011

Firstpage

1

Lastpage

7

Abstract

This paper presents a summary of the current state-of-the-art in INS-based navigation systems in AUVs manufactured by Bluefin Robotics Corporation. A detailed description of the successful integrations of the Kearfott T-24 Ring Laser Gyro and the IXSEA PHINS III Fiber Optic Gyro into recent Bluefin Robotics AUVs is presented. Both systems provide excellent navigation accuracy for high quality data acquisition. This paper provides a comprehensive assessment of the primary advantages and disadvantages of each INS, paying particular attention to navigation accuracy, power draw, physical size, and acoustic radiated noise. Additionally, a brief presentation of a recently integrated Synthetic Aperture Sonar system will be used to highlight how critical a high-performance INS is to hydrographic, mine countermeasures, and other SAS applications.

Keywords

data acquisition; inertial navigation; remotely operated vehicles; synthetic aperture sonar; underwater vehicles; Bluefin Robotics Corporation; IXSEA PHINS III Fiber Optic Gyro; Kearfott T-24 Ring Laser Gyro; acoustic radiated noise; autonomous underwater vehicles; high navigation accuracy; high quality data acquisition; inertial navigation systems; physical size; power draw; synthetic aperture sonar system; Accuracy; Calibration; Global Positioning System; Sensors; Sonar navigation; Vehicles; AUVs; Bluefin Robotics; FOG; IXSEA; Kearfott; RLG; UUVs; autonomous underwater vehicles; fiber optic gyro; inertial navigation system; ring laser gyro; unmanned underwater vehicles;

fLanguage

English

Publisher

ieee

Conference_Titel

OCEANS, 2011 IEEE - Spain

Conference_Location

Santander

Print_ISBN

978-1-4577-0086-6

Type

conf

DOI

10.1109/Oceans-Spain.2011.6003517

Filename

6003517