Simulation on improvement of position estimation accuracy in underwater using MEMS IMU

Junji Shimizu; Kenta Hata; Yoshikazu Koike; Hiroaki Morino; Eriko Enomoto; Masyhuri Husna; Noritaka Hirohashi; Etsuro Shimizu; Kunio Sakata

doi:10.23919/ELINFOCOM.2019.8706500

Simulation on improvement of position estimation accuracy in underwater using MEMS IMU

Junji Shimizu, Kenta Hata, Yoshikazu Koike, Hiroaki Morino, Eriko Enomoto, Masyhuri Husna, Noritaka Hirohashi, Etsuro Shimizu, Kunio Sakata

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

In recent years, development of an underwater observation system that is low cost and easy to operate is greatly required with the expansion of demand for marine resources survey acquiring rare metal and so on. The authors developed a free-fall type observation system of which body is glass sphere. Since the glass sphere has durability for high hydrodynamic pressure, retailed camera is able to be set inside the sphere to motion the sea environment. However, the positioning of the observation system is severe problem, because sinking motion is only provided by gravity or tidal force. To realize a low cost measurement system, we try to use MEMS IMU (Micro Electro Mechanical Systems Inertial Measurement Unit) for position estimation. The position by MEMS IMU has sensor noise and caused in large estimation error. In this paper, to reduce the estimation error, we propose the combination of optical range sensor. By adopting light rather than ultrasonic for range sensor, it is easy to adapt to systems using glass spheres. At first, sensor noise is modeled by allan variance calculated from measured stationary data, position estimation simulation using the modeled sensor data was performed. By adding the ranging data, the standard deviation of the position estimation can be reduced in (x, y)= (28.8%, 4.43%) with comparison of estimation by the sensor data of MEMS IMU and the depth sensor.

Original language	English
Title of host publication	ICEIC 2019 - International Conference on Electronics, Information, and Communication
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9788995004449
DOIs	https://doi.org/10.23919/ELINFOCOM.2019.8706500
Publication status	Published - 2019 May 3
Event	18th International Conference on Electronics, Information, and Communication, ICEIC 2019 - Auckland, New Zealand Duration: 2019 Jan 22 → 2019 Jan 25

Publication series

Name	ICEIC 2019 - International Conference on Electronics, Information, and Communication

Conference

Conference	18th International Conference on Electronics, Information, and Communication, ICEIC 2019
Country/Territory	New Zealand
City	Auckland
Period	19/1/22 → 19/1/25

Keywords

Free-fall type observation system
Glass sphere
IMU (Inertial Measurement Unit)
Inertial navigation system
Kalman filter
MEMS (Micro Electro Mechanical System)
Range sensor

ASJC Scopus subject areas

Control and Systems Engineering
Electrical and Electronic Engineering

Access to Document

10.23919/ELINFOCOM.2019.8706500

Cite this

Shimizu, J., Hata, K., Koike, Y., Morino, H., Enomoto, E., Husna, M., Hirohashi, N., Shimizu, E., & Sakata, K. (2019). Simulation on improvement of position estimation accuracy in underwater using MEMS IMU. In ICEIC 2019 - International Conference on Electronics, Information, and Communication [8706500] (ICEIC 2019 - International Conference on Electronics, Information, and Communication). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.23919/ELINFOCOM.2019.8706500

Simulation on improvement of position estimation accuracy in underwater using MEMS IMU. / Shimizu, Junji; Hata, Kenta; Koike, Yoshikazu et al.
ICEIC 2019 - International Conference on Electronics, Information, and Communication. Institute of Electrical and Electronics Engineers Inc., 2019. 8706500 (ICEIC 2019 - International Conference on Electronics, Information, and Communication).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Shimizu, J, Hata, K, Koike, Y , Morino, H, Enomoto, E, Husna, M, Hirohashi, N, Shimizu, E & Sakata, K 2019, Simulation on improvement of position estimation accuracy in underwater using MEMS IMU. in ICEIC 2019 - International Conference on Electronics, Information, and Communication., 8706500, ICEIC 2019 - International Conference on Electronics, Information, and Communication, Institute of Electrical and Electronics Engineers Inc., 18th International Conference on Electronics, Information, and Communication, ICEIC 2019, Auckland, New Zealand, 19/1/22. https://doi.org/10.23919/ELINFOCOM.2019.8706500

Shimizu J, Hata K, Koike Y , Morino H, Enomoto E, Husna M et al. Simulation on improvement of position estimation accuracy in underwater using MEMS IMU. In ICEIC 2019 - International Conference on Electronics, Information, and Communication. Institute of Electrical and Electronics Engineers Inc. 2019. 8706500. (ICEIC 2019 - International Conference on Electronics, Information, and Communication). doi: 10.23919/ELINFOCOM.2019.8706500

Shimizu, Junji ; Hata, Kenta ; Koike, Yoshikazu et al. / Simulation on improvement of position estimation accuracy in underwater using MEMS IMU. ICEIC 2019 - International Conference on Electronics, Information, and Communication. Institute of Electrical and Electronics Engineers Inc., 2019. (ICEIC 2019 - International Conference on Electronics, Information, and Communication).

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title = "Simulation on improvement of position estimation accuracy in underwater using MEMS IMU",

abstract = "In recent years, development of an underwater observation system that is low cost and easy to operate is greatly required with the expansion of demand for marine resources survey acquiring rare metal and so on. The authors developed a free-fall type observation system of which body is glass sphere. Since the glass sphere has durability for high hydrodynamic pressure, retailed camera is able to be set inside the sphere to motion the sea environment. However, the positioning of the observation system is severe problem, because sinking motion is only provided by gravity or tidal force. To realize a low cost measurement system, we try to use MEMS IMU (Micro Electro Mechanical Systems Inertial Measurement Unit) for position estimation. The position by MEMS IMU has sensor noise and caused in large estimation error. In this paper, to reduce the estimation error, we propose the combination of optical range sensor. By adopting light rather than ultrasonic for range sensor, it is easy to adapt to systems using glass spheres. At first, sensor noise is modeled by allan variance calculated from measured stationary data, position estimation simulation using the modeled sensor data was performed. By adding the ranging data, the standard deviation of the position estimation can be reduced in (x, y)= (28.8%, 4.43%) with comparison of estimation by the sensor data of MEMS IMU and the depth sensor.",

keywords = "Free-fall type observation system, Glass sphere, IMU (Inertial Measurement Unit), Inertial navigation system, Kalman filter, MEMS (Micro Electro Mechanical System), Range sensor",

author = "Junji Shimizu and Kenta Hata and Yoshikazu Koike and Hiroaki Morino and Eriko Enomoto and Masyhuri Husna and Noritaka Hirohashi and Etsuro Shimizu and Kunio Sakata",

note = "Funding Information: ACKNOWLEDGMENT We all appreciate for Mr. Miyagawa, technical officer of Tokyo university of Marine Science and Technology and Mr. Nishizaki, technical officer of Oki Marine Biological Station, Shimane University. They supported our experiment. The glass sphere is provided by Okamoto Glass Co., Ltd and the plastic cover is provided by Vacuum mold Co., Ltd. We also appreciate for them. This work was supported by JSPS KAKENHI Grant Number JP16730101. Publisher Copyright: {\textcopyright} 2019 Institute of Electronics and Information Engineers (IEIE).; 18th International Conference on Electronics, Information, and Communication, ICEIC 2019 ; Conference date: 22-01-2019 Through 25-01-2019",

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doi = "10.23919/ELINFOCOM.2019.8706500",

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AU - Shimizu, Junji

AU - Hata, Kenta

AU - Koike, Yoshikazu

AU - Morino, Hiroaki

AU - Enomoto, Eriko

AU - Husna, Masyhuri

AU - Hirohashi, Noritaka

AU - Shimizu, Etsuro

AU - Sakata, Kunio

N1 - Funding Information: ACKNOWLEDGMENT We all appreciate for Mr. Miyagawa, technical officer of Tokyo university of Marine Science and Technology and Mr. Nishizaki, technical officer of Oki Marine Biological Station, Shimane University. They supported our experiment. The glass sphere is provided by Okamoto Glass Co., Ltd and the plastic cover is provided by Vacuum mold Co., Ltd. We also appreciate for them. This work was supported by JSPS KAKENHI Grant Number JP16730101. Publisher Copyright: © 2019 Institute of Electronics and Information Engineers (IEIE).

PY - 2019/5/3

Y1 - 2019/5/3

N2 - In recent years, development of an underwater observation system that is low cost and easy to operate is greatly required with the expansion of demand for marine resources survey acquiring rare metal and so on. The authors developed a free-fall type observation system of which body is glass sphere. Since the glass sphere has durability for high hydrodynamic pressure, retailed camera is able to be set inside the sphere to motion the sea environment. However, the positioning of the observation system is severe problem, because sinking motion is only provided by gravity or tidal force. To realize a low cost measurement system, we try to use MEMS IMU (Micro Electro Mechanical Systems Inertial Measurement Unit) for position estimation. The position by MEMS IMU has sensor noise and caused in large estimation error. In this paper, to reduce the estimation error, we propose the combination of optical range sensor. By adopting light rather than ultrasonic for range sensor, it is easy to adapt to systems using glass spheres. At first, sensor noise is modeled by allan variance calculated from measured stationary data, position estimation simulation using the modeled sensor data was performed. By adding the ranging data, the standard deviation of the position estimation can be reduced in (x, y)= (28.8%, 4.43%) with comparison of estimation by the sensor data of MEMS IMU and the depth sensor.

AB - In recent years, development of an underwater observation system that is low cost and easy to operate is greatly required with the expansion of demand for marine resources survey acquiring rare metal and so on. The authors developed a free-fall type observation system of which body is glass sphere. Since the glass sphere has durability for high hydrodynamic pressure, retailed camera is able to be set inside the sphere to motion the sea environment. However, the positioning of the observation system is severe problem, because sinking motion is only provided by gravity or tidal force. To realize a low cost measurement system, we try to use MEMS IMU (Micro Electro Mechanical Systems Inertial Measurement Unit) for position estimation. The position by MEMS IMU has sensor noise and caused in large estimation error. In this paper, to reduce the estimation error, we propose the combination of optical range sensor. By adopting light rather than ultrasonic for range sensor, it is easy to adapt to systems using glass spheres. At first, sensor noise is modeled by allan variance calculated from measured stationary data, position estimation simulation using the modeled sensor data was performed. By adding the ranging data, the standard deviation of the position estimation can be reduced in (x, y)= (28.8%, 4.43%) with comparison of estimation by the sensor data of MEMS IMU and the depth sensor.

KW - Free-fall type observation system

KW - Glass sphere

KW - IMU (Inertial Measurement Unit)

KW - Inertial navigation system

KW - Kalman filter

KW - MEMS (Micro Electro Mechanical System)

KW - Range sensor

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T3 - ICEIC 2019 - International Conference on Electronics, Information, and Communication

BT - ICEIC 2019 - International Conference on Electronics, Information, and Communication

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 18th International Conference on Electronics, Information, and Communication, ICEIC 2019

Y2 - 22 January 2019 through 25 January 2019

ER -

Simulation on improvement of position estimation accuracy in underwater using MEMS IMU

Abstract

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Conference

Keywords

ASJC Scopus subject areas

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