Full Text:   <2190>

Summary:  <1815>

CLC number: TP391

On-line Access: 2024-08-27

Received: 2023-10-17

Revision Accepted: 2024-05-08

Crosschecked: 2018-08-23

Cited: 0

Clicked: 6416

Citations:  Bibtex RefMan EndNote GB/T7714

 ORCID:

Ching Soon Tan

http://orcid.org/0000-0002-6329-4558

-   Go to

Article info.
Open peer comments

Frontiers of Information Technology & Electronic Engineering  2018 Vol.19 No.8 P.1042-1055

http://doi.org/10.1631/FITEE.1700720


Automatic analysis of deep-water remotely operated vehicle footage for estimation of Norway lobster abundance


Author(s):  Ching Soon Tan, Phooi Yee Lau, Paulo L. Correia, Aida Campos

Affiliation(s):  Centre for Computing and Intelligent Systems, Universiti Tunku Abdul Rahman, Kampar 31900, Malaysia; more

Corresponding email(s):   laupy@utar.edu.my

Key Words:  Object detection, Object tracking, Feature extraction, Remotely operated vehicle (ROV)


Ching Soon Tan, Phooi Yee Lau, Paulo L. Correia, Aida Campos. Automatic analysis of deep-water remotely operated vehicle footage for estimation of Norway lobster abundance[J]. Frontiers of Information Technology & Electronic Engineering, 2018, 19(8): 1042-1055.

@article{title="Automatic analysis of deep-water remotely operated vehicle footage for estimation of Norway lobster abundance",
author="Ching Soon Tan, Phooi Yee Lau, Paulo L. Correia, Aida Campos",
journal="Frontiers of Information Technology & Electronic Engineering",
volume="19",
number="8",
pages="1042-1055",
year="2018",
publisher="Zhejiang University Press & Springer",
doi="10.1631/FITEE.1700720"
}

%0 Journal Article
%T Automatic analysis of deep-water remotely operated vehicle footage for estimation of Norway lobster abundance
%A Ching Soon Tan
%A Phooi Yee Lau
%A Paulo L. Correia
%A Aida Campos
%J Frontiers of Information Technology & Electronic Engineering
%V 19
%N 8
%P 1042-1055
%@ 2095-9184
%D 2018
%I Zhejiang University Press & Springer
%DOI 10.1631/FITEE.1700720

TY - JOUR
T1 - Automatic analysis of deep-water remotely operated vehicle footage for estimation of Norway lobster abundance
A1 - Ching Soon Tan
A1 - Phooi Yee Lau
A1 - Paulo L. Correia
A1 - Aida Campos
J0 - Frontiers of Information Technology & Electronic Engineering
VL - 19
IS - 8
SP - 1042
EP - 1055
%@ 2095-9184
Y1 - 2018
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/FITEE.1700720


Abstract: 
Underwater imaging is being used increasingly by marine biologists as a means to assess the abundance of marine resources and their biodiversity. Previously, we developed the first automatic approach for estimating the abundance of Norway lobsters and counting their burrows in video sequences captured using a monochrome camera mounted on trawling gear. In this paper, an alternative framework is proposed and tested using deep-water video sequences acquired via a remotely operated vehicle. The proposed framework consists of four modules: (1) pre-processing, (2) object detection and classification, (3) object-tracking, and (4) quantification. Encouraging results were obtained from available test videos for the automatic video-based abundance estimation in comparison with manual counts by human experts (ground truth). For the available test set, the proposed system achieved 100% precision and recall for lobster counting, and around 83% precision and recall for burrow detection.

深水遥控潜水器影片自动分析在挪威龙虾丰度估算中的应用

概要:水下成像技术越来越多地被海洋生物学家应用于海洋资源和生物多样性的丰度评估。之前,我们开发了挪威龙虾丰度测算方法,并利用安装在拖网上的黑白摄像机采集的视频序列对龙虾洞进行计数。在本文中,我们提出一种替代架构,并利用遥控潜水器采集的深水视频序列对该架构进行测试。该架构由以下4个模块组成:(1)预处理;(2)目标检测与分类;(3)目标追踪;(4)量化。在可用的测试视频中,对基于视频的自动丰度估算方法进行测试,并与专家人工计数结果(地表实值)比对,得到了令人鼓舞的结果。在可用的测试集中,所提出的系统在龙虾计数上的查准率和查全率达到100%,在龙虾洞计数上的查准率和查全率达到83%。

关键词:目标检测;目标追踪;特征提取;遥控潜水器

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1]Akbani R, Kwek S, Japkowicz N, 2004. Applying support vector machines to imbalanced datasets. Proc 15th European Conf on Machine Learning, p.39-50.

[2]Badekas E, Papamarkos N, 2005. Automatic evaluation of document binarization results. Proc 10th Iberoamerican Congress Conf on Progress in Patt Recognition, Image Analysis and Applications, p.1005-1014.

[3]Ben-Hur A, Weston J, 2010. A user’s guide to support vector machines. In: Carugo O, Eisenhaber F (Eds.), Data Mining Techniques for the Life Sciences. Humana Press, New York, p.223-239.

[4]Bernardin K, Stiefelhagen R, 2008. Evaluating multiple object tracking performance: the CLEAR MOT metrics. EURASIP J Image Video Process, 2008:246309.

[5]Bouguet JY, 2000. Pyramidal Implementation of the Lucas Kanade Feature Tracker Description of the Algorithm. Intel Corporation Microprocessor Research Labs, Santa Clara, USA.

[6]Correia PL, Lau PY, Fonseca P, et al., 2007. Underwater video analysis for Norway lobster stock quantification using multiple visual attention features. Proc 15th European Signal Processing Conf, p.1764-1768.

[7]Denise S, 2007. Homework Helpers: Calculus (Homework Helpers). Career Press, Wayne.

[8]Fonseca P, Correia PL, Campos A, et al., 2008. Fishery-independent estimation of benthic species density—a novel approach applied to Norway lobster Nephrops norvegicus. Mar Ecol Prog Ser, 369:267-271.

[9]Howard FG, 1989. The Norway lobster. Scott Fisher Inform Pamphl, No. 7.

[10]Johnsen S, Sosik H, 2004. Shedding light on light in the ocean. Ocean Mag, bf43(2):1-5.

[11]Kuhn HW, 1955. The Hungarian method for the assignment problem. Nav Res Log Q, 2(1-2):83-97.

[12]Lau PY, Correia PL, Fonseca P, et al., 2008. I2N2: a software for the classification of benthic habitats characteristics. Proc 16th European Signal Processing Conf, p.1-5.

[13]Lau PY, Correia PL, Fonseca P, et al., 2012. Estimating Norway lobster abundance from deep-water videos: an automatic approach. IET Image Process, 6(1):22-30.

[14]Morello EB, Froglia C, Atkinson RJA, 2007. Underwater television as a fishery-independent method for stock assessment of Norway lobster ( Nephrops norvegicus) in the central Adriatic Sea (Italy). ICES J Mar Sci, 64(6):1116-1123.

[15]Sardà F, Aguzzi J, 2012. A review of burrow counting as an alternative to other typical methods of assessment of Norway lobster populations. Rev Fish Biol Fisher, 22(2):409-422.

[16]Sauvola J, Pietikäinen M, 2000. Adaptive document image binarization. Patt Recogn, 33(2):225-236.

[17]Shafait F, Keysers D, Breuel TM, 2008. Efficient implementation of local adaptive thresholding techniques using integral images. Proc SPIE, 6815:10.

[18]Sooknanan K, Doyle J, Wilson J, et al., 2013. Mosaics for burrow detection in underwater surveillance video. OCEANS, p.1-6.

[19]Struc V, Vesnicer B, Pavesic N, 2008. The phase-based Gabor fisher classifier and its application to face recognition under varying illumination conditions. Proc 2nd Int Conf on Signal Processing and Communication Systems, p.1-6.

[20]Suzuki S, Be K, 1985. Topological structural analysis of digitized binary images by border following. Comput Vis Graph Image Process, 30(1):32-46.

[21]Tan CS, Lau PY, Low TJ, et al., 2014. Detection of marine species on underwater video images. Int Workshop on Advanced Image Technology, p.192-196.

[22]Tan CS, Lau PY, Correia PL, et al., 2015. A tracking scheme for Norway lobster and burrow abundance estimation in underwater video sequences. Proc Int Workshop on Advanced Image Technology.

[23]Yang CJ, Duraiswami R, Davis L, 2005. Fast multiple object tracking via a hierarchical particle filter. Proc IEEE Int Conf on Computer Vision, p.212-219.

Open peer comments: Debate/Discuss/Question/Opinion

<1>

Please provide your name, email address and a comment





Journal of Zhejiang University-SCIENCE, 38 Zheda Road, Hangzhou 310027, China
Tel: +86-571-87952783; E-mail: cjzhang@zju.edu.cn
Copyright © 2000 - 2024 Journal of Zhejiang University-SCIENCE