Using Recreation‐Grade Side‐Scan Sonar to Produce Classified Maps of Submerged Aquatic Vegetation

Bennett, Daniel; Bister, Timothy J.; Ott, Richard A.

doi:10.1002/nafm.10386

Cited by 7 publications

(4 citation statements)

References 40 publications

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Section: Available Sensorsmentioning

confidence: 99%

“…A single beam echosounder produces transects of data (Figure 7), while a multibeam echosounder can create acoustic images with two dimensions of pixels [33]. Side scanners also produce acoustic images and are especially effective in macrophyte studies as their horizontal plane intersects vertically growing plants [33,69,70]. The exclusively positional data provided by acoustic sensors cannot provide information about the species, health or maturity of vegetation; the applications of such sensors are thus limited to structural information.…”

Section: Available Sensorsmentioning

confidence: 99%

“…It has been found that hydroacoustic methods produce higher SAV height and percent cover measurements than those from divers or imagery. Hydroacoustic methods may therefore not capture modest changes in SAV conditions and are not suited to direct comparison with data gathered through other methods [70,90]. Still, ongoing innovations in hydroacoustic RS-such as the Dual-frequency Identification Sonar, which produces acoustic video footage-are expected to make acoustic RS more appealing and accessible for work in turbid waters [33].…”

Section: Available Sensorsmentioning

confidence: 99%

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A Review of Remote Sensing of Submerged Aquatic Vegetation for Non-Specialists

Rowan

Kalácska

2021

Remote Sensing

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Submerged aquatic vegetation (SAV) is a critical component of aquatic ecosystems. It is however understudied and rapidly changing due to global climate change and anthropogenic disturbances. Remote sensing (RS) can provide the efficient, accurate and large-scale monitoring needed for proper SAV management and has been shown to produce accurate results when properly implemented. Our objective is to introduce RS to researchers in the field of aquatic ecology. Applying RS to underwater ecosystems is complicated by the water column as water, and dissolved or suspended particulate matter, interacts with the same energy that is reflected or emitted by the target. This is addressed using theoretical or empiric models to remove the water column effect, though no model is appropriate for all aquatic conditions. The suitability of various sensors and platforms to aquatic research is discussed in relation to both SAV as the subject and to project aims and resources. An overview of the required corrections, processing and analysis methods for passive optical imagery is presented and discussed. Previous applications of remote sensing to identify and detect SAV are briefly presented and notable results and lessons are discussed. The success of previous work generally depended on the variability in, and suitability of, the available training data, the data’s spatial and spectral resolutions, the quality of the water column corrections and the level to which the SAV was being investigated (i.e., community versus species.)

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Section: Available Sensorsmentioning

confidence: 99%

Section: Available Sensorsmentioning

confidence: 99%

Section: Available Sensorsmentioning

confidence: 99%

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A Review of Remote Sensing of Submerged Aquatic Vegetation for Non-Specialists

Rowan

Kalácska

2021

Remote Sensing

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“…Recreation-grade SSS instruments have enabled scientists to manually and semi-manually map the benthos. Applications include mapping large wood (Kaeser and Litts, 2008;Holcomb et al, 2020), substrate (Kaeser and Litts, 2010;Kaeser et al, 2013;Cheek et al, 2016;Walker and Alford, 2016;Scholl et al, 2021), meso-habitats (Smit and Kaeser, 2016;Kaeser et al, 2019), fish abundance (Bollinger and Kline, 2017;Lawson et al, 2020;Wolfenkoehler et al, 2023), and aquatic vegetation (Bennett et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Open-source approach for reproducible substrate mapping using semantic segmentation on recreation-grade side scan sonar datasets

Bodine,

Buscombe,

Hocking

2023

Preprint

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Knowledge of the variation and distribution of substrates at large spatial extents in aquatic systems, particularly rivers, is severely lacking, impeding species conservation and ecosystem restoration efforts. Air and space-borne remote sensing important for terrestrial and atmospheric measurements are limited in benthic environments due to river stage, turbidity, and canopy cover, requiring direct observation of conditions in the field. Recreation-grade side scan sonar (SSS) instruments, or fishfinders, have demonstrated their unparalleled value as a low-cost scientific instrument capable of rapidly imaging benthic environments due to the ease of deploying and operating the instrument. However, existing methods for generating georeferenced datasets from these instruments, including sonar mosaics and substrate maps, remains a barrier of adoption for wider scientific inquiry due to the high degree of human-intervention and expertise required to generate these datasets. To address this short-coming, we introduced PING-Mapper; an open-source and freely available Python-based software for generating geospatial benthic datasets from popular Humminbird® instruments reproducibly, with minimal intervention from the user. The previously released Version 1.0 of the software provided automated workflows for exporting georeferenced sonar imagery. This study extends functionality with Version 2.0 by incorporating semantic segmentation with deep neural network models to reproducibly map substrates at large spatial extents. We present a novel approach for generating label-ready sonar datasets, creating label-image training sets, and model training with transfer learning; all with readily available open-source tools. The substrate models, achieving overall accuracies of 78%, are integrated into PING-Mapper v2.0, providing an automated workflow to generate map substrate distribution anywhere. Additional workflows enable masking sonar shadows, calculating independent bedpicks, and correcting attenuation effects in the imagery to improve interpretability. This software provides an improved mechanism for generating geospatial benthic datasets from recreation-grade SSS systems, thereby lowering the barrier for inclusion in wider aquatic research.

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A comparison of recreational and survey‐grade side‐scan sonar systems in mapping reservoir fish habitat

Fletcher,

Booth,

Pritt

2024

N American J Fish Manag

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ObjectiveLittoral zone aquatic habitat is an important component of sport fish population dynamics in freshwater lakes and reservoirs and is a primary target of fisheries management actions. However, habitat data for these systems are often minimal or nonexistent due to the cost and time‐consuming nature of traditional aquatic habitat sampling methods. Side‐scan sonar has been identified as a potential tool that can address these limitations, allowing quantification of habitat features over large areas. Side‐scan sonar is available in two forms: recreational (consumer grade) and professional (survey grade). Our goal was to compare these two grades of side‐scan sonar by analyzing their ability to map littoral habitat features in three Ohio reservoirs.MethodsWe used a Lowrance Active Imaging 3‐in‐1 system (≈US$2000) recreational sonar and an EdgeTech 6205 system (≈$150,000) survey‐grade sonar to collect imagery in the littoral zones of reservoirs. We manually quantified submerged woody debris, standing timber, aquatic vegetation, and benthic substrate in a geographical information system (GIS) using imagery from each sonar system and compared habitat estimates and GIS processing times. We analyzed how differences in image resolution between the two sonar systems affected the level of variation in habitat classification values generated by individual analysts.ResultWe found small differences in habitat classification values and accuracy between the two sonar systems, and trade‐offs existed in spatial accuracy and ability to image dense vegetation. However, side‐scan data acquisition, postprocessing, and habitat classification were generally less time‐intensive with the recreational Lowrance system than with the survey‐grade EdgeTech system. Unexpectedly, the lower quality Lowrance imagery had less user‐based variation in GIS habitat classification.ConclusionRecreational side‐scan sonar systems such as the Lowrance system provide sufficient imagery resolution, habitat classification values, and accuracy at a lower cost and with less processing time than survey‐grade side‐scan sonar systems and are useful tools for quantifying littoral habitat features in reservoirs.

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Using Recreation‐Grade Side‐Scan Sonar to Produce Classified Maps of Submerged Aquatic Vegetation

Cited by 7 publications

References 40 publications

A Review of Remote Sensing of Submerged Aquatic Vegetation for Non-Specialists

A Review of Remote Sensing of Submerged Aquatic Vegetation for Non-Specialists

Open-source approach for reproducible substrate mapping using semantic segmentation on recreation-grade side scan sonar datasets

A comparison of recreational and survey‐grade side‐scan sonar systems in mapping reservoir fish habitat

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