A Review of Modeling Approaches for Understanding and Monitoring the Environmental Effects of Marine Renewable Energy

Buenau, Kate E.; Garavelli, Lysel; Hemery, Lenaïg G.; García‐Medina, Gabriel

doi:10.3390/jmse10010094

Cited by 11 publications

(11 citation statements)

References 193 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…At turbine sites, this may inform monitoring requirements or the determination of acceptable collision risk levels. Additionally, the risk of collision of a fish with a turbine blade is assumed to be higher for larger fish (Hammar et al, 2015), and fish length distributions can serve as inputs to probability‐ and physics‐based models that estimate the probability of encounter or collision (Buenau et al, 2022). Acoustic cameras offer one approach to collecting these data, but their limitations should be considered relative to both study design and data interpretation.…”

Section: Capabilities Of Acoustic Cameras For Monitoring Fish Around ...mentioning

confidence: 99%

“…The interactions between fishes and their predators are important to understand when managing populations or communities, especially when anthropomorphic influences can lead to variations in predation levels (Murphy et al, 2021). Further, ecological modelling techniques used to study interactions between prey and predators have been applied to predict the risk of the collision of fish and turbines (Buenau et al, 2022). Avoidance and evasion behaviours associated with fish eluding predators can also be used to describe fish responses to the presence of moving turbine blades (Sparling et al, 2020), and acoustic camera observations of these behaviours are informative for collision risk assessments.…”

Section: Capabilities Of Acoustic Cameras For Monitoring Fish Around ...mentioning

confidence: 99%

See 1 more Smart Citation

Observing fish interactions with marine energy turbines using acoustic cameras

Cotter

Staines

2023

Fish and Fisheries

View full text Add to dashboard Cite

Marine current energy converters such as tidal and riverine turbines have the potential to provide reliable, clean power. The risk of collision of fishes with marine energy turbines is not yet well understood, in part due to the challenges associated with observing fish at turbine sites. Turbidity and light availability can limit the effectiveness of optical sensors like video cameras, motivating the use of acoustic cameras for this task. However, challenges persist in collecting and interpreting data acquired from acoustic cameras. Given the limited number of turbine deployments to date, it is prudent to draw on the application of acoustic cameras to monitor fish in other scenarios. This article synthesizes their use for other fisheries applications to inform best practices and set realistic expectations for the results of acoustic camera monitoring at turbine sites. We discuss six key tasks performed with acoustic cameras: detecting objects, identifying objects as fish, counting fish, measuring fish, classifying fish taxonomically and analysing fish behavior. Specific challenges to monitoring fish at turbine sites are discussed. This article is intended to serve as a reference for researchers, regulators and marine energy developers on effective use of acoustic cameras to monitor fish at turbine sites. The studies detailed in this article provide evidence that, in some scenarios, acoustic cameras can be used to inform the risk of fish collision with marine energy turbines but doing so requires careful study design and data processing.

show abstract

Section: Capabilities Of Acoustic Cameras For Monitoring Fish Around ...mentioning

confidence: 99%

Section: Capabilities Of Acoustic Cameras For Monitoring Fish Around ...mentioning

confidence: 99%

Observing fish interactions with marine energy turbines using acoustic cameras

Cotter

Staines

2023

Fish and Fisheries

View full text Add to dashboard Cite

show abstract

“…A comprehensive approach to stressor-receptor interaction research, monitoring, and modeling can advance the pace of ME development [16]. Predictive models can be used to evaluate the potential effects of ME projects, extend the utility of existing monitoring data, and prioritize future monitoring.…”

Section: Physical and Biological Modeling Recommendation Summarymentioning

confidence: 99%

“…Deployment of hydrophones and underwater acoustic cameras near the WEC using similar technologies to [10,11] for short-term deployments may provide information necessary for understanding seabird diving behavior around WECs and the exposure time to underwater noise and collision risk stressors. Data may be used in ecological models to understand population effects over time [16]. Collectively, these data may inform mitigations to reduce localized impacts and promote ecological resilience [36].…”

Section: Temporal Planning For Environmental Monitoringmentioning

confidence: 99%

See 1 more Smart Citation

A Summary of Environmental Monitoring Recommendations for Marine Energy Development That Considers Life Cycle Sustainability

Amerson

Harris

Michener

et al. 2022

JMSE

View full text Add to dashboard Cite

Recommendations derived from papers documenting the Triton Field Trials (TFiT) study of marine energy environmental monitoring technology and methods under the Triton Initiative (Triton), as reported in this Special Issue, are summarized here. Additionally, a brief synopsis describes how to apply the TFiT recommendations to establish an environmental monitoring campaign, and provides an overview describing the importance of identifying the optimal time to perform such campaigns. The approaches for tracking and measuring the effectiveness of recommendations produced from large environmental monitoring campaigns among the stakeholder community are discussed. The discussion extends beyond the initial scope of TFiT to encourage discussion regarding marine energy sustainability that includes life cycle assessment and other life cycle sustainability methodologies. The goal is to inspire stakeholder collaboration across topics associated with the marine energy industry, including diversity and inclusion, energy equity, and how Triton’s work connects within the context of the three pillars of energy sustainability: environment, economy, and society.

show abstract

Absorption of echo signal for underwater acoustic signal target system using hybrid of ensemble empirical mode with machine learning techniques

Ashok

Latha²

2023

Multimed Tools Appl

View full text Add to dashboard Cite

A Review of Modeling Approaches for Understanding and Monitoring the Environmental Effects of Marine Renewable Energy

Cited by 11 publications

References 193 publications

Observing fish interactions with marine energy turbines using acoustic cameras

Observing fish interactions with marine energy turbines using acoustic cameras

A Summary of Environmental Monitoring Recommendations for Marine Energy Development That Considers Life Cycle Sustainability

Absorption of echo signal for underwater acoustic signal target system using hybrid of ensemble empirical mode with machine learning techniques

Contact Info

Product

Resources

About