Analysis and control of acoustic emissions from marine energy converters

Journal Article

Title: Analysis and control of acoustic emissions from marine energy converters

Author:

He, J.; Malyi, M.; Shek, J.

Publication Date:

February 20, 2026

Journal:

Clean Energy

Volume:

Issue:

Pages:

136-145

Publisher:

Oxford Academic

Affiliation

University of Edinburgh

Technology:

Marine Energy, Tidal

Stressor:

Noise

Receptor:

Marine Mammals

Language:

English

Document Access

Website:

External Link

Attachment:

Access File

Citation

APA
BibTex
RIS

He, J.; Malyi, M.; Shek, J. (2026). Analysis and control of acoustic emissions from marine energy converters. Clean Energy, 10(2), 136-145. https://doi.org/10.1093/ce/zkag010

@article{He-2026-,
author = {He, J and Malyi, M and Shek, J},
title = {Analysis and control of acoustic emissions from marine energy converters},
journal = {Clean Energy},
year = {2026},
month = {feb},
publisher = {Oxford Academic},
volume = {10},
number = {2},
pages = {136--145},
doi = {10.1093/ce/zkag010},
url = {https://academic.oup.com/ce/article/10/2/136/8493128},
keywords = {Marine Energy, Tidal, Noise, Marine Mammals},
}

Export Citation to BibTex

TY - JOUR
TI - Analysis and control of acoustic emissions from marine energy converters
AU - He, J
AU - Malyi, M
AU - Shek, J
T2 - Clean Energy
AB - Environmental licensing related to underwater acoustic emissions represents a critical bottleneck for the commercial deployment of marine renewable energy. This study presents a control engineering framework to mitigate acoustic risks from tidal current converters (TCCs) without compromising project viability. A MATLAB/Simulink model of a TCC was utilized to evaluate two distinct mitigation tiers: (i) architectural modification, comparing a geared induction generator against a direct-drive permanent magnet synchronous generator (PMSG) and (ii) operational control, analysing the impact of switching frequencies and maximum power point tracking coefficient (⁠Kopt) tuning. Results indicate that lowering switching frequencies (⁠Fs⁠) is ineffective, increasing power electronic losses by over 2000% with negligible acoustic benefit. Conversely, the direct-drive PMSG architecture reduced sound pressure levels by ∼10 dB re 1μPa, effectively eliminating mechanical tonal noise. For existing geared systems, de-tuning the Kopt coefficient by a factor of 1.2 reduced the probability of exceeding temporary threshold shift limits for marine mammals, with a quantified energy yield reduction of 3.58%. These findings propose a hierarchical mitigation strategy: selecting direct-drive topologies for acoustically sensitive sites, and utilizing maximum power point tracking coefficient based power curtailment as a transient operational mode during critical biological migration periods.
DA - 2026/02//
PY - 2026
PB - Oxford Academic
VL - 10
IS - 2
SP - 136
EP - 145
UR - https://academic.oup.com/ce/article/10/2/136/8493128
DO - 10.1093/ce/zkag010
LA - English
KW - Marine Energy
KW - Tidal
KW - Noise
KW - Marine Mammals
ER -

Export Citation to RIS

Abstract

Environmental licensing related to underwater acoustic emissions represents a critical bottleneck for the commercial deployment of marine renewable energy. This study presents a control engineering framework to mitigate acoustic risks from tidal current converters (TCCs) without compromising project viability. A MATLAB/Simulink model of a TCC was utilized to evaluate two distinct mitigation tiers: (i) architectural modification, comparing a geared induction generator against a direct-drive permanent magnet synchronous generator (PMSG) and (ii) operational control, analysing the impact of switching frequencies and maximum power point tracking coefficient (⁠K_opt) tuning. Results indicate that lowering switching frequencies (⁠F_s⁠) is ineffective, increasing power electronic losses by over 2000% with negligible acoustic benefit. Conversely, the direct-drive PMSG architecture reduced sound pressure levels by ∼10 dB re 1μPa, effectively eliminating mechanical tonal noise. For existing geared systems, de-tuning the K_optcoefficient by a factor of 1.2 reduced the probability of exceeding temporary threshold shift limits for marine mammals, with a quantified energy yield reduction of 3.58%. These findings propose a hierarchical mitigation strategy: selecting direct-drive topologies for acoustically sensitive sites, and utilizing maximum power point tracking coefficient based power curtailment as a transient operational mode during critical biological migration periods.