POWER-Net: Predictive Optimization and Wave Energy Regulation in Networked WEC Systems

Conference Paper

Title: POWER-Net: Predictive Optimization and Wave Energy Regulation in Networked WEC Systems

Author:

Hashemi, Z.; Maity, D.; Wolek, A.

Publication Date:

August 13, 2025

Event Name:

OREC/UMERC 2025 Conference

Event Session:

Strategies for Marine Energy Device Deployment, Operations and Maintenance

Event Location:

Corvallis, United States of America

Pages:

Affiliation:

University of North Carolina at Charlotte

Technology:

Wave

Collection Method:

Modeling

Engineering:

Array Effects, Performance

Language:

English

Document Access

Website:

External Link

Attachment:

Access File

Notice: This material may be protected by Copyright Law.

Citation

APA
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Hashemi, Z.; Maity, D.; Wolek, A. (2025). POWER-Net: Predictive Optimization and Wave Energy Regulation in Networked WEC Systems. Paper presented at OREC/UMERC 2025 Conference, Corvallis, United States of America.

@conference{Hashemi-2025-,
author = {Hashemi, Z and Maity, D and Wolek, A},
title = {POWER-Net: Predictive Optimization and Wave Energy Regulation in Networked WEC Systems},
year = {2025},
month = {aug},
series = {OREC/UMERC 2025 Conference},
pages = {15},
address = {Corvallis, United States of America},
url = {https://umerc2025.exordo.com/programme/presentation/94},
keywords = {Wave, Modeling, Array Effects, Performance},
}

Export Citation to BibTex

TY - CONF
TI - POWER-Net: Predictive Optimization and Wave Energy Regulation in Networked WEC Systems
AU - Hashemi, Z
AU - Maity, D
AU - Wolek, A
T2 - OREC/UMERC 2025 Conference
C1 - Corvallis, United States of America
AB - This work presents a control framework for maximizing energy extraction in arrays of wave energy converters (WECs) operating in hydrodynamically coupled environments. Each WEC’s motion influences others through radiated wave interactions, making coordinated control essential. We model the coupled dynamics using Cummins’ equation and design a centralized controller that computes optimal control inputs for all WECs based on collective state information. To reduce communication burden, we investigate an event-triggered communication strategy where WECs transmit sensor data only when necessary. We analyze the impact of communication frequency on energy capture and quantify the trade-off between communication overhead and performance. Simulation results show that intermittent communication can achieve near-optimal power extraction while significantly reducing communication requirements.The presentation from OREC/UMERC 2025 can be found here.
DA - 2025/08//
PY - 2025
SP - 15
UR - https://umerc2025.exordo.com/programme/presentation/94
LA - English
KW - Wave
KW - Modeling
KW - Array Effects
KW - Performance
ER -

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Abstract

This work presents a control framework for maximizing energy extraction in arrays of wave energy converters (WECs) operating in hydrodynamically coupled environments. Each WEC’s motion influences others through radiated wave interactions, making coordinated control essential. We model the coupled dynamics using Cummins’ equation and design a centralized controller that computes optimal control inputs for all WECs based on collective state information. To reduce communication burden, we investigate an event-triggered communication strategy where WECs transmit sensor data only when necessary. We analyze the impact of communication frequency on energy capture and quantify the trade-off between communication overhead and performance. Simulation results show that intermittent communication can achieve near-optimal power extraction while significantly reducing communication requirements.

The presentation from OREC/UMERC 2025 can be found here.