Analyzing the impact of aeroelastic model fidelity on control co-design optimization of floating offshore wind turbines

Robert Behrens de Luna, Francesco Papi, David Marten, and Christian Oliver Paschereit

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Total article views: 886 (including HTML, PDF, and XML)

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HTML: 651
PDF: 202
XML: 33
Total: 886
BibTeX: 28
EndNote: 38

Views and downloads (calculated since 25 Sep 2025)

Month	HTML	PDF	XML	Total
Sep 2025	134	9	4	147
Oct 2025	125	25	9	159
Nov 2025	95	37	9	141
Dec 2025	181	87	11	279
Jan 2026	116	44	0	160

Cumulative views and downloads (calculated since 25 Sep 2025)

Month	HTML	PDF	XML	Total
Sep 2025	134	9	4	147
Oct 2025	125	25	9	159
Nov 2025	95	37	9	141
Dec 2025	181	87	11	279
Jan 2026	116	44	0	160

HTML	PDF	XML	Total	BibTeX	EndNote
224	78	4	306	3	4

HTML	PDF	XML	Total	BibTeX	EndNote
427	124	29	580	25	34

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Total article views: 886 (including HTML, PDF, and XML) Thereof 869 with geography defined and 17 with unknown origin.

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Latest update: 09 Jan 2026

Short summary

Floating offshore wind turbines make wind resources in deeper waters accessible. However, these systems are more complex and costly than fixed-bottom wind turbines and require further optimization to reduce cost. This study analyzed the effect of aeroelastic modeling fidelity on the design of the floater and the wind turbine controller. The results showed that an increase in fidelity resulted in lighter platforms, influenced controller parameters and led to lower costs overall.