Blind testing of shoreline evolution models

Jennifer Montaño; Giovanni Coco; Jose A.A. Antolínez; Tomas Beuzen; Karin R. Bryan; Laura Cagigal; Bruno Castelle; Mark A. Davidson; Evan B. Goldstein; Raimundo Ibaceta; Déborah Idier; Bonnie C. Ludka; Sina Masoud-Ansari; Fernando J. Méndez; A. Brad Murray; Nathaniel G. Plant; Katherine M. Ratliff; Arthur Robinet; Ana Rueda; Nadia Sénéchal; Joshua A. Simmons; Kristen D. Splinter; Scott Stephens; Ian Townend; Sean Vitousek; Kilian Vos

doi:10.1038/s41598-020-59018-y

Blind testing of shoreline evolution models

Jennifer Montaño^*, Giovanni Coco, Jose A.A. Antolínez, Tomas Beuzen, Karin R. Bryan, Laura Cagigal, Bruno Castelle, Mark A. Davidson, Evan B. Goldstein, Raimundo Ibaceta, Déborah Idier, Bonnie C. Ludka, Sina Masoud-Ansari, Fernando J. Méndez, A. Brad Murray, Nathaniel G. Plant, Katherine M. Ratliff, Arthur Robinet, Ana Rueda, Nadia SénéchalJoshua A. Simmons, Kristen D. Splinter, Scott Stephens, Ian Townend, Sean Vitousek, Kilian Vos

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

69 Citations (Scopus)

Abstract

Beaches around the world continuously adjust to daily and seasonal changes in wave and tide conditions, which are themselves changing over longer time-scales. Different approaches to predict multi-year shoreline evolution have been implemented; however, robust and reliable predictions of shoreline evolution are still problematic even in short-term scenarios (shorter than decadal). Here we show results of a modelling competition, where 19 numerical models (a mix of established shoreline models and machine learning techniques) were tested using data collected for Tairua beach, New Zealand with 18 years of daily averaged alongshore shoreline position and beach rotation (orientation) data obtained from a camera system. In general, traditional shoreline models and machine learning techniques were able to reproduce shoreline changes during the calibration period (1999–2014) for normal conditions but some of the model struggled to predict extreme and fast oscillations. During the forecast period (unseen data, 2014–2017), both approaches showed a decrease in models’ capability to predict the shoreline position. This was more evident for some of the machine learning algorithms. A model ensemble performed better than individual models and enables assessment of uncertainties in model architecture. Research-coordinated approaches (e.g., modelling competitions) can fuel advances in predictive capabilities and provide a forum for the discussion about the advantages/disadvantages of available models.

Original language	English
Article number	2137
Journal	Scientific Reports
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41598-020-59018-y
Publication status	Published - 1 Dec 2020
Externally published	Yes

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Montaño, J., Coco, G., Antolínez, J. A. A., Beuzen, T., Bryan, K. R., Cagigal, L., Castelle, B., Davidson, M. A., Goldstein, E. B., Ibaceta, R., Idier, D., Ludka, B. C., Masoud-Ansari, S., Méndez, F. J., Murray, A. B., Plant, N. G., Ratliff, K. M., Robinet, A., Rueda, A., ... Vos, K. (2020). Blind testing of shoreline evolution models. Scientific Reports, 10(1), [2137]. https://doi.org/10.1038/s41598-020-59018-y

Montaño, Jennifer ; Coco, Giovanni ; Antolínez, Jose A.A. ; Beuzen, Tomas ; Bryan, Karin R. ; Cagigal, Laura ; Castelle, Bruno ; Davidson, Mark A. ; Goldstein, Evan B. ; Ibaceta, Raimundo ; Idier, Déborah ; Ludka, Bonnie C. ; Masoud-Ansari, Sina ; Méndez, Fernando J. ; Murray, A. Brad ; Plant, Nathaniel G. ; Ratliff, Katherine M. ; Robinet, Arthur ; Rueda, Ana ; Sénéchal, Nadia ; Simmons, Joshua A. ; Splinter, Kristen D. ; Stephens, Scott ; Townend, Ian ; Vitousek, Sean ; Vos, Kilian. / Blind testing of shoreline evolution models. In: Scientific Reports. 2020 ; Vol. 10, No. 1.

@article{546c229bfd6e4670b089f5c7be22cc55,

title = "Blind testing of shoreline evolution models",

abstract = "Beaches around the world continuously adjust to daily and seasonal changes in wave and tide conditions, which are themselves changing over longer time-scales. Different approaches to predict multi-year shoreline evolution have been implemented; however, robust and reliable predictions of shoreline evolution are still problematic even in short-term scenarios (shorter than decadal). Here we show results of a modelling competition, where 19 numerical models (a mix of established shoreline models and machine learning techniques) were tested using data collected for Tairua beach, New Zealand with 18 years of daily averaged alongshore shoreline position and beach rotation (orientation) data obtained from a camera system. In general, traditional shoreline models and machine learning techniques were able to reproduce shoreline changes during the calibration period (1999–2014) for normal conditions but some of the model struggled to predict extreme and fast oscillations. During the forecast period (unseen data, 2014–2017), both approaches showed a decrease in models{\textquoteright} capability to predict the shoreline position. This was more evident for some of the machine learning algorithms. A model ensemble performed better than individual models and enables assessment of uncertainties in model architecture. Research-coordinated approaches (e.g., modelling competitions) can fuel advances in predictive capabilities and provide a forum for the discussion about the advantages/disadvantages of available models.",

author = "Jennifer Monta{\~n}o and Giovanni Coco and Antol{\'i}nez, {Jose A.A.} and Tomas Beuzen and Bryan, {Karin R.} and Laura Cagigal and Bruno Castelle and Davidson, {Mark A.} and Goldstein, {Evan B.} and Raimundo Ibaceta and D{\'e}borah Idier and Ludka, {Bonnie C.} and Sina Masoud-Ansari and M{\'e}ndez, {Fernando J.} and Murray, {A. Brad} and Plant, {Nathaniel G.} and Ratliff, {Katherine M.} and Arthur Robinet and Ana Rueda and Nadia S{\'e}n{\'e}chal and Simmons, {Joshua A.} and Splinter, {Kristen D.} and Scott Stephens and Ian Townend and Sean Vitousek and Kilian Vos",

year = "2020",

month = dec,

day = "1",

doi = "10.1038/s41598-020-59018-y",

language = "English",

volume = "10",

journal = "Scientific Reports",

issn = "2045-2322",

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Montaño, J, Coco, G, Antolínez, JAA, Beuzen, T, Bryan, KR, Cagigal, L, Castelle, B, Davidson, MA, Goldstein, EB, Ibaceta, R, Idier, D, Ludka, BC, Masoud-Ansari, S, Méndez, FJ, Murray, AB, Plant, NG, Ratliff, KM, Robinet, A, Rueda, A, Sénéchal, N, Simmons, JA, Splinter, KD, Stephens, S, Townend, I, Vitousek, S & Vos, K 2020, 'Blind testing of shoreline evolution models', Scientific Reports, vol. 10, no. 1, 2137. https://doi.org/10.1038/s41598-020-59018-y

Blind testing of shoreline evolution models. / Montaño, Jennifer; Coco, Giovanni; Antolínez, Jose A.A.; Beuzen, Tomas; Bryan, Karin R.; Cagigal, Laura; Castelle, Bruno; Davidson, Mark A.; Goldstein, Evan B.; Ibaceta, Raimundo; Idier, Déborah; Ludka, Bonnie C.; Masoud-Ansari, Sina; Méndez, Fernando J.; Murray, A. Brad; Plant, Nathaniel G.; Ratliff, Katherine M.; Robinet, Arthur; Rueda, Ana; Sénéchal, Nadia; Simmons, Joshua A.; Splinter, Kristen D.; Stephens, Scott; Townend, Ian; Vitousek, Sean; Vos, Kilian.

In: Scientific Reports, Vol. 10, No. 1, 2137, 01.12.2020.

Research output: Contribution to journal › Article › peer-review

TY - JOUR

T1 - Blind testing of shoreline evolution models

AU - Montaño, Jennifer

AU - Coco, Giovanni

AU - Antolínez, Jose A.A.

AU - Beuzen, Tomas

AU - Bryan, Karin R.

AU - Cagigal, Laura

AU - Castelle, Bruno

AU - Davidson, Mark A.

AU - Goldstein, Evan B.

AU - Ibaceta, Raimundo

AU - Idier, Déborah

AU - Ludka, Bonnie C.

AU - Masoud-Ansari, Sina

AU - Méndez, Fernando J.

AU - Murray, A. Brad

AU - Plant, Nathaniel G.

AU - Ratliff, Katherine M.

AU - Robinet, Arthur

AU - Rueda, Ana

AU - Sénéchal, Nadia

AU - Simmons, Joshua A.

AU - Splinter, Kristen D.

AU - Stephens, Scott

AU - Townend, Ian

AU - Vitousek, Sean

AU - Vos, Kilian

PY - 2020/12/1

Y1 - 2020/12/1

N2 - Beaches around the world continuously adjust to daily and seasonal changes in wave and tide conditions, which are themselves changing over longer time-scales. Different approaches to predict multi-year shoreline evolution have been implemented; however, robust and reliable predictions of shoreline evolution are still problematic even in short-term scenarios (shorter than decadal). Here we show results of a modelling competition, where 19 numerical models (a mix of established shoreline models and machine learning techniques) were tested using data collected for Tairua beach, New Zealand with 18 years of daily averaged alongshore shoreline position and beach rotation (orientation) data obtained from a camera system. In general, traditional shoreline models and machine learning techniques were able to reproduce shoreline changes during the calibration period (1999–2014) for normal conditions but some of the model struggled to predict extreme and fast oscillations. During the forecast period (unseen data, 2014–2017), both approaches showed a decrease in models’ capability to predict the shoreline position. This was more evident for some of the machine learning algorithms. A model ensemble performed better than individual models and enables assessment of uncertainties in model architecture. Research-coordinated approaches (e.g., modelling competitions) can fuel advances in predictive capabilities and provide a forum for the discussion about the advantages/disadvantages of available models.

AB - Beaches around the world continuously adjust to daily and seasonal changes in wave and tide conditions, which are themselves changing over longer time-scales. Different approaches to predict multi-year shoreline evolution have been implemented; however, robust and reliable predictions of shoreline evolution are still problematic even in short-term scenarios (shorter than decadal). Here we show results of a modelling competition, where 19 numerical models (a mix of established shoreline models and machine learning techniques) were tested using data collected for Tairua beach, New Zealand with 18 years of daily averaged alongshore shoreline position and beach rotation (orientation) data obtained from a camera system. In general, traditional shoreline models and machine learning techniques were able to reproduce shoreline changes during the calibration period (1999–2014) for normal conditions but some of the model struggled to predict extreme and fast oscillations. During the forecast period (unseen data, 2014–2017), both approaches showed a decrease in models’ capability to predict the shoreline position. This was more evident for some of the machine learning algorithms. A model ensemble performed better than individual models and enables assessment of uncertainties in model architecture. Research-coordinated approaches (e.g., modelling competitions) can fuel advances in predictive capabilities and provide a forum for the discussion about the advantages/disadvantages of available models.

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U2 - 10.1038/s41598-020-59018-y

DO - 10.1038/s41598-020-59018-y

M3 - Article

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VL - 10

JO - Scientific Reports

JF - Scientific Reports

SN - 2045-2322

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ER -

Blind testing of shoreline evolution models

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