Literature review; change to file layout

2022-02-04 14:52:03 +01:00 · 2022-02-04 14:52:03 +01:00 · 26bd60624d
parent 723d859f0c
commit 26bd60624d
5 changed files with 229 additions and 82 deletions
--- a/biblio/bibliography_research.tex
+++ b/biblio/bibliography_research.tex
@ -0,0 +1,58 @@
 \chapter{Bibliography research}
 \section{Extracting components from buoy data}
 \paragraph{incident and reflected wave separation}
 \cite{mansard1980measurement}: extract incident and reflected spectra from
 spectrum measurements at three different points.
 \cite{suh2001separation,frigaard1995time,baldock1999separation,
 roge2019estimation,andersen2017estimation}
 \paragraph{incident and reflected wave separation single gauge}
 \paragraph{incident and reflected wave separation puv method}
 Probablement très intéressant: \cite{inch2016accurate}:
 \cite{sheremet2002observations,guza1977resonant}
 Très bien: \cite{huntley1999use,tatavarti1989incoming}
 \cite{pedersen2007resolving}
 \paragraph{puv method}
 \cite{sobey1999locally}
 \paragraph{artha breakwater reflection}
 \cite{poncet2020wave,larroque2018situ}
 \section{Reflection}
 \paragraph{wave reflection analysis}
 \cite{davidson1996new}
 \section{Modeling wave impact on porous media}
 \paragraph{olaFlow}
 \cite{olaFlow,higuera2015application}: \cite{bogdanov2011direct,del2011three}
 \section{Breakwater modeling}
 \paragraph{modelling breakwater} sph: \cite{altomare2014numerical};
 \paragraph{rubble-mound breakwater model} \cite{vanneste20152d,
 sumer2000experimental,kim2005neural,troch1999development,koley2020numerical,
 losada1979joint,lara2008wave,losada2008numerical}
 \paragraph{breakwater model} \cite{hsu2002}
 \section{Modeling}
 \paragraph{using wave buoy data in numerical models} \cite{thomas2015,
 mentaschi2013,rusu2011}
 \section{Block displacement}
 \paragraph{boulder transport by waves} \cite{erdmann2018boulder,may2015block,
 weiss2012mystery,weiss2015untangling,zainali2015boulder,zainali2016high}
 \paragraph{boulder transport flow} \cite{nandasena2011reassessment,
 nandasena2013boulder,martinez2011quasi,kennedy2016observations,lodhi2020role,
 oetjen2021experiments,oetjen2020significance}
 \paragraph{storm waves boulder interaction} \cite{nandasena2011numerical}
 Très intéressant: \cite{weiss2017toward},
 \cite{sheremet2002observations,sheremet2016triads}
 \paragraph{block transport by waves} \cite{imamura2008numerical,
 barbano2010large,PARIS20111,biolchi2016}
 \section{Other}
 \cite{miche1951}
 \section{Flow in porous media}
 \paragraph{wave flow porous media} \cite{SHAO2010304}
--- a/biblio/introduction.tex
+++ b/biblio/introduction.tex
@ -0,0 +1,21 @@
 \chapter{Introduction}
 In February 2017, a \SI{50}{\tonne} concrete block was displaced by a wave onto
 the Artha breakwater in Saint-Jean-de-Luz. This event was captured by a
 photographer, and earlier work from \textcite{amir} allowed to extract the
 conditions under which this event happened using field data along with
 numerical modeling.
 The goal of the present study is to establish a numerical model representing
 the conditions under which this block displacement event happened at the scale
 of the breakwater. The simulation will be performed using the olaFlow
 \parencite{olaFlow} model in a three-dimensionnal setting.
 This study presents several aspects that are crucial to consider in order to
 obtain accurate results. The seastate that lead to the studied event is known
 thanks to a wave buoy located in front of the breakwater \parencite{amir}.
 However, in order to input an accurate incident wave into the numerical model,
 it will be necessary to extract the incident and reflected waves from the raw
 buoy data. Then, it will be necessary to accurately model the Artha breakwater,
 especially regarding its porous character. Finally, the results of this
 simulation will need to be compared to the literature on block displacement by
 waves for validation.
--- a/biblio/library.bib
+++ b/biblio/library.bib
@ -624,3 +624,73 @@
 	issue = {1},
 	doi = {10.51400/2709-6998.2138},
 }
@inbook{gaillard1980,
 	author = {Pierre Gaillard  and Michel Gauthier  and Forrest Holly },
 	title = {Method of Analysis of Random Wave Experiments with Reflecting Coastal Structures},
 	year = {1980},
 	booktitle = {Coastal Engineering 1980},
 	pages = {204-220},
 	doi = {10.1061/9780872622647.011},
 	URL = {https://ascelibrary.org/doi/abs/10.1061/9780872622647.011},
 	eprint = {https://ascelibrary.org/doi/pdf/10.1061/9780872622647.011},
 }
@inbook{guza1984,
 	author = {R. T. Guza  and E. B. Thornton  and R. A. Holman },
 	title = {Swash on Steep and Shallow Beaches},
 	booktitle = {Coastal Engineering 1984},
 	chapter = {},
 	year = {1984},
 	pages = {708-723},
 	doi = {10.1061/9780872624382.049},
 	URL = {https://ascelibrary.org/doi/abs/10.1061/9780872624382.049},
 	eprint = {https://ascelibrary.org/doi/pdf/10.1061/9780872624382.049},
 }
@inbook{kubota1990,
 	author = {Susumu Kubota  and Masaru Mizuguchi  and Mitsuo Takezawa },
 	title = {Reflection from Swash Zone on Natural Beaches},
 	booktitle = {Coastal Engineering 1990},
 	year = {1990},
 	chapter = {},
 	pages = {570-583},
 	doi = {10.1061/9780872627765.046},
 	URL = {https://ascelibrary.org/doi/abs/10.1061/9780872627765.046},
 	eprint = {https://ascelibrary.org/doi/pdf/10.1061/9780872627765.046},
 }
@article{walton1992,
 	title = {Wave reflection from natural beaches},
 	journal = {Ocean Engineering},
 	volume = {19},
 	number = {3},
 	pages = {239-258},
 	year = {1992},
 	issn = {0029-8018},
 	doi = {https://doi.org/10.1016/0029-8018(92)90027-2},
 	url = {https://www.sciencedirect.com/science/article/pii/0029801892900272},
 	author = {T.L. Walton},
 }
@article{hughes1993,
 	title = {Laboratory wave reflection analysis using co-located gages},
 	journal = {Coastal Engineering},
 	volume = {20},
 	number = {3},
 	pages = {223-247},
 	year = {1993},
 	issn = {0378-3839},
 	doi = {https://doi.org/10.1016/0378-3839(93)90003-Q},
 	url = {https://www.sciencedirect.com/science/article/pii/037838399390003Q},
 	author = {Steven A. Hughes},
 }
@report{miche1951,
 	title = {Le pouvoir réfléchissant des ouvrages maritimes exposés à l'action
 		de la houle},
 	author = {Miche, M.},
 	year = {1951},
 	publisher = {École nationale des ponts et chaussées},
 	booktitle = {Hydraulic Engineering Reports},
 }
--- a/biblio/literature.tex
+++ b/biblio/literature.tex
@ -0,0 +1,72 @@
 \chapter{Literature Review}
 In this chapter, literature relevant to the present study will be reviewed.
 \section{Separating incident and reflected components from wave buoy data}
 The separation of incident and reflected waves is a crucial step in numerically
 modeling a seastate. Using the raw data from a buoy as the input of a wave
 model will lead to incorrect results in the domain as the flow velocity at the
 boundary will not be correctly generated.
 Several methods exist to extract reflected components in measured seastates,
 and they can generally be categorised in two types of methods: array methods
 and PUV methods \parencite{inch2016accurate}. Array methods rely on the use of
 multiple measurement points of water level to extracted the incident and
 reflected waves, while PUV methods use colocated pressure and velocity
 measurements to separate incident and reflected components of the signal.
 \subsection{Array methods}
 \begin{itemize}
 	\item \cite{mansard1980measurement}: Presentation of least-square method to separate
 incident and reflected spectra. Requires simultaneous measurement at 3
 positions, on a line parallel to the direction of wave propagation.
 \parencite{gaillard1980}
 	\item \cite{frigaard1995time}: Separate 2D wave field into waves propagating towards
 and away from a structure, using 2 gauges. Method quite efficient, even with
 small filters. SIRW Method, realtime.
 	\item \cite{baldock1999separation}: Starting from \textcite{frigaard1995time},
 arbitrary 2D bathymetry using linear shoaling. Small error for large reflection
 coefficients, larger for low reflection.
 	\item \cite{suh2001separation}: Technique to separate incident and reflected waves on
 a known current.
 	\item \cite{inch2016accurate}: creation of a lookup table to correct noise-induced
 bias in array methods.
 	\item \cite{andersen2017estimation}: estimation of incident and reflected components
 for non-linear waves.
 	\item \cite{roge2019estimation}: extension to irregular waves.
 \end{itemize}
 \subsection{PUV methods}
 \begin{itemize}
 	\item ?? \cite{guza1977resonant}: model of the surf zone as a standing wave combined
 with a progressive wave. Accurate results of surface elevation and runup for
 reflectivities over 0.3.
 	\item ?? \cite{guza1984}: 
 	\item \cite{tatavarti1989incoming}: Decompose colocated random field
 		measurements of wave elevation and currenct velocity into incoming and
 		outgoing components. Less sensitive to noise.
 	\item \cite{kubota1990}: comparison between different wave theories:
 		quasi-nonlinear long-wave theory gave the best results.
 	\item \cite{walton1992}: application to beaches, possibility to have higher
 	reflected energy than incident energy.
 	\item \cite{hughes1993}: colocated horizontal and vertical velocities or
 	horizontal velocity and surface elevation. Validation for full reflection of
 	irregular non breaking waves.
 	\item \cite{huntley1999use}: principal component analysis technique to avoid
 	noise-induced bias.
 	\item \cite{sheremet2002observations}:
 \end{itemize}
--- a/biblio/main.tex
+++ b/biblio/main.tex
@ -1,4 +1,4 @@
-\documentclass[english, a4paper, 11pt]{report}
+\documentclass[english, a4paper, 11pt]{book}
 \usepackage{cours}
 \setmainlanguage{english}
@ -27,91 +27,17 @@ at the Artha breakwater on February 28, 2017}
 \date{February 2022}
 \begin{document}
 \frontmatter
 \maketitle
-\chapter*{Bibliography research}
+\tableofcontents
 \section{Extracting components from buoy data}
 \paragraph{incident and reflected wave separation}
 \cite{mansard1980measurement}: extract incident and reflected spectra from
 spectrum measurements at three different points.
 \cite{suh2001separation,frigaard1995time,baldock1999separation,
 roge2019estimation,andersen2017estimation}
-\paragraph{incident and reflected wave separation single gauge}
+\mainmatter
-\paragraph{incident and reflected wave separation puv method}
+\include{bibliography_research}
-Probablement très intéressant: \cite{inch2016accurate}:
+\include{introduction}
-\cite{sheremet2002observations,guza1977resonant}
+\include{literature}
 Très bien: \cite{huntley1999use,tatavarti1989incoming}
 \cite{pedersen2007resolving}
 \paragraph{puv method}
 \cite{sobey1999locally}
 \paragraph{artha breakwater reflection}
 \cite{poncet2020wave,larroque2018situ}
 \section{Reflection}
 \paragraph{wave reflection analysis}
 \cite{davidson1996new}
 \section{Modeling wave impact on porous media}
 \paragraph{olaFlow}
 \cite{olaFlow,higuera2015application}: \cite{bogdanov2011direct,del2011three}
 \section{Breakwater modeling}
 \paragraph{modelling breakwater} sph: \cite{altomare2014numerical};
 \paragraph{rubble-mound breakwater model} \cite{vanneste20152d,
 sumer2000experimental,kim2005neural,troch1999development,koley2020numerical,
 losada1979joint,lara2008wave,losada2008numerical}
 \paragraph{breakwater model} \cite{hsu2002}
 \section{Modeling}
 \paragraph{using wave buoy data in numerical models} \cite{thomas2015,
 mentaschi2013,rusu2011}
 \section{Block displacement}
 \paragraph{boulder transport by waves} \cite{erdmann2018boulder,may2015block,
 weiss2012mystery,weiss2015untangling,zainali2015boulder,zainali2016high}
 \paragraph{boulder transport flow} \cite{nandasena2011reassessment,
 nandasena2013boulder,martinez2011quasi,kennedy2016observations,lodhi2020role,
 oetjen2021experiments,oetjen2020significance}
 \paragraph{storm waves boulder interaction} \cite{nandasena2011numerical}
 Très intéressant: \cite{weiss2017toward},
 \cite{sheremet2002observations,sheremet2016triads}
 \paragraph{block transport by waves} \cite{imamura2008numerical,
 barbano2010large,PARIS20111,biolchi2016}
 \section{Flow in porous media}
 \paragraph{wave flow porous media} \cite{SHAO2010304}
 \chapter{Introduction}
 In February 2017, a \SI{50}{\tonne} concrete block was displaced by a wave onto
 the Artha breakwater in Saint-Jean-de-Luz. This event was captured by a
 photographer, and earlier work from \textcite{amir} allowed to extract the
 conditions under which this event happened using field data along with
 numerical modeling.
 The goal of the present study is to establish a numerical model representing
 the conditions under which this block displacement event happened at the scale
 of the breakwater. The simulation will be performed using the olaFlow
 \parencite{olaFlow} model in a three-dimensionnal setting.
 This study presents several aspects that are crucial to consider in order to
 obtain accurate results. The seastate that lead to the studied event is known
 thanks to a wave buoy located in front of the breakwater \parencite{amir}.
 However, in order to input an accurate incident wave into the numerical model,
 it will be necessary to extract the incident and reflected waves from the raw
 buoy data. Then, it will be necessary to accurately model the Artha breakwater,
 especially regarding its porous character. Finally, the results of this
 simulation will need to be compared to the literature on block displacement by
 waves for validation.
 \chapter{Literature Review}
 In this chapter, literature relevant to the present study will be reviewed.
 \section{Separating incident and reflected components from wave buoy data}
 \backmatter
 \nocite{*}
 \printbibliography
 \end{document}