Presentation is loading. Please wait.

Presentation is loading. Please wait.

Session 2.1 : Theoretical results, numerical and physical simulations Introductory presentation Rogue Waves and wave focussing – speculations on theory,

Published byJocelin Morris Modified over 9 years ago

Similar presentations

Presentation on theme: "Session 2.1 : Theoretical results, numerical and physical simulations Introductory presentation Rogue Waves and wave focussing – speculations on theory,"— Presentation transcript:

1 Session 2.1 : Theoretical results, numerical and physical simulations Introductory presentation Rogue Waves and wave focussing – speculations on theory, numerical results and observations Paul H. Taylor University of Oxford ROGUE WAVES 2004 Workshop

2 Acknowledgements : My students : Erwin Vijfvinkel, Richard Gibbs, Dan Walker Prof. Chris Swan and his students : Tom Baldock, Thomas Johannessen, William Bateman

3 This is not a rogue (or freak) wave – it was entirely expected !!

4 This might be a freak wave Freak ?

5 NewWave - Average shape – the scaled auto-correlation function NewWave + bound harmonics NewWave + harmonics Draupner wave For linear crest amplitude 14.7m, Draupner wave is a 1 in ~200,000 wave

6 1- and 2- D modelling 1.Exact – Laplace + fully non-linear bcs – numerical spectral / boundary element / finite element 2.NLEEs NLS (Peregrine 1983) Dysthe 1979 Lo and Mei 1985 Dysthe, Trulsen, Krogstad & Socquet-Juglard 2003

7 Perturbative physics to various orders 1 st – Linear dispersion 2 nd – Bound harmonics + crest/trough,  set-down and return flow (triads in v. shallow water) 3 rd – 4-wave Stokes correction for regular waves, BF, NLS solitons etc. 4 th – (5-wave) crescent waves What is important in the field ? all of the time 1 st order RANDOM field most of the time 2 nd order occasionally 3 rd AND BREAKING

8 Frequency / wavenumber focussing Short waves ahead of long waves -overtaking to give focus event (on a linear basis) -spectral content -how long before focus -nonlinearity (steepness and wave depth) In examples – linear initial conditions on ( ,  ) same linear  (x) components at start time for several kd In all cases, non-linear group dynamics

9 1-D focussing on deep water – exact simulations

10 Shallow - no extra elevation Deeper - extra elevation for more compact group Ref. Katsardi + Swan

11 Shallow Deep Crest Trough Crest Wave kinematics – role of the return flow (2 nd order)

12 1-D Deepwater focussed wavegroup (kd  ) Gaussian spectrum (like peak of Jonswap) 1:1 linear focus Extra amplitude

13 Evolution of wavenumber spectrum with time

14 1-D Gaussian group– wavenumber spectra, showing relaxation to almost initial state

15 Wave group overtaking – non-linear dynamics on deep water

16 Numerics – discussed here Solves Laplace equation with fully non-linear boundary conditions Based on pseudo-spectral G-operator of Craig and Sulem (J Comp Phys 108, 73-83, 1993) 1-D code by Vijfvinkel 1996 Extended to directional spread seas by Bateman*, Swan and Taylor (J Comp Phys 174, 277-305, 2001) *Ph.D. from Dept. of Civil & Environmental Eng at Imperial College, London - supervised by C. Swan Well validated against high quality wave basin data – for both uni-directional and spread groups

17 Focussing of a directional spread wave group

18 2-D Gaussian group – fully nonlinear focus

19 Exact non-linear Linear (2+1) NLS Lo and Mei 1987 2-D dominant physics is x-contraction, y-expansion

20 Extra elevation ? Not in 2-D 1:1 linear focus

21 In directionally spread interactions – permanent energy transfers (4-wave resonance) – NLEE or Zakharov eqn 2-D is very different from 1-D

22 Directional spectral changes – for isolated NewWave-type focussed event Similar results in Bateman’s thesis and Dysthe et al. 2003 for random field

23 What about nonlinear Schrodinger equation i u T + u XX - u YY + ½ u c u 2 = 0 NLS-properties 1D x-long group  elevation  focussing - BRIGHT SOLITON 1D y-lateral group elevation  de-focussing - DARK SOLITON 2D group  vs. balance determines what happens to elevation focus in longitudinal AND de-focus in lateral directions

24 NLS modelling – conserved quantities (2-d version) useful for1. checking numerics 2. approx. analytics

25 Assume Gaussian group defined by A – amplitude of group at focus S X – bandwidth in mean wave direction (also S Y ) gives exact solution to linear part of NLS i u T + u XX - u YY = 0 (actually this is in Kinsman’s classic book)

26 Assume A, S X, S Y, and T/t are slowly varying 1-D x-direction FULLY DISPERSED FOCUS A - , S X - , T -   A F, S XF, T F =0 similarly 1-D y-direction 2-D (x,y)-directions

27 Approx. Gaussian evolution 1-D x-long : focussing and contraction A F /A -  =1 + 2 -5/2 (A -  / S X -  ) 2 + …. S XF /S x-  =1 + 2 -3/2 (A -  / S X -  ) 2 + …. 1-D y-lateral : de-focussing and expansion A F /A -  =1 - 2 -5/2 (A -  / S Y -  ) 2 + …. S YF /S Y-  =1 - 2 -3/2 (A -  / S Y -  ) 2 + ….

28 Simple NLS-scaling of fully non-linear results

29 Approx. Gaussian evolution 2-D (x,y) : assume S X-  = S Y-  = S -  A F /A -  =1 + + …. S XF /S -  =1 + 2 -3 (A -  / S -  ) ) 2 + …. S YF /S -  =1  2 -3 (A -  / S -  ) ) 2 + …. focussing in x-long, de-focussing in y-lat, no extra elevation much less non-linear event than 1-D (0.6  )

30 Importance of (A/S) – like Benjamin-Feir index 2-D qualitatively different to 1-D need 2-D Benjamin-Feir index, incl.directional spreading In 2-D little opportunity for extra elevation but changes in shape of wave group at focus and long-term permanent changes 2-D is much less non-linear than 1-D Conclusions based on NLS-type modelling

31 ‘Ghosts’ in a random sea – a warning from the NLS-equation u(x,t) = 2 1/2 Exp[2 I t] (1-4(1+4 I t)/(1+4x 2 +16t 2 )) t   uniform regular wave t =0 PEAK 3x regular background UNDETECTABLE BEFOREHAND (Osborne et al. 2000)

32 Where now ? Random simulations Laplace / Zakharov / NLEE Initial conditions – linear random ? How long – timescales ? BUT No energy input - wind No energy dissipation – breaking No vorticity – vertical shear, horiz. current eddies

33 BUT Energy input – wind Damping weakens BF sidebands (Segur 2004) and eventually wins  decaying regular wave Negative damping ~ energy input – drives BF and 4-wave interactions ?

34 Vertical shear Green-Naghdi fluid sheets (Chan + Swan 2004) higher crests before breaking Horizontal current eddies NLS-type models with surface current term (Peregrine)

35 Largest crest 2 nd largest crest Set-up NOT SET-DOWN Draupner wave – a rogue-like aspect – bound long waves

36 Conclusions We (I) don’t know how to make the Draupner wave Energy conserving models may not be the answer Freak waves might be ‘ghosts’

37

38

39

Download ppt "Session 2.1 : Theoretical results, numerical and physical simulations Introductory presentation Rogue Waves and wave focussing – speculations on theory,"

Similar presentations

P.W. Terry K.W. Smith University of Wisconsin-Madison Outline

P.W. Terry K.W. Smith University of Wisconsin-Madison Outline
Experimental tasks Spectra Extend to small scale; wavenumber dependence (Taylor hyp.); density, flow Verify existence of inertial range Determine if decorrelation.

Experimental tasks Spectra Extend to small scale; wavenumber dependence (Taylor hyp.); density, flow Verify existence of inertial range Determine if decorrelation.
Slide 1The Wave Model: 1.3. Energy Balance Eqn (Physics) 1.3. Energy Balance Eqn (Physics): Discuss wind input and nonlinear transfer in some detail. Dissipation.

Slide 1The Wave Model: 1.3. Energy Balance Eqn (Physics) 1.3. Energy Balance Eqn (Physics): Discuss wind input and nonlinear transfer in some detail. Dissipation.
INWAVE: THE INFRAGRAVITY WAVE DRIVER OF THE COAWST SYSTEM

INWAVE: THE INFRAGRAVITY WAVE DRIVER OF THE COAWST SYSTEM
1 1 Symposium Bjørn Gjevik 70 år Harald E. Krogstad, Department of Mathematical Sciences, NTNU, Trondheim and work in progress with Karsten Trulsen, Department.

1 1 Symposium Bjørn Gjevik 70 år Harald E. Krogstad, Department of Mathematical Sciences, NTNU, Trondheim and work in progress with Karsten Trulsen, Department.
Lecture III of VI (Claudio Piani) Rotation, vorticity, geostrophic adjustment, inertial oscillations, gravity waves with rotation.

Lecture III of VI (Claudio Piani) Rotation, vorticity, geostrophic adjustment, inertial oscillations, gravity waves with rotation.
A REVIEW OF WHISTLER TURBULENCE BY THREE- DIMENSIONAL PIC SIMULATIONS A REVIEW OF WHISTLER TURBULENCE BY THREE- DIMENSIONAL PIC SIMULATIONS S. Peter Gary,

A REVIEW OF WHISTLER TURBULENCE BY THREE- DIMENSIONAL PIC SIMULATIONS A REVIEW OF WHISTLER TURBULENCE BY THREE- DIMENSIONAL PIC SIMULATIONS S. Peter Gary,
Fatigue of Offshore Structures: Applications and Research Issues Steve Winterstein

Fatigue of Offshore Structures: Applications and Research Issues Steve Winterstein
The role of resonant wave interactions in the evolution of extreme wave events R. Gibson and C. Swan Imperial College London.

The role of resonant wave interactions in the evolution of extreme wave events R. Gibson and C. Swan Imperial College London.
Specialization in Ocean Energy MODELLING OF WAVE ENERGY CONVERSION António F.O. Falcão Instituto Superior Técnico, Universidade de Lisboa 2014.

Specialization in Ocean Energy MODELLING OF WAVE ENERGY CONVERSION António F.O. Falcão Instituto Superior Técnico, Universidade de Lisboa 2014.
Unified Wave Model for Progressive Waves in Finite Water Depth Shijun LIAO ( 廖世俊 ) State Key Lab of Ocean Engineering Shanghai Jiaotong University, China.

Unified Wave Model for Progressive Waves in Finite Water Depth Shijun LIAO ( 廖世俊 ) State Key Lab of Ocean Engineering Shanghai Jiaotong University, China.
Direct numerical simulation study of a turbulent stably stratified air flow above the wavy water surface. O. A. Druzhinin, Y. I. Troitskaya Institute of.

Direct numerical simulation study of a turbulent stably stratified air flow above the wavy water surface. O. A. Druzhinin, Y. I. Troitskaya Institute of.
Turbulence of Gravity Waves in Laboratory Experiments S Lukaschuk 1, P Denissenko 1, S Nazarenko 2 1 Fluid Dynamics Laboratory, University of Hull 2 Mathematics.

Turbulence of Gravity Waves in Laboratory Experiments S Lukaschuk 1, P Denissenko 1, S Nazarenko 2 1 Fluid Dynamics Laboratory, University of Hull 2 Mathematics.
The research on the interactions between short and long waves or waves and currents on a variable bottom has not been made much in the past. Most of the.

The research on the interactions between short and long waves or waves and currents on a variable bottom has not been made much in the past. Most of the.
Chapter 4 Wave-Wave Interactions in Irregular Waves Irregular waves are approximately simulated by many periodic wave trains (free or linear waves) of.

Chapter 4 Wave-Wave Interactions in Irregular Waves Irregular waves are approximately simulated by many periodic wave trains (free or linear waves) of.
Wave Modeling Local Wave Transformations Billy L. Edge & Margery Overton CVEN 695-02.

Wave Modeling Local Wave Transformations Billy L. Edge & Margery Overton CVEN
Relationship between Probability density and Spectrum An interconnection of the statistical properties of random wave field.

Relationship between Probability density and Spectrum An interconnection of the statistical properties of random wave field.
Rossby wave propagation. Propagation… Three basic concepts: Propagation in the vertical Propagation in the y-z plane Propagation in the x-y plan.

Rossby wave propagation. Propagation… Three basic concepts: Propagation in the vertical Propagation in the y-z plane Propagation in the x-y plan.
Chapter 3.1 Weakly Nonlinear Wave Theory for Periodic Waves (Stokes Expansion)  Introduction The solution for Stokes waves is valid in deep or intermediate.

Chapter 3.1 Weakly Nonlinear Wave Theory for Periodic Waves (Stokes Expansion)  Introduction The solution for Stokes waves is valid in deep or intermediate.
Relationship between Probability density and Spectrum An interconnection of the statistical properties of random wave field.

Relationship between Probability density and Spectrum An interconnection of the statistical properties of random wave field.

Similar presentations

Ads by Google