Presentation is loading. Please wait.

Presentation is loading. Please wait.

Reflection+ Transmission Coefficients for 2-Layer Problem.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Reflection+ Transmission Coefficients for 2-Layer Problem."— Presentation transcript:

1 Reflection+ Transmission Coefficients for 2-Layer Problem

2 Outline 1.Two-Layer Problem: Reflection+Transmission Coefficients, Snell’s Law, Refractions, Critical angle, Post-critical Waves.

3 D = e i(k x - k z - wt) x z (2) U = R e i(k x + k z - wt) x z xz (2) increase x, z { - increase t { D = Te i(k x - k’ z - wt) x z k = w – k xz 222c k’ = w – k xz 222c’  c’ c  ’ 2-Layer Medium: Find R & T

4 (2) xz  c’ c  ’ 2-Layer Medium: Find R & T Te Te i(k x - k’ z - wt) x z P = - e i(k x - k z - wt) x z P = U + D = +e i(k x + k z - wt) x z + R Two unknowns R & T, need two equations of constraint

5 B.C. #1: Pressure Must Match at z=0 ik x Te Te x e ik x x e x + R = +- P = P @z=0 Te Te i(k x - wt) x e x e x + R = @z=0 Divide by e i( wt) Implies k = k xx sin O = sin O’ cc’ ik x x O O  c’ c  ’ Snell’s Law

6 Pressure must match at z=0 +- P = P @z=0 OO ik x Te Te x e ik x x e x + R = ik x x @z=0 + - w = w.... Recall w = -1 dP/dz .. ik x -ik Te -ik Te x -ik e ik x x e x + ik R = zzz @z=0 z=0  c’ c  ’ B.C. #2: Particle Accel. Must Match at z=0  Vertical acceleration matches @ z=0 so w+ = w- @ z=0

7 Pressure & accelration must match at z=0 OO ik x Te Te x e ik x x e x + R = ik x x @z=0 -ik Te -ik Te x -ik e ik x x e x + ik R = zzz @z=0 c’ cos O - c cos O c cos O + c’ cos O , ,  R =  c’ c  ’ c’ cos O c cos O + c’ cos O , , T = 2 

8 Special Cases: Bright Spots c’ cos O - c cos O c cos O + c’ cos O , ,  R = O = 0: c’ - c , R = c’ + c ,  Positive Refle. Coeff when Model is low over hi velocity Negative Refle. Coeff when Model is hi over low velocity BRIGHT SPOT Gas sand has lower impedance than wet sand. Works well in GOM and young sedimentary basins

9 Special Cases: Critical Angle c’ cos O - c cos O c cos O + c’ cos O , ,  R = O = critical angle: O O  c’ c  ’ sin O = sin O sin O = sin O’ c c’ 1 < c c’

10 Special Cases: Post Critical Reflections c’ cos O - c cos O c cos O + c’ cos O , ,  R = O = critical angle: O O  c’ c  ’ sin O = sin O sin O = sin O’ c c’ 1 < c c’

11 c’ cos O - c cos O c cos O + c’ cos O , ,  R = O = critical angle: O O  c’ c  ’ sin O = sin O sin O = sin O’ c c’ 1 < c c’ Special Cases: Post Critical Reflections

12 c’ cos O - c cos O c cos O + c’ cos O , ,  R = O = critical angle: O O  c’ c  ’ sin O = 1 c c’ 1 < c c’ Special Cases: Post Critical Reflections

13 c’ cos O - c cos O c cos O + c’ cos O , ,  R = O = post critical angle: O O  c’ c  ’ sin O > 1 c c’ 1 < c c’ Total Energy Reflection Post Critical Phase Shift Special Cases: Post Critical Reflections

14 Special Cases: Post Critical Reflection Coeff. c’ cos O - c cos O c cos O + c’ cos O , ,  R = sin = c’sinO O c = 1 – 2 c’sinO c’sinOc { { c > 1 - 1 2 c’sinO c’sinOc { { = i - 1 2 c’sinO c’sinOc { { = e i  /2 e Ocos = 1 – sin O 2 A B e i  /2

15 Special Cases: Post Critical Reflection Coeff. c’ cos O - c cos O , ,  R = c’ A - c e i  /2 ,  B c’ A + c e i  /2 ,  B Reflection coefficient is now a complex number U = R e i(k x + k z - wt) x z e i c’ cos O c cos O + - 1 2 c’sinO c’sinO c { { = e i  /2 B e cos O = cos O = A Phase change in upgoing post critical reflections Havoc AVO and stacking!

16 Layered Medium & Critical Angle 3 km/s 60 X (km) 60 0 3.5 Z (km) Time (s) 0 Post-critical reflection ray Post-critical reflections Sea floor 4.0 1.5 km/s CSGModel

17 Special Cases: Pressure+Marine Free Surface c’ cos O - c cos O c cos O + c’ cos O , ,  R = Free Surface  ’c’=0: R = - c cos O c cos O   = -1 P = 1 + R = 1 – 1 = 0 1 ghosts

18 c’ cos O + c cos O c cos O + c’ cos O , ,  R = Free Surface  ’c’=0: R = + c cos O c cos O   = 1 w = 1 + R = 1 + 1 = 2 1 +1 ghosts Special Cases: Part. Vel. + Land Free Surface Part.

19 Special Cases: Part. Vel. + Land Free Surface Why is particle velocity R opposite polarity to pressure R? ik x -ik Te -ik Te x -ik e ik x x e x + ik R = zzz @z=0 so w+ = w- @ z=0 Recall w = -1 dP/dz .. - D D - U R = zz z Downgoing particle-z velocity Down particle-z vel. Up particle-z vel. R =-R part.press.

20 Special Cases: Impedance P = e ik z z Recall w = -1 dP/dz .. ik z z ik z dP/dz = e where ik z = P dP/dz = P Therefore w ..ik z = - P dP/dz = - P But w = -i w w.... Therefore w  ik z = P dP/dz = P iwiwiwiw or P/w =  c.Impedance

21 Special Cases: Conservation of Energy Flow cccc Previously we found that the Energy Density in deforming a cube was given by P 2 2 Therefore the rate at which energy is flowing across a flat interface by a propagating plane wave is by P cccc 2 Energy/area/time = = c 2 P cccc 2 Conservation of energy demands energy flow of incident wave is same as the transmitted and reflected wave: cccc 21 = R + T cccc  c’ 22 ’ Note: > 1 + cccc  c’ 2 ’ ’

22 Special Cases P = sinO1/v1 = sinO2/v2=sinO3/v3=sinO4/v4 v1 v2 v3 v4 Slowness = inverse apparent Vx

23 Time v1 v2 v3 v4 Slope = v5 v5

24 D = e i(k x - k z - wt) x z (2) U = R e i(k x + k z - wt) x z xz D = Te i(k x + k’ z - wt) x z  c’ c  ’ 2-Layer Medium: Find R & T P = U + D + P = D -

25 Special Cases: Post Critical Reflection Coeff. Post-critical reflection ray

Download ppt "Reflection+ Transmission Coefficients for 2-Layer Problem."

Similar presentations

Plane wave reflection and transmission

Plane wave reflection and transmission
Wave Incidence at Oblique angles

Wave Incidence at Oblique angles
The Asymptotic Ray Theory

The Asymptotic Ray Theory
Chapter 1- General Properties of Waves Reflection Seismology Geol 4068

Chapter 1- General Properties of Waves Reflection Seismology Geol 4068
Snell’s Law.

Snell’s Law.
1 Complex math basics material from Advanced Engineering Mathematics by E Kreyszig and from Liu Y; Tian Y; “Succinct formulas for decomposition of complex.

1 Complex math basics material from Advanced Engineering Mathematics by E Kreyszig and from Liu Y; Tian Y; “Succinct formulas for decomposition of complex.
1 Metamaterials with Negative Parameters Advisor: Prof. Ruey-Beei Wu Student : Hung-Yi Chien 錢鴻億 2010 / 03 / 04.

1 Metamaterials with Negative Parameters Advisor: Prof. Ruey-Beei Wu Student : Hung-Yi Chien 錢鴻億 2010 / 03 / 04.
Electromagnetic (E-M) theory of waves at a dielectric interface

Electromagnetic (E-M) theory of waves at a dielectric interface
Identification of seismic phases

Identification of seismic phases
Reflection Coefficients For a downward travelling P wave, for the most general case: Where the first term on the RHS is the P-wave displacement component.

Reflection Coefficients For a downward travelling P wave, for the most general case: Where the first term on the RHS is the P-wave displacement component.
Lecture 12 Light: Reflection and Refraction Chapter 22.1  22.4 Outline History of Studies of Light Reflection of Light The Law of Refraction. Index of.

Lecture 12 Light: Reflection and Refraction Chapter 22.1  22.4 Outline History of Studies of Light Reflection of Light The Law of Refraction. Index of.
Reflection and refraction

Reflection and refraction
Chapter 23: Fresnel equations Chapter 23: Fresnel equations

Chapter 23: Fresnel equations Chapter 23: Fresnel equations
EEE340Lecture 391 For nonmagnetic media,  1 =  2 =  0 8-10.1: Total reflection When  1 >  2 (light travels from water to air)  t >  i If  t = 

EEE340Lecture 391 For nonmagnetic media,  1 =  2 =  : Total reflection When  1 >  2 (light travels from water to air)  t >  i If  t = 
Electro- magnetic waves in matter. Linear media: velocity: most materials:

Electro- magnetic waves in matter. Linear media: velocity: most materials:
Seismic waves Wave propagation Hooke’s law Newton’s law  wave equation Wavefronts and Rays Interfaces Reflection and Transmission coefficients.

Seismic waves Wave propagation Hooke’s law Newton’s law  wave equation Wavefronts and Rays Interfaces Reflection and Transmission coefficients.
Wave spreads over a larger surface as it travels through the medium. For a spherical wave, the wave energy falls off as the square of the distance. Its.

Wave spreads over a larger surface as it travels through the medium. For a spherical wave, the wave energy falls off as the square of the distance. Its.
Electromagnetic Wave Theory

Electromagnetic Wave Theory
EEE340Lecture 381 8-10: Oblique Incidence at a Plane Dielectric Boundary A plane wave propagating in where z x.

EEE340Lecture : Oblique Incidence at a Plane Dielectric Boundary A plane wave propagating in where z x.
Reflection and Refraction. Plane wave A plane wave can be written as follows: Here A represent the E or B fields, q=i,r,t and j=x,y,z So this is a representation.

Reflection and Refraction. Plane wave A plane wave can be written as follows: Here A represent the E or B fields, q=i,r,t and j=x,y,z So this is a representation.

Similar presentations

Ads by Google