📄 traceray.m
字号:
function [t,p,L]=traceray(vp,zp,vs,zs,raycode,x,xcap,pfan,itermax,optflag,pflag,dflag,xnot)
% TRACERAY: traces an arbitrary ray given its raycode for v(z)
%
% [t,p,L]=traceray(vp,zp,vs,zs,raycode,x,xcap,pfan,itermax,optflag,pflag,dflag,xnot)
%
% TRACERAY uses the modified bisection algorithm
% to trace an arbitrary vector of rays through a stratified medium.
% The rays can have any number of reflections and mode conversions and any start
% and end point.
% vp,zp = velocity and depth vectors giving the p wave model. Depths are
% considered to be the tops of homogeneous layers.
% vs,zs = velocity and depth vectors giving the s wave model.
% for both models, depths are considered to be the tops of homogeneous layers. Thus,
% the first velocity applies from the first depth to the second. A constant velocity
% would be specified like vp=1500;zp=0; etc.
% raycode = n by 2 matrix specifying the ray where n is the number of "legs" on the
% raypath. The first column is a list of
% depths and the second is a list of the integers 1 or 2 indicating P
% or S. The ray is traced from depth raycode(1,1) to raycode(2,1) with
% the raytype indicated by raycode(1,2) and so on. The depths in raycode need
% not correspond to layer boundaries in the P and S velocity models. Note that the last
% entry in column two is meaningless.
% x = vector of desired source-receiver offsets (horizontal)
% MUST be non-negative numbers
% xcap = (scalar) capture radius
% pfan = vector of ray parameters to use for the initial fan of rays
% By default, the routine generates the fan using straight rays.
% Setting pfan to -1 or omitting it activates default behavior.
% Setting pfan to -2 causes the routine to use the pfan used in the
% last call to this program. (pfan of -1 and -2 are identical on the
% first call.)
% itermax = maximum number of iterations allowed for ray capture
% =========================== Default = 4 ================================
% optflag = if nonzero then refine captured rays by linear interpolation
% =========================== Default = 1 ================================
% pflag = if nonzero, then print information about all failed rays
% =========================== Default = 0 ================================
% dflag = 0 no action
% = 1 then a new figure window will be opened and the raypaths plotted
% = 2 raypaths will be plotted in the current window
% = -n e.g. a negative integer, the drawing will occur in the current
% axis of the figure number n.
% =========================== Default = 0 ================================
% xnot = starting x coordinate to draw rays from
% =========================== Default = 0 ================================
% NOTE: All z variables must be specified relative to a common datum
%
% t = vector of traveltimes for each x
% p = vector of ray parameters for each x
% L = vector of geometrical spreading factors for each x
% (if L is not asked for, it will not be calculated)
%
% G.F. Margrave, CREWES Project, June 1995
%
% NOTE: It is illegal for you to use this software for a purpose other
% than non-profit education or research UNLESS you are employed by a CREWES
% Project sponsor. By using this software, you are agreeing to the terms
% detailed in this software's Matlab source file.
% BEGIN TERMS OF USE LICENSE
%
% This SOFTWARE is maintained by the CREWES Project at the Department
% of Geology and Geophysics of the University of Calgary, Calgary,
% Alberta, Canada. The copyright and ownership is jointly held by
% its author (identified above) and the CREWES Project. The CREWES
% project may be contacted via email at: crewesinfo@crewes.org
%
% The term 'SOFTWARE' refers to the Matlab source code, translations to
% any other computer language, or object code
%
% Terms of use of this SOFTWARE
%
% 1) Use of this SOFTWARE by any for-profit commercial organization is
% expressly forbidden unless said organization is a CREWES Project
% Sponsor.
%
% 2) A CREWES Project sponsor may use this SOFTWARE under the terms of the
% CREWES Project Sponsorship agreement.
%
% 3) A student or employee of a non-profit educational institution may
% use this SOFTWARE subject to the following terms and conditions:
% - this SOFTWARE is for teaching or research purposes only.
% - this SOFTWARE may be distributed to other students or researchers
% provided that these license terms are included.
% - reselling the SOFTWARE, or including it or any portion of it, in any
% software that will be resold is expressly forbidden.
% - transfering the SOFTWARE in any form to a commercial firm or any
% other for-profit organization is expressly forbidden.
%
% END TERMS OF USE LICENSE
if(nargin<13)
xnot=0;
end
if(nargin<12)
dflag=0;
end
if(nargin<11)
pflag=0;
end
if(nargin<10)
optflag=1;
end
if(nargin<9)
itermax=4;
end
if( nargin<8)
pfan=-1;
end
if(~prod(double(size(vp)==size(zp))))
error('vp and zp must be the same size');
end
if(~prod(double(size(vs)==size(zs))))
error('vs and zs must be the same size');
end
if(length(xcap)~=1 )
error(' xcap must be scalar ')
end
%make sure zsrc < Zd and zr<zd
%if(zsrc > zd )
% error(' zsrc must be less than zd');
%end
%if(zr > zd )
% error(' zr must be less than zd');
%end
ind=find(x<0);
if(~isempty(ind))
error('offsets must be nonnegative');
end
if(size(raycode,2)~=2)
error('raycode must have two columns');
end
%unpack the raycode
zray=raycode(:,1);
raytype=raycode(:,2);
zsrc=zray(1);
zr=zray(end);
zd=max(zray);
%adjust zsrc,zr,and zd and z2 so that they won't be exactly on layer boundaries
% zsrc=zsrc+100000*eps;
% zr=zr+100000*eps;
% zd=zd-100000*eps;
%create one-way model
vmod=[];
zmod=[];
zmax=0;
vp=vp(:);vs=vs(:);
zp=zp(:);zs=zs(:);
vp=[vp;vp(end)];
zp=[zp;1000000];
zpthk=diff(zp);%thicknesses
vs=[vs;vs(end)];
zs=[zs;1000000];
zsthk=diff(zs);%thicknesses
for k=1:length(zray)-1
zr1=zray(k);
zr2=zray(k+1);
dir=sign(zr2-zr1);
incd=round((1+dir)/2);
incu=round((1-dir)/2);
if(raytype(k)==1)
ind1=surround(zp,zray(k));
ind2=surround(zp,zray(k+1));
vmod=[vmod;vp(ind1);vp(ind1+dir:dir:ind2)];
zmod=[zmod;zr1;zp(ind1+incd:dir:ind2+incu)];
else
ind1=surround(zs,zray(k));
ind2=surround(zs,zray(k+1));
vmod=[vmod;vs(ind1);vs(ind1+dir:dir:ind2)];
zmod=[zmod;zr1;zs(ind1+incd:dir:ind2+incu)];
end
end
zmod=[zmod;zr2];
zmod=[0;cumsum(abs(diff(zmod)))];
%zmod=[zmod;zmax];
% if( zsrc < zp(1) | zsrc < zs(1))
% error(' source depth outside model range');
%elseif(zr < zp(1) | zr < zs(1) )
% error('receiver depth outside model range');
% end
z1=zmod(1);%start depth
z2=zmod(end);%end depth
%determine pmax
vmax=max([vmod]);
nearlyone=.999;
pmax=nearlyone/vmax;
%the meaning of pmax is that it is the maximum ray parameter which will not
%be critically refracted anywhere in vp or vs.
if(pfan==-2)
global PFAN
if(isempty(PFAN))
pfan=-1;
else
pfan=PFAN;
PFAN=-2;
end
else
PFAN=0;
end
if(pfan==-1)
%shoot a fan of rays Iterate once if the fan does not span the xrange
%guess angle range
xmaxf=max(x);
xminf=min(x);
if(xminf~=xmaxf)
nrays=3*length(x);
xfan=linspace(xminf,xmaxf,nrays);
th=atan(xfan/(z2-z1));
%determine the fan ray parameters
pfan=sin(th)/vmod(1);
%put in a max and min p
if(min(pfan)>0)
pfan=[0 pfan];
xfan=[0 xfan];
nrays=nrays+1;
end
if(max(pfan)>pmax)
ind=find(pfan<pmax);
pfan=pfan(ind);
xfan=xfan(ind);
nrays=length(ind);
end
if(max(pfan)<pmax)
pfan=[pfan pmax];
xfan=[xfan (z2-z1)*nearlyone/sqrt(1-nearlyone*nearlyone)];
nrays=nrays+1;
end
xminf=2.0*min(xfan);
xmaxf=2.0*max(xfan);
else
%3 rays 1 x
th=atan(xmaxf/(z2-z1)); %straight ray to xmax
nrays=3;
po=sin(th)/vmod(1);
if(po>pmax)
po=pmax/2;
end
pfan=[0 po pmax];
th=asin(pfan*vmod(1));
xfan=(z2-z1)*tan(th);
xminf=2.0*min(xfan);
xmaxf=2.0*max(xfan);
end
else
%make sure its a row vector
ind=find(isnan(pfan));
if(~isempty(ind))
pfan(ind)=[];
end
pfan=pfan(:)';
pfan=sort(pfan);
ind=find(pfan==0);
if(isempty(ind))
pfan=[0 pfan];
end
ind=find(pfan>=pmax);
if(~isempty(ind))
pfan(ind)=[];
end
pfan=[pfan pmax];
nrays=length(pfan);
end
%shoot first fan
%
[xx,tt]=shootray(vmod,zmod,pfan);
xmax=max(xx);
xmin=min(xx);
%see if we have spanned the x range and revise if needed
imin=surround(xx,min(x));
imax=surround(xx,max(x));
newfan=0;
if(isempty(imax))
if(max(pfan)<pmax)
pm= .5*(max(pfan)+pmax);
pfan=[pfan pm];
imax=length(pfan)-1;
newfan=1;
end
end
if(~isempty(imax))
pfan=pfan(imin:imax+1);
end
%shoot new fan (if p changed)
if(length(pfan)~=nrays | newfan)
% first p
[xx,tt]=shootray(vmod,zmod,pfan);
% invoke symmetry to double these
xmax=max(xx);
xmin=min(xx);
end
%
% loop over x
% -1 find xx which brackets x(k)
% -2 shoot a finer fan of rays
% -3 find the rays which bracket x(k)
% -4 repeat 2 and 3 until a ray is captured at x(k)
%
t=inf*ones(size(x));
p=nan*ones(size(x));
for k=1:length(x)
ind=surround(xx,x(k));
if(isempty(ind))
if(x(k)>=xmax) %test for off high end
i1=length(xx);
i2=[];
else
i1=[]; %off low end
i2=1;
end
else
if(length(ind)>1) %use first arrival
it=find(tt(ind)==min(tt(ind)));
ind=ind(it);
end
i1=ind;
i2=ind+1;
end
captured=0;
hopeless=0;
iter=0;
x1=xx(i1); x2=xx(i2);
t1=tt(i1); t2=tt(i2);
p1=pfan(i1); p2=pfan(i2);
if( isempty(i2) & max(pfan)==pmax)
hopeless=1;
end
while(~captured & iter<itermax & ~hopeless)
iter=iter+1;
%test for capture
xtst1=abs(x(k)-x1);
xtst2=abs(x(k)-x2);
if( xtst1< xcap & xtst1<=xtst2)
captured=1;
p(k)=p1;
t(k)=t1;
%final adjustment
if(optflag)
%linear interpolation
t(k)= t1 + (x(k)-x1)*(t2-t1)/(x2-x1);
p(k)= p1 + (x(k)-x1)*(p2-p1)/(x2-x1);
end
%disp([' capture on iter= ' int2str(iter)])
elseif( xtst2 < xcap & xtst2<=xtst1)
captured=1;
p(k)=p2;
t(k)=t2;
%final adjustment
if(optflag)
%linear interpolation
t(k)= t2 + (x(k)-x2)*(t1-t2)/(x1-x2);
p(k)= p2 + (x(k)-x2)*(p1-p2)/(x1-x2);
end
%disp([' capture on iter= ' int2str(iter)])
end
%shoot a new fan
if(~captured)
%end cases first
if(isempty(i1))
p1=0;
elseif(isempty(i2))
p2=.5*(p2+pmax);
end
dp= (x(k)-x1)*(p2-p1)/(x2-x1);
p0= p1+ dp;
p2= min([p1+2*dp, pmax]);
p1= p1+.5*dp;
pnew=[p1 p0 p2];
if(isempty(pnew))
hopeless=1;
else
%shoot and check for nans
[xxnew,ttnew]=shootray(vmod,zmod,pnew);
xmx=max(xxnew);
xmn=min(xxnew);
%analyze the fan. see if we have bracketed our target
ind=surround(xxnew,x(k));
if(isempty(ind))
if(~isempty(xmx))
if(x(k)>=xmx)
n2=2*(x(k)-xxnew(2))/(xxnew(3)-xxnew(2));
p2=min([p1+n2*dp, pmax]);
pnew(3)=p2;
end
[xxnew,ttnew]=shootray(vmod,zmod,pnew);
xmx=max(xxnew);
xmn=min(xxnew);
ind=surround(xxnew,x(k));
if(isempty(ind));
i1=3;
i2=[];
else
i1=ind;
i2=ind+1;
end
else
i1=[];
i2=1;
end
else
if(length(ind)>1) %use first arrival
it=find(ttnew(ind)==min(ttnew(ind)));
ind=ind(it);
end
i1=ind;
i2=ind+1;
end
if( isempty(i2) & max(pnew)==pmax)
hopeless=1;
else
x1=xxnew(i1); x2=xxnew(i2);
t1=ttnew(i1); t2=ttnew(i2);
p1=pnew(i1); p2=pnew(i2);
end
end
end
end
%end the while loop
if(~captured & pflag)
disp([' capture failed for zsrc,zr,zd= ' num2str(zsrc) ',' num2str(zr) ...
',' num2str(zd) ' and x= ' num2str(x(k))]);
end
%end the for loop
end
if(PFAN)
PFAN=pfan;
end
if(dflag)
if(dflag==1)
figure;
end
if(dflag<0)
figure(abs(dflag));
end
xray=xnot;
for k=1:length(zray)-1
if(raytype(k)==1)
[hray,xray]=drawray(vp,zp,zray(k),zray(k+1),xray,p,'k');
else
[hray,xray]=drawray(vs,zs,zray(k),zray(k+1),xray,p,'r');
end
end
if(dflag==1)
flipy;xlabel('offset');ylabel('depth');
if(length(x)>1)
dx=x(2)-x(1);
else
dx=100;
end
axis([min([x(:);0])-dx max([x(:);0])+dx min(zp) max([max(zp(end-1));zsrc;zr;zd])])
end
end
if(nargout>2)
L=sphdiv(vmod,zmod,p);
end
⌨️ 快捷键说明
复制代码
Ctrl + C
搜索代码
Ctrl + F
全屏模式
F11
切换主题
Ctrl + Shift + D
显示快捷键
?
增大字号
Ctrl + =
减小字号
Ctrl + -