Fortran 77 package CRT version 7.10
Prague, June 2014
- Vaclav Bucha
- Department of Geophysics, Charles University Prague,
Ke Karlovu 3, 121 16 Praha 2, Czech Republic
- Petr Bulant
- Department of Geophysics, Charles University Prague,
Ke Karlovu 3, 121 16 Praha 2, Czech Republic
- Vlastislav Cerveny
- Department of Geophysics, Charles University Prague,
Ke Karlovu 3, 121 16 Praha 2, Czech Republic
- Ludek Klimes
- Department of Geophysics, Charles University Prague,
Ke Karlovu 3, 121 16 Praha 2, Czech Republic
- Ivan Psencik
- Institute of Geophysics, Acad. Sci. Czech Rep.,
Bocni II 1401, 141 31 Praha 4, Czech Republic
This is just a general overview, the detailed description of input
data, procedures, and other important topics is included within the
individual FORTRAN77 source code files.
The code of the complete ray tracing subroutine package CRT is build
up on the basis of the model specification subroutine package MODEL.
Thus this general description of C.R.T. should be understood as a
continuation of the general description 'modeldoc.htm' of the seismic
model specification subroutines.
Copyright note
This software package is property of its authors,
is distributed in source form,
and may be used free of charge.
If any result obtained with help of any part of this package
is published, we appreciate citation
of all papers related to the used part of this package.
Refer to the references
related to this package.
General description
Programming language,
error messages, screen output, etc.
Unified memory management.
History files.
Alphabetical list of input parameters of all
programs.
New in version 7.10
Compiling and linking programs of package CRT
All Fortran 77 source code and include files are assumed
to be located in a single directory when being compiled and linked.
The files with main programs contain, at their ends, Fortran 90
INCLUDE command for all subroutine files required. In this
way, each program may simply be compiled and linked as a single file.
All filenames are assumed to be expressed in lowercase (since version
5.00) which should be more convenient than uppercase on Unix systems.
Fortran 77 source code files have extension '.for'. The corresponding
files with specifications of the COMMON blocks have extension '.inc'
and are included in the Fortran 77 source code by means of Fortran 90
INCLUDE command.
If linking 'crt.for' with a compiler's CalComp graphics library
(e.g., with Lahey's F77L3 'graph3.lib' on a PC) in order to enable
graphic screen output, do not forget to adjust the CalComp plotting
area in 'scro.for'.
Compilation and linking:
- Install package FORMS into your working directory
according to the description in
forms.htm.
- Install package MODEL into your working directory
according to the description in
model.htm.
- Copy all files (or at least all *.for, *.inc and
*.pl files) of package CRT into your working directory.
All the files may also be extracted using
pkunzip -d crt.zip or
tar -xvf crt.tar.
At http://sw3d.cz, *.zip contain ASCII files in the DOS format.
At http://sw3d.cz, *.tar contain ASCII files in the UNIX format.
On the UNIX disk, *.zip and *.tar contain ASCII files
in the UNIX format.
On the DOS disk, *.zip and *.tar contain ASCII files
in the DOS format.
- If you wish to compile programs
crtpts.for,
green.for and
mtt.for,
you need also subroutine indexx.for of the
Numerical Recipes
and the corresponding licence.
- Run Perl script fcrt.pl
by entering command
perl fcrt.pl
to compile and link the programs of package CRT.
For the list of files to compile and link, refer to
Perl script fcrt.pl,
which employs Perl script
f.pl
of package FORMS to compile each program.
All necessary subroutine files and include files are included
by the Fortran 90 INCLUDE command.
Fortran 77 subroutine files are included at the end of above
listed files containing main programs.
Running programs of package CRT
All Fortran 77 source code and include files together with all the
Perl scripts and data files of packages FORMS, MODEL and CRT are assumed
to be located in the same single working directory
in which the programs will be run.
It is recommended to run the programs from the
history files.
The history files may contain the information how to execute the
programs, the data read from standard input (Fortran)
or from the command line (Perl) and the data read
from the SEP parameter files.
Data from standard input *:
Main input data of each program are read from the standard input,
and consist of a single line, containing filenames and
at most few numerical parameters.
For the description of input data of individual programs refer to
the list of files below.
List of error messages
File list of package CRT
The Complete Ray Tracing consists of packages FORMS, MODEL and of the
following FORTRAN77 source code and demo files:
- (A) Documentation:
- crt.htm
-
This file (main HTML file containing basic description and links
to the files of this package).
- crtver.htm
-
List of the released versions.
- crterr.htm
-
List of error messages with the links to their descriptions.
- (B) Basic complete ray tracing program and subroutines:
-
These files together with the forward modelling model
specification routines of files 'model.for', 'metric.for',
'srfc.for', 'parm.for', 'val.for', 'fit.for'
form a consistent basic version of the complete ray
tracing program.
- crt.for
-
Main program CRT
for Complete Ray Tracing.
It reads the input data and then controls the complete ray tracing
of the specified elementary waves.
-
Input data are read in by the subroutine CRTIN of file
'crtin.for', called by main program CRT.
The input data
are described in file
crtin.for.
-
Outputs written into disk files are concentrated in
subroutine file writ.for.
-
Screen output is concentrated in subroutine file 'scro.for',
in subroutines SCRO1, SCRO2, SCRO3, SCRO4 and SCRO5.
Refer to file 'scro.for' for the
description of the screen
output, both textual and graphical.
Users are encouraged to customize the screen output by means of
preparing their own versions of 'scro.for'.
-
-
a) Textual screen output:
Textual screen output is available on all the systems. The number
of the source, the number of the wave, the number of the ray,
activity, ray parameters, history, and end of the ray may be
printed according to the user's selection of the
input parameters for
the textual screen output.
-
b) Graphical screen output:
All graphic outputs are concentrated in the subroutine file
'scro.for', in subroutines SCRO1, SCRO2, SCRO3, SCRO4 and SCRO5.
CalComp subroutines
PLOTS(0,0,0)
PLOT(XPAGE,YPAGE,IPEN)
NEWPEN(INP)
are called. Subroutine SYMBOL cannot be used because its
CalComp specification is not conformal with the FORTRAN77
standard. Subroutine NUMBER is not employed. If the
subroutines PLOTS, PLOT and NEWPEN are not present in the
computer, they must be substituted by user-defined or void
subroutines. The specification of their parameters can be found
in the subroutine file
scro.for.
It is also possible to use the CalComp to Xlib interface
calcompx.c,
or the CalComp to PostScript interface
calcops.for.
Edit INCLUDE commands
at the end of the 'crt.for' program to enable screen graphics,
and see also the input
parameters for the graphical screen output.
-
Reasons of the termination of the computation of a ray
are specified by the output parameter IEND of the subroutines
INIT2 and RAY2 and are listed in the subroutine files
ray.for
(reasons 10 to 75) and
init.for
(reasons 71 to 75).
-
List of the computed quantities is given in the package
ray.for.
-
- crtin.for
-
Subroutines designed to open the data files for
complete ray tracing and to read the input data sets CRT,
MODEL, DCRT and INIT. Called e.g. by the main program
'crt.for'.
- code.for
-
Subroutine file devoted to the codes for
elementary waves. Contains the general description of the
codes for elementary waves and subroutines designed to
read the input data for the codes of elementary waves and
to transform the used numerical code of the elementary
wave under consideration into instructions specifying the
behaviour of the wave at the initial points of rays and at
all points of incidence of the rays at interfaces (see
C.R.T.4).
- code.inc
-
Include file with COMMON block for 'code.for'.
- ray.for
-
Contains the subroutine designed to read the input data for complete
ray tracing and to store them in the memory (see
C.R.T.5.6),
the list of the quantities computed along rays (see
C.R.T.5.2),
and the subroutine designed to continue the complete ray tracing
of a ray from the given point (see
C.R.T.5.7).
- dcrt.inc
-
Include file with COMMON block with data controlling
ray tracing. The data are read by 'ray.for' and are used
by various ray tracing routines.
- raycb.for
-
Subroutines for complete ray tracing within one
complex block (see
C.R.T.5.8).
- raycb.inc
-
Include file with COMMON block for 'raycb.for'.
- trans.for
-
Subroutine transforming the computed quantities
across a curved interface (see
C.R.T.5.9),
and subroutine replacing the amplitudes by ones involving
the appropriate conversion coefficients (see
C.R.T.5.5.4).
- coef.for
-
Subroutines computing the reflection/transmission
coefficients (see
C.R.T.5.9.7).
- init.for
-
Subroutines designed to read the input data for the
initial surface, and to define the initial values of the
quantities for complete tracing of a ray with given
take-off parameters (see
C.R.T.6).
- initd.inc
-
Include file with COMMON blocks for 'init.for',
containing input data and related quantities.
- initc.inc
-
Include file with COMMON block for 'init.for'
and other routines, containing the quantities at the
initial point of the ray being currently traced.
- rpar.for
-
Subroutines controlling the take-off parameters of
the rays. A user may introduce his own procedure of
selection of the take-off parameters and his own two-point
ray tracing algorithm by means of a modification of this
subroutine file, or subsequently referred files 'rp2d.for'
and 'rp3d.for' controlling the shooting algorithms.
- rpard.inc
-
Include file with COMMON block for 'rpar.for',
containing input data and related quantities.
- rparc.inc
-
Include file with COMMON blocks for 'rpar.for' to
record the ray histories and other related quantities.
- rp2d.for
-
Subroutines controlling the one-parametric shooting
algorithm determining the normalized take-off parameter
of rays for 2-D two-point ray tracing.
- rp2d.inc
-
Include file with COMMON block for 'rp2d.for'.
- rp3d.for
-
Subroutines controlling the two-parametric shooting
algorithm determining the normalized take-off parameters
of rays for 3-D two-point ray tracing.
- rp3d.inc
-
Include file with COMMON block for 'rp3d.for'.
- rp3dnul.for
-
Void subroutines replacing 'rp3d.for' to save
RAM if only 2-D ray tracing is performed. Not very interesting.
- writ.for
-
Subroutines creating the output of complete ray tracing (see
C.R.T.5.5).
- writ.inc
-
Include file with COMMON blocks for 'writ.for'.
- scro.for
-
Subroutine file for the screen output of program 'crt.for'.
The screen output consists of a simple graphic output
and of writing the brief messages on the status of
the currently computed ray to the console. This output
controls the console by means of the ANSI escape sequences
supported by MS-DOS ANSI.SYS driver on IBM-compatible
personal computers, and by the '+' ASA carriage control
character in the first column to avoid line feed.
This console output is just an example,
the subroutines SCRO1, SCRO2, SCRO3, SCRO4 and
SCRO5 have to be modified by a user for the particular
computer system.
Graphic output is accomplished by means of invocation of
'CalComp' subroutines PLOTS, PLOT, and NEWPEN. They may
be already available on some computers for some FORTRAN77
compilers (e.g., PLOTS, PLOT, and NEWPEN are included in
the Lahey FORTRAN77 compilers for PC's). Otherwise,
'scro.for' may be linked with 'plotnul.for' to disable
plotting, or with user's own interface routines to his
particular graphic system (see files 'plotnul.for' and
'calcomp.for').
- scro.inc
-
Include file with COMMON block for 'scro.for'.
- apw.for
-
Subroutines to write the quantities at the points of rays
into unformatted output files.
- pointc.inc
-
Include file with COMMON block /POINTC/ to store
the quantities calculated at a point of a ray, used by
'apw.for' for writing to output files, by subroutine AP00 of
of file 'ap.for' for reading from input files, and by subroutines
of file 'ap.for' and other routines processing the results of the
'crt.for' program.
- (C) The following subroutine files may be used to modify the basic
version of the complete ray tracing program by means of
additional screen output routines:
- plotnul.for
-
Dummy version of the CalComp graphic
containing the plot subroutines called by the subroutines
of the package 'scro.for', see also the section
graphics of this guide.
- calcomp.cfg
-
Configuration file to the 'calcomp.for' routines,
disabling the interactive communication and other features
of 'calcomp.for' not required by the 'scro.for'
routines. The 'calcomp.cfg' configuration file is active
just if located in the current directory. Otherwise, the
'calcomp.for' routines run in an interactive way and may
create another 'calcomp.cfg' configuration file. Refer to
the FORMS package.
- calcompx.c
-
CalComp to Xlib interface containing the CalComp
plotting routines PLOTS, PLOT and NEWPEN. For
compilation and linking see
crtx.mak.
- crtx.mak
-
Makefile for compilation and linking CalComp
to Xlib interface
calcompx.c
-
containing the CalComp
plotting routines PLOTS, PLOT and NEWPEN.
- (D) Application routines and programs facilitating the processing
of the results of complete ray tracing:
-
When using the complete ray tracing program composed of
the subroutine files listed above, we determine and
store various quantities along the ray and at the points
of intersection of the ray with some selected surfaces.
The following sets of routines may be utilized when
processing the results of the complete ray tracing,
including a kinematic inversion:
- ap.for
-
Applications and processing of the results of complete
ray tracing. Subroutines designed to read from the files
the quantities describing the points of rays, and to
evaluate many other quantities used in seismology and
discussed in the chapter
C.R.T.7.
These subroutines may be included in user's application
programs following the complete ray tracing program.
Individual subroutines correspond to the individual sections
of the chapter
C.R.T.7,
and may call many subroutines of the above files composing
the complete ray tracing program.
- an.for
-
Subroutines to modify the output of subroutines of file 'ap.for'
in anisotropic media.
- apvar.for
-
Subroutines designed to evaluate the variations of
the travel time with respect to the model coefficients.
- rpplot.for
-
Program RPPLOT
plotting ray parameters using the output files
of program 'crt.for'.
-
Description of input data.
- rpplot.inc
-
Include file with COMMON block for 'rpplot.for'.
- rpsymb.for
-
Auxiliary subroutine for 'rpplot.for' to plot centred symbols.
- crtpfa.for
-
Program CRTPFA to calculate two
prevailing-frequency coupling-ray-theory S-wave Green tensors
along each input reference ray. The Green tensors are
continuous along the reference ray. The input reference ray
is then doubled. The first of the doubled rays is written with
the first Green tensor, the second of the doubled rays with
the second Green tensor. The program may be used to enable
interpolation of the prevailing-frequency coupling-ray-theory
S-wave Green tensors by program MTT.
-
Description of input data.
- crtpfa.inc
-
Include file with COMMON block for 'crtpfa.for'.
- pfatubes.for
-
Program PFATUBES to modify the file
'CRT-T' with indices of triangles in order to enable interpolation
within ray tubes formed by rays written by program CRTPFA.
-
Description of input data.
- pfatubes.inc
-
Include file with COMMON block for 'pfatubes.for'.
- crt2d3d.for
-
Program CRT2D3D
to transform 2-D system of rays to 3-D
system of rays to be processed by program MTT,
which previous versions worked only in 3-D.
-
Description of input data.
- mtt.for
-
Program MTT
to calculate Multivalued Travel Times on a 3-D grid of points
by means of bicubic interpolation within ray cells,
and to calculate other quantities on the 3-D grid of points
by means of bilinear interpolation within ray cells.
Program MTT uses the rays stored in the output files of program CRT.
-
Description of input data.
- mttq.for
-
Subroutine file to deal with the user-defined quantities
to be interpolated by program MTT.
A user is welcome to edit this file according to the instructions
provided. He may read his input parameters and
define new quantities in the points of the rays.
- mtt.inc
-
Include file with COMMON block for 'mtt.for'.
- mttwf.inc
-
Include file with COMMON block for 'mtt.for' and 'wfsrf.for'.
- wfsrf.for
-
Program WFSRF
using output files of program CRT
to generate wavefronts composed of polygons for display purposes.
-
Description of input data.
- wfsrf.inc
-
Include file with COMMON block for 'wfsrf.for'.
- mttgrd.for
-
Program MTTGRD
to convert multivalued travel times produced
by program MTT into several singlevalued grids
corresponding to individual ray histories.
-
Description of input data.
- crt2p.for
-
Program CRT2P
to single out two-point rays in the
unformatted output program CRT. Simple illustrative
example how to use 'ap.for'.
-
Description of input data.
- crtcart.for
-
Program CRTCART
to convert the rays calculated by program
CRT from curvilinear to Cartesian coordinates,
which are required by 'mtt.for'.
-
Description of input data.
- crtout.for
-
Subroutines to facilitate conversion of the
unformatted output of program CRT into formatted files.
- ttsort.for
-
Subroutine to sort the quantities according to the
receivers, and at each receiver according to the
increasing travel time.
- crtray.for
-
Program CRTRAY
converting the unformatted output of
program CRT into formatted files with rays suitable for plotting.
-
Description of input data.
- crtpts.for
-
Program CRTPTS
converting the unformatted output of
program CRT into formatted file with endpoints of rays.
-
Description of input data.
- crtlew.for
-
Program CRTLEW to calculate the directions
of the projections of the ray segments into the given 2-D section,
and to calculate the length of all ray segments according to the
given angular intervals. The output then may be used, e.g., as
weights for calculation of Lyapunov exponents.
-
Description of input data.
- green.for
-
Program GREEN
to convert the unformatted output of program CRT
into a formatted file containing the ray-theory elastodynamic
Green function.
-
Description of input data.
- wan.for
-
Subroutines to compute quantities along a ray necessary
for computation of the Green function by means of coupling
ray-theory in weakly anisotropic models without interfaces.
Subroutines to calculate second order perturbations.
Called by 'green.for'.
- wanpfa.for
-
Subroutines called by 'wan.for' and 'crtpfa.for'.
- watable.for
-
Program WATABLE
to calculate differences between travel times and their
approximations by the second order perturbations.
- greenss.for
-
Program GREENSS
to read a formatted file containing the
ray-theory elastodynamic Green function and to generate
ray-theory time-domain synthetic seismograms (without
attenuation) or frequency-domain response functions
(including causal Futterman's attenuation).
-
Description of input data.
- rm.for
-
Interface between program 'greenss.for' and package RMATRIX.
- rmnul.for
-
File containing void versions of two subroutines called by
program 'greenss.for'.
- invtt.for
-
Program INVTT
designed to evaluate the derivatives of
the travel time with respect to the model coefficients.
-
Description of input data.
- (E) Perl scripts:
- srpcrt.pl
-
Perl script to generate coordinates of the
source and receiver points for given configuration
parameters, perform two-point ray tracing, and convert
unformatted output into a simple formatted file.
It runs programs 'srp', 'crt' and 'crtpts'.
- fcrt.pl
-
Perl script to compile the CRT package by means of
predefined script 'f.pl' compiling and linking a single
Fortran 77 source code file.
- (F) Universal and demo data files:
- codep.dat
-
Data specifying only the refracted P wave.
- codep2.dat
-
Additional input data file for the CRT program,
specifying the codes of 3 elementary P waves (2 reflected).
- codes.dat
-
Data specifying only the refracted S wave.
- writ.dat
-
Additional input data file for the CRT program, with
names of the output files. Whole two-point rays are
stored in files corresponding to individual elementary
waves and the points of intersection with given surfaces
are stored in files corresponding to individual surfaces.
- writall.dat
-
Alternative data file specifying the names of the
output files. All whole rays are stored, not only two-point rays.
- writsrf.dat
-
Alternative data file specifying the names of the
output files. No whole rays are stored. The points of
intersection with given surfaces are stored in files
corresponding to individual surfaces.
- writnul.dat
-
Alternative data file specifying the names of the
output files. Nothing is written.
- source.dat
-
Sample main input data for the GREENSS program to
specify the point source (moment-tensor or single-force
seismic source).
- sourcex.dat
-
Data specifying the seismic moment tensor of an explosive source
(extracted from examples in 'source.dat').
Acknowledgements
The development of the complete ray tracing algorithm and the
related Fortran 77 packages has been partially supported by:
- Faculty of Mathematics and Physics, Charles University, Prague.
- Energy, Mines and Resources Canada, Ottawa, Ontario.
- Institute of Geotechnics, Czechoslovak Academy of Sciences, Prague.
- Geophysical Institute, Academy of Sciences of the Czech Republic.
- Grant Agency of the Academy of Sciences of the Czech Republic
under Contracts 31223 and 346110.
- Grant Agency of the Charles University under Contracts 8/94,
38/94, 237/2001, 229/2002 and 375/2004.
- Grant Agency of the Czech Republic under Contracts 205/95/1465,
205/01/0927, 205/01/D097, 205/04/1104, 205/07/0032
and P210/10/0736.
- Ministry of Education, Youth and Sports of the Czech Republic
within research project CzechGeo.
- European Commission within the framework of the JOULE II Project
"Integrated Structural Imaging of Seismic Data".
- Members of consortium "Seismic Waves in Complex 3-D Structures".