seismic_CPML_2D_isotropic_second_order.f90

!
! SEISMIC_CPML Version 1.1.1, November 2009.
!
! Copyright Universite de Pau et des Pays de l'Adour, CNRS and INRIA, France.
! Contributor: Dimitri Komatitsch, dimitri DOT komatitsch aT univ-pau DOT fr
!
! This software is a computer program whose purpose is to solve
! the two-dimensional isotropic elastic wave equation
! using a finite-difference method with Convolutional Perfectly Matched
! Layer (C-PML) conditions.
!
! This software is governed by the CeCILL license under French law and
! abiding by the rules of distribution of free software. You can use,
! modify and/or redistribute the software under the terms of the CeCILL
! license as circulated by CEA, CNRS and INRIA at the following URL
! "http://www.cecill.info".
!
! As a counterpart to the access to the source code and rights to copy,
! modify and redistribute granted by the license, users are provided only
! with a limited warranty and the software's author, the holder of the
! economic rights, and the successive licensors have only limited
! liability.
!
! In this respect, the user's attention is drawn to the risks associated
! with loading, using, modifying and/or developing or reproducing the
! software by the user in light of its specific status of free software,
! that may mean that it is complicated to manipulate, and that also
! therefore means that it is reserved for developers and experienced
! professionals having in-depth computer knowledge. Users are therefore
! encouraged to load and test the software's suitability as regards their
! requirements in conditions enabling the security of their systems and/or
! data to be ensured and, more generally, to use and operate it in the
! same conditions as regards security.
!
! The full text of the license is available at the end of this program
! and in file "LICENSE".

  program seismic_CPML_2D_iso_second

! 2D elastic finite-difference code in velocity and stress formulation
! with Convolutional-PML (C-PML) absorbing conditions for an isotropic medium

! Dimitri Komatitsch, University of Pau, France, April 2007.

! The second-order staggered-grid formulation of Madariaga (1976) and Virieux (1986) is used:
!
!            ^ y
!            |
!            |
!
!            +-------------------+
!            |                   |
!            |                   |
!            |                   |
!            |                   |
!            |        v_y        |
!   sigma_xy +---------+         |
!            |         |         |
!            |         |         |
!            |         |         |
!            |         |         |
!            |         |         |
!            +---------+---------+  ---> x
!           v_x    sigma_xx
!                  sigma_yy
!

! The C-PML implementation is based in part on formulas given in Roden and Gedney (2000).
! If you use this code for your own research, please cite some (or all) of these
! articles:
!
! @ARTICLE{MaKoEz08,
! author = {Roland Martin and Dimitri Komatitsch and Abdela\^aziz Ezziani},
! title = {An unsplit convolutional perfectly matched layer improved at grazing
! incidence for seismic wave equation in poroelastic media},
! journal = {Geophysics},
! year = {2008},
! volume = {73},
! pages = {T51-T61},
! number = {4},
! doi = {10.1190/1.2939484}}
!
! @ARTICLE{MaKo09,
! author = {Roland Martin and Dimitri Komatitsch},
! title = {An unsplit convolutional perfectly matched layer technique improved
! at grazing incidence for the viscoelastic wave equation},
! journal = {Geophysical Journal International},
! year = {2009},
! volume = {179},
! pages = {333-344},
! number = {1},
! doi = {10.1111/j.1365-246X.2009.04278.x}}
!
! @ARTICLE{MaKoGe08,
! author = {Roland Martin and Dimitri Komatitsch and Stephen D. Gedney},
! title = {A variational formulation of a stabilized unsplit convolutional perfectly
! matched layer for the isotropic or anisotropic seismic wave equation},
! journal = {Computer Modeling in Engineering and Sciences},
! year = {2008},
! volume = {37},
! pages = {274-304},
! number = {3}}
!
! @ARTICLE{KoMa07,
! author = {Dimitri Komatitsch and Roland Martin},
! title = {An unsplit convolutional {P}erfectly {M}atched {L}ayer improved
!          at grazing incidence for the seismic wave equation},
! journal = {Geophysics},
! year = {2007},
! volume = {72},
! number = {5},
! pages = {SM155-SM167},
! doi = {10.1190/1.2757586}}
!
! The original CPML technique for Maxwell's equations is described in:
!
! @ARTICLE{RoGe00,
! author = {J. A. Roden and S. D. Gedney},
! title = {Convolution {PML} ({CPML}): {A}n Efficient {FDTD} Implementation
!          of the {CFS}-{PML} for Arbitrary Media},
! journal = {Microwave and Optical Technology Letters},
! year = {2000},
! volume = {27},
! number = {5},
! pages = {334-339},
! doi = {10.1002/1098-2760(20001205)27:5<334::AID-MOP14>3.0.CO;2-A}}

!
! To display the 2D results as color images, use:
!
!   " display image*.gif " or " gimp image*.gif "
!
! or
!
!   " montage -geometry +0+3 -rotate 90 -tile 1x21 image*Vx*.gif allfiles_Vx.gif "
!   " montage -geometry +0+3 -rotate 90 -tile 1x21 image*Vy*.gif allfiles_Vy.gif "
!   then " display allfiles_Vx.gif " or " gimp allfiles_Vx.gif "
!   then " display allfiles_Vy.gif " or " gimp allfiles_Vy.gif "
!

! IMPORTANT : all our CPML codes work fine in single precision as well (which is significantly faster).
!             If you want you can thus force automatic conversion to single precision at compile time
!             or change all the declarations and constants in the code from double precision to single.

  implicit none

! total number of grid points in each direction of the grid
  integer, parameter :: NX = 101
  integer, parameter :: NY = 641

! size of a grid cell
  double precision, parameter :: DELTAX = 10.d0
  double precision, parameter :: DELTAY = DELTAX

! flags to add PML layers to the edges of the grid
  logical, parameter :: USE_PML_XMIN = .true.
  logical, parameter :: USE_PML_XMAX = .true.
  logical, parameter :: USE_PML_YMIN = .true.
  logical, parameter :: USE_PML_YMAX = .true.

! thickness of the PML layer in grid points
  integer, parameter :: NPOINTS_PML = 10

! P-velocity, S-velocity and density
  double precision, parameter :: cp = 3300.d0
  double precision, parameter :: cs = cp / 1.732d0
  double precision, parameter :: density = 2800.d0

! total number of time steps
  integer, parameter :: NSTEP = 2000

! time step in seconds
  double precision, parameter :: DELTAT = 2.d-3

! parameters for the source
  double precision, parameter :: f0 = 7.d0
  double precision, parameter :: t0 = 1.20d0 / f0
  double precision, parameter :: factor = 1.d7

! source
  integer, parameter :: ISOURCE = NX - 2*NPOINTS_PML - 1
  integer, parameter :: JSOURCE = 2 * NY / 3 + 1
  double precision, parameter :: xsource = (ISOURCE - 1) * DELTAX
  double precision, parameter :: ysource = (JSOURCE - 1) * DELTAY
! angle of source force clockwise with respect to vertical (Y) axis
  double precision, parameter :: ANGLE_FORCE = 135.d0

! receivers
  integer, parameter :: NREC = 2
  double precision, parameter :: xdeb = xsource - 100.d0   ! first receiver x in meters
  double precision, parameter :: ydeb = 2300.d0            ! first receiver y in meters
  double precision, parameter :: xfin = xsource            ! last receiver x in meters
  double precision, parameter :: yfin =  300.d0            ! last receiver y in meters

! display information on the screen from time to time
  integer, parameter :: IT_DISPLAY = 100

! value of PI
  double precision, parameter :: PI = 3.141592653589793238462643d0

! conversion from degrees to radians
  double precision, parameter :: DEGREES_TO_RADIANS = PI / 180.d0

! zero
  double precision, parameter :: ZERO = 0.d0

! large value for maximum
  double precision, parameter :: HUGEVAL = 1.d+30

! velocity threshold above which we consider that the code became unstable
  double precision, parameter :: STABILITY_THRESHOLD = 1.d+25

! main arrays
  double precision, dimension(NX,NY) :: vx,vy,sigmaxx,sigmayy,sigmaxy,lambda,mu,rho

! to interpolate material parameters at the right location in the staggered grid cell
  double precision lambda_half_x,mu_half_x,lambda_plus_two_mu_half_x,mu_half_y,rho_half_x_half_y

! for evolution of total energy in the medium
  double precision epsilon_xx,epsilon_yy,epsilon_xy
  double precision, dimension(NSTEP) :: total_energy_kinetic,total_energy_potential

! power to compute d0 profile
  double precision, parameter :: NPOWER = 2.d0

  double precision, parameter :: K_MAX_PML = 1.d0 ! from Gedney page 8.11
  double precision, parameter :: ALPHA_MAX_PML = 2.d0*PI*(f0/2.d0) ! from Festa and Vilotte

! arrays for the memory variables
! could declare these arrays in PML only to save a lot of memory, but proof of concept only here
  double precision, dimension(NX,NY) :: &
      memory_dvx_dx, &
      memory_dvx_dy, &
      memory_dvy_dx, &
      memory_dvy_dy, &
      memory_dsigmaxx_dx, &
      memory_dsigmayy_dy, &
      memory_dsigmaxy_dx, &
      memory_dsigmaxy_dy

  double precision :: &
      value_dvx_dx, &
      value_dvx_dy, &
      value_dvy_dx, &
      value_dvy_dy, &
      value_dsigmaxx_dx, &
      value_dsigmayy_dy, &
      value_dsigmaxy_dx, &
      value_dsigmaxy_dy

! 1D arrays for the damping profiles
  double precision, dimension(NX) :: d_x,K_x,alpha_x,a_x,b_x,d_x_half,K_x_half,alpha_x_half,a_x_half,b_x_half
  double precision, dimension(NY) :: d_y,K_y,alpha_y,a_y,b_y,d_y_half,K_y_half,alpha_y_half,a_y_half,b_y_half

  double precision :: thickness_PML_x,thickness_PML_y,xoriginleft,xoriginright,yoriginbottom,yorigintop
  double precision :: Rcoef,d0_x,d0_y,xval,yval,abscissa_in_PML,abscissa_normalized

! for the source
  double precision :: a,t,force_x,force_y,source_term

! for receivers
  double precision xspacerec,yspacerec,distval,dist
  integer, dimension(NREC) :: ix_rec,iy_rec
  double precision, dimension(NREC) :: xrec,yrec

! for seismograms
  double precision, dimension(NSTEP,NREC) :: sisvx,sisvy

  integer :: i,j,it,irec

  double precision :: Courant_number,velocnorm

!---
!--- program starts here
!---

  print *
  print *,'2D elastic finite-difference code in velocity and stress formulation with C-PML'
  print *

! display size of the model
  print *
  print *,'NX = ',NX
  print *,'NY = ',NY
  print *
  print *,'size of the model along X = ',(NX - 1) * DELTAX
  print *,'size of the model along Y = ',(NY - 1) * DELTAY
  print *
  print *,'Total number of grid points = ',NX * NY
  print *

!--- define profile of absorption in PML region

! thickness of the PML layer in meters
  thickness_PML_x = NPOINTS_PML * DELTAX
  thickness_PML_y = NPOINTS_PML * DELTAY

! reflection coefficient (INRIA report section 6.1) http://hal.inria.fr/docs/00/07/32/19/PDF/RR-3471.pdf
  Rcoef = 0.001d0

! check that NPOWER is okay
  if(NPOWER < 1) stop 'NPOWER must be greater than 1'

! compute d0 from INRIA report section 6.1 http://hal.inria.fr/docs/00/07/32/19/PDF/RR-3471.pdf
  d0_x = - (NPOWER + 1) * cp * log(Rcoef) / (2.d0 * thickness_PML_x)
  d0_y = - (NPOWER + 1) * cp * log(Rcoef) / (2.d0 * thickness_PML_y)

  print *,'d0_x = ',d0_x
  print *,'d0_y = ',d0_y
  print *

  d_x(:) = ZERO
  d_x_half(:) = ZERO
  K_x(:) = 1.d0
  K_x_half(:) = 1.d0
  alpha_x(:) = ZERO
  alpha_x_half(:) = ZERO
  a_x(:) = ZERO
  a_x_half(:) = ZERO

  d_y(:) = ZERO
  d_y_half(:) = ZERO
  K_y(:) = 1.d0
  K_y_half(:) = 1.d0
  alpha_y(:) = ZERO
  alpha_y_half(:) = ZERO
  a_y(:) = ZERO
  a_y_half(:) = ZERO

! damping in the X direction

! origin of the PML layer (position of right edge minus thickness, in meters)
  xoriginleft = thickness_PML_x
  xoriginright = (NX-1)*DELTAX - thickness_PML_x

  do i = 1,NX

! abscissa of current grid point along the damping profile
    xval = DELTAX * dble(i-1)

!---------- left edge
    if(USE_PML_XMIN) then

! define damping profile at the grid points
      abscissa_in_PML = xoriginleft - xval
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_x
        d_x(i) = d0_x * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_x(i) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_x(i) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

! define damping profile at half the grid points
      abscissa_in_PML = xoriginleft - (xval + DELTAX/2.d0)
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_x
        d_x_half(i) = d0_x * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_x_half(i) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_x_half(i) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

    endif

!---------- right edge
    if(USE_PML_XMAX) then

! define damping profile at the grid points
      abscissa_in_PML = xval - xoriginright
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_x
        d_x(i) = d0_x * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_x(i) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_x(i) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

! define damping profile at half the grid points
      abscissa_in_PML = xval + DELTAX/2.d0 - xoriginright
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_x
        d_x_half(i) = d0_x * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_x_half(i) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_x_half(i) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

    endif

! just in case, for -5 at the end
    if(alpha_x(i) < ZERO) alpha_x(i) = ZERO
    if(alpha_x_half(i) < ZERO) alpha_x_half(i) = ZERO

    b_x(i) = exp(- (d_x(i) / K_x(i) + alpha_x(i)) * DELTAT)
    b_x_half(i) = exp(- (d_x_half(i) / K_x_half(i) + alpha_x_half(i)) * DELTAT)

! this to avoid division by zero outside the PML
    if(abs(d_x(i)) > 1.d-6) a_x(i) = d_x(i) * (b_x(i) - 1.d0) / (K_x(i) * (d_x(i) + K_x(i) * alpha_x(i)))
    if(abs(d_x_half(i)) > 1.d-6) a_x_half(i) = d_x_half(i) * &
      (b_x_half(i) - 1.d0) / (K_x_half(i) * (d_x_half(i) + K_x_half(i) * alpha_x_half(i)))

  enddo

! damping in the Y direction

! origin of the PML layer (position of right edge minus thickness, in meters)
  yoriginbottom = thickness_PML_y
  yorigintop = (NY-1)*DELTAY - thickness_PML_y

  do j = 1,NY

! abscissa of current grid point along the damping profile
    yval = DELTAY * dble(j-1)

!---------- bottom edge
    if(USE_PML_YMIN) then

! define damping profile at the grid points
      abscissa_in_PML = yoriginbottom - yval
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_y
        d_y(j) = d0_y * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_y(j) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_y(j) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

! define damping profile at half the grid points
      abscissa_in_PML = yoriginbottom - (yval + DELTAY/2.d0)
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_y
        d_y_half(j) = d0_y * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_y_half(j) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_y_half(j) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

    endif

!---------- top edge
    if(USE_PML_YMAX) then

! define damping profile at the grid points
      abscissa_in_PML = yval - yorigintop
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_y
        d_y(j) = d0_y * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_y(j) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_y(j) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

! define damping profile at half the grid points
      abscissa_in_PML = yval + DELTAY/2.d0 - yorigintop
      if(abscissa_in_PML >= ZERO) then
        abscissa_normalized = abscissa_in_PML / thickness_PML_y
        d_y_half(j) = d0_y * abscissa_normalized**NPOWER
! this taken from Gedney page 8.2
        K_y_half(j) = 1.d0 + (K_MAX_PML - 1.d0) * abscissa_normalized**NPOWER
        alpha_y_half(j) = ALPHA_MAX_PML * (1.d0 - abscissa_normalized) + 0.1d0 * ALPHA_MAX_PML
      endif

    endif

    b_y(j) = exp(- (d_y(j) / K_y(j) + alpha_y(j)) * DELTAT)
    b_y_half(j) = exp(- (d_y_half(j) / K_y_half(j) + alpha_y_half(j)) * DELTAT)

! this to avoid division by zero outside the PML
    if(abs(d_y(j)) > 1.d-6) a_y(j) = d_y(j) * (b_y(j) - 1.d0) / (K_y(j) * (d_y(j) + K_y(j) * alpha_y(j)))
    if(abs(d_y_half(j)) > 1.d-6) a_y_half(j) = d_y_half(j) * &
      (b_y_half(j) - 1.d0) / (K_y_half(j) * (d_y_half(j) + K_y_half(j) * alpha_y_half(j)))

  enddo

! compute the Lame parameters and density
  do j = 1,NY
    do i = 1,NX
        rho(i,j) = density
        mu(i,j) = density*cs*cs
        lambda(i,j) = density*(cp*cp - 2.d0*cs*cs)
    enddo
  enddo

! print position of the source
  print *,'Position of the source:'
  print *
  print *,'x = ',xsource
  print *,'y = ',ysource
  print *

! define location of receivers
  print *,'There are ',nrec,' receivers'
  print *
  xspacerec = (xfin-xdeb) / dble(NREC-1)
  yspacerec = (yfin-ydeb) / dble(NREC-1)
  do irec=1,nrec
    xrec(irec) = xdeb + dble(irec-1)*xspacerec
    yrec(irec) = ydeb + dble(irec-1)*yspacerec
  enddo

! find closest grid point for each receiver
  do irec=1,nrec
    dist = HUGEVAL
    do j = 1,NY
    do i = 1,NX
      distval = sqrt((DELTAX*dble(i-1) - xrec(irec))**2 + (DELTAY*dble(j-1) - yrec(irec))**2)
      if(distval < dist) then
        dist = distval
        ix_rec(irec) = i
        iy_rec(irec) = j
      endif
    enddo
    enddo
    print *,'receiver ',irec,' x_target,y_target = ',xrec(irec),yrec(irec)
    print *,'closest grid point found at distance ',dist,' in i,j = ',ix_rec(irec),iy_rec(irec)
    print *
  enddo

! check the Courant stability condition for the explicit time scheme
! R. Courant et K. O. Friedrichs et H. Lewy (1928)
  Courant_number = cp * DELTAT * sqrt(1.d0/DELTAX**2 + 1.d0/DELTAY**2)
  print *,'Courant number is ',Courant_number
  print *
  if(Courant_number > 1.d0) stop 'time step is too large, simulation will be unstable'

! suppress old files (can be commented out if "call system" is missing in your compiler)
! call system('rm -f Vx_*.dat Vy_*.dat image*.pnm image*.gif')

! initialize arrays
  vx(:,:) = ZERO
  vy(:,:) = ZERO
  sigmaxx(:,:) = ZERO
  sigmayy(:,:) = ZERO
  sigmaxy(:,:) = ZERO

! PML
  memory_dvx_dx(:,:) = ZERO
  memory_dvx_dy(:,:) = ZERO
  memory_dvy_dx(:,:) = ZERO
  memory_dvy_dy(:,:) = ZERO
  memory_dsigmaxx_dx(:,:) = ZERO
  memory_dsigmayy_dy(:,:) = ZERO
  memory_dsigmaxy_dx(:,:) = ZERO
  memory_dsigmaxy_dy(:,:) = ZERO

! initialize seismograms
  sisvx(:,:) = ZERO
  sisvy(:,:) = ZERO

! initialize total energy
  total_energy_kinetic(:) = ZERO
  total_energy_potential(:) = ZERO

!---
!---  beginning of time loop
!---

  do it = 1,NSTEP

!------------------------------------------------------------
! compute stress sigma and update memory variables for C-PML
!------------------------------------------------------------

  do j = 2,NY
    do i = 1,NX-1

! interpolate material parameters at the right location in the staggered grid cell
      lambda_half_x = 0.5d0 * (lambda(i+1,j) + lambda(i,j))
      mu_half_x = 0.5d0 * (mu(i+1,j) + mu(i,j))
      lambda_plus_two_mu_half_x = lambda_half_x + 2.d0 * mu_half_x

      value_dvx_dx = (vx(i+1,j) - vx(i,j)) / DELTAX
      value_dvy_dy = (vy(i,j) - vy(i,j-1)) / DELTAY

      memory_dvx_dx(i,j) = b_x_half(i) * memory_dvx_dx(i,j) + a_x_half(i) * value_dvx_dx
      memory_dvy_dy(i,j) = b_y(j) * memory_dvy_dy(i,j) + a_y(j) * value_dvy_dy

      value_dvx_dx = value_dvx_dx / K_x_half(i) + memory_dvx_dx(i,j)
      value_dvy_dy = value_dvy_dy / K_y(j) + memory_dvy_dy(i,j)

      sigmaxx(i,j) = sigmaxx(i,j) + &
         (lambda_plus_two_mu_half_x * value_dvx_dx + lambda_half_x * value_dvy_dy) * DELTAT

      sigmayy(i,j) = sigmayy(i,j) + &
         (lambda_half_x * value_dvx_dx + lambda_plus_two_mu_half_x * value_dvy_dy) * DELTAT

    enddo
  enddo

  do j = 1,NY-1
    do i = 2,NX

! interpolate material parameters at the right location in the staggered grid cell
      mu_half_y = 0.5d0 * (mu(i,j+1) + mu(i,j))

      value_dvy_dx = (vy(i,j) - vy(i-1,j)) / DELTAX
      value_dvx_dy = (vx(i,j+1) - vx(i,j)) / DELTAY

      memory_dvy_dx(i,j) = b_x(i) * memory_dvy_dx(i,j) + a_x(i) * value_dvy_dx
      memory_dvx_dy(i,j) = b_y_half(j) * memory_dvx_dy(i,j) + a_y_half(j) * value_dvx_dy

      value_dvy_dx = value_dvy_dx / K_x(i) + memory_dvy_dx(i,j)
      value_dvx_dy = value_dvx_dy / K_y_half(j) + memory_dvx_dy(i,j)

      sigmaxy(i,j) = sigmaxy(i,j) + mu_half_y * (value_dvy_dx + value_dvx_dy) * DELTAT

    enddo
  enddo

!--------------------------------------------------------
! compute velocity and update memory variables for C-PML
!--------------------------------------------------------

  do j = 2,NY
    do i = 2,NX

      value_dsigmaxx_dx = (sigmaxx(i,j) - sigmaxx(i-1,j)) / DELTAX
      value_dsigmaxy_dy = (sigmaxy(i,j) - sigmaxy(i,j-1)) / DELTAY

      memory_dsigmaxx_dx(i,j) = b_x(i) * memory_dsigmaxx_dx(i,j) + a_x(i) * value_dsigmaxx_dx
      memory_dsigmaxy_dy(i,j) = b_y(j) * memory_dsigmaxy_dy(i,j) + a_y(j) * value_dsigmaxy_dy

      value_dsigmaxx_dx = value_dsigmaxx_dx / K_x(i) + memory_dsigmaxx_dx(i,j)
      value_dsigmaxy_dy = value_dsigmaxy_dy / K_y(j) + memory_dsigmaxy_dy(i,j)

      vx(i,j) = vx(i,j) + (value_dsigmaxx_dx + value_dsigmaxy_dy) * DELTAT / rho(i,j)

    enddo
  enddo

  do j = 1,NY-1
    do i = 1,NX-1

! interpolate density at the right location in the staggered grid cell
      rho_half_x_half_y = 0.25d0 * (rho(i,j) + rho(i+1,j) + rho(i+1,j+1) + rho(i,j+1))

      value_dsigmaxy_dx = (sigmaxy(i+1,j) - sigmaxy(i,j)) / DELTAX
      value_dsigmayy_dy = (sigmayy(i,j+1) - sigmayy(i,j)) / DELTAY

      memory_dsigmaxy_dx(i,j) = b_x_half(i) * memory_dsigmaxy_dx(i,j) + a_x_half(i) * value_dsigmaxy_dx
      memory_dsigmayy_dy(i,j) = b_y_half(j) * memory_dsigmayy_dy(i,j) + a_y_half(j) * value_dsigmayy_dy

      value_dsigmaxy_dx = value_dsigmaxy_dx / K_x_half(i) + memory_dsigmaxy_dx(i,j)
      value_dsigmayy_dy = value_dsigmayy_dy / K_y_half(j) + memory_dsigmayy_dy(i,j)

      vy(i,j) = vy(i,j) + (value_dsigmaxy_dx + value_dsigmayy_dy) * DELTAT / rho_half_x_half_y

    enddo
  enddo

! add the source (force vector located at a given grid point)
  a = pi*pi*f0*f0
  t = dble(it-1)*DELTAT

! Gaussian
! source_term = factor * exp(-a*(t-t0)**2)

! first derivative of a Gaussian
  source_term = - factor * 2.d0*a*(t-t0)*exp(-a*(t-t0)**2)

! Ricker source time function (second derivative of a Gaussian)
! source_term = factor * (1.d0 - 2.d0*a*(t-t0)**2)*exp(-a*(t-t0)**2)

  force_x = sin(ANGLE_FORCE * DEGREES_TO_RADIANS) * source_term
  force_y = cos(ANGLE_FORCE * DEGREES_TO_RADIANS) * source_term

! define location of the source
  i = ISOURCE
  j = JSOURCE

! interpolate density at the right location in the staggered grid cell
  rho_half_x_half_y = 0.25d0 * (rho(i,j) + rho(i+1,j) + rho(i+1,j+1) + rho(i,j+1))

  vx(i,j) = vx(i,j) + force_x * DELTAT / rho(i,j)
  vy(i,j) = vy(i,j) + force_y * DELTAT / rho_half_x_half_y

! Dirichlet conditions (rigid boundaries) on the edges or at the bottom of the PML layers
  vx(1,:) = ZERO
  vx(NX,:) = ZERO

  vx(:,1) = ZERO
  vx(:,NY) = ZERO

  vy(1,:) = ZERO
  vy(NX,:) = ZERO

  vy(:,1) = ZERO
  vy(:,NY) = ZERO

! store seismograms
  do irec = 1,NREC
    sisvx(it,irec) = vx(ix_rec(irec),iy_rec(irec))
    sisvy(it,irec) = vy(ix_rec(irec),iy_rec(irec))
  enddo

! compute total energy in the medium (without the PML layers)

! compute kinetic energy first, defined as 1/2 rho ||v||^2
! in principle we should use rho_half_x_half_y instead of rho for vy
! in order to interpolate density at the right location in the staggered grid cell
! but in a homogeneous medium we can safely ignore it
  total_energy_kinetic(it) = 0.5d0 * sum( &
      rho(NPOINTS_PML+1:NX-NPOINTS_PML,NPOINTS_PML+1:NY-NPOINTS_PML)*( &
       vx(NPOINTS_PML+1:NX-NPOINTS_PML,NPOINTS_PML+1:NY-NPOINTS_PML)**2 +  &
       vy(NPOINTS_PML+1:NX-NPOINTS_PML,NPOINTS_PML+1:NY-NPOINTS_PML)**2))

! add potential energy, defined as 1/2 epsilon_ij sigma_ij
! in principle we should interpolate the medium parameters at the right location
! in the staggered grid cell but in a homogeneous medium we can safely ignore it
  total_energy_potential(it) = ZERO
  do j = NPOINTS_PML+1, NY-NPOINTS_PML
    do i = NPOINTS_PML+1, NX-NPOINTS_PML
      epsilon_xx = ((lambda(i,j) + 2.d0*mu(i,j)) * sigmaxx(i,j) - lambda(i,j) * &
        sigmayy(i,j)) / (4.d0 * mu(i,j) * (lambda(i,j) + mu(i,j)))
      epsilon_yy = ((lambda(i,j) + 2.d0*mu(i,j)) * sigmayy(i,j) - lambda(i,j) * &
        sigmaxx(i,j)) / (4.d0 * mu(i,j) * (lambda(i,j) + mu(i,j)))
      epsilon_xy = sigmaxy(i,j) / (2.d0 * mu(i,j))
      total_energy_potential(it) = total_energy_potential(it) + &
        0.5d0 * (epsilon_xx * sigmaxx(i,j) + epsilon_yy * sigmayy(i,j) + 2.d0 * epsilon_xy * sigmaxy(i,j))
    enddo
  enddo

! output information
  if(mod(it,IT_DISPLAY) == 0 .or. it == 5) then

! print maximum of norm of velocity
    velocnorm = maxval(sqrt(vx**2 + vy**2))
    print *,'Time step # ',it,' out of ',NSTEP
    print *,'Time: ',sngl((it-1)*DELTAT),' seconds'
    print *,'Max norm velocity vector V (m/s) = ',velocnorm
    print *,'total energy = ',total_energy_kinetic(it) + total_energy_potential(it)
    print *
! check stability of the code, exit if unstable
    if(velocnorm > STABILITY_THRESHOLD) stop 'code became unstable and blew up'

    call create_color_image(vx,NX,NY,it,ISOURCE,JSOURCE,ix_rec,iy_rec,nrec, &
                         NPOINTS_PML,USE_PML_XMIN,USE_PML_XMAX,USE_PML_YMIN,USE_PML_YMAX,1)
    call create_color_image(vy,NX,NY,it,ISOURCE,JSOURCE,ix_rec,iy_rec,nrec, &
                         NPOINTS_PML,USE_PML_XMIN,USE_PML_XMAX,USE_PML_YMIN,USE_PML_YMAX,2)

  endif

  enddo   ! end of time loop

! save seismograms
  call write_seismograms(sisvx,sisvy,NSTEP,NREC,DELTAT)

! save total energy
  open(unit=20,file='energy.dat',status='unknown')
  do it = 1,NSTEP
    write(20,*) sngl(dble(it-1)*DELTAT),sngl(total_energy_kinetic(it)), &
       sngl(total_energy_potential(it)),sngl(total_energy_kinetic(it) + total_energy_potential(it))
  enddo
  close(20)

! create script for Gnuplot for total energy
  open(unit=20,file='plot_energy',status='unknown')
  write(20,*) '# set term x11'
  write(20,*) 'set term postscript landscape monochrome dashed "Helvetica" 22'
  write(20,*)
  write(20,*) 'set xlabel "Time (s)"'
  write(20,*) 'set ylabel "Total energy"'
  write(20,*)
  write(20,*) 'set output "cpml_total_energy_semilog.eps"'
  write(20,*) 'set logscale y'
  write(20,*) 'plot "energy.dat" us 1:2 t ''Ec'' w l lc 1, "energy.dat" us 1:3 &
              & t ''Ep'' w l lc 3, "energy.dat" us 1:4 t ''Total energy'' w l lc 4'
  write(20,*) 'pause -1 "Hit any key..."'
  write(20,*)
  close(20)

  open(unit=20,file='plot_comparison',status='unknown')
  write(20,*) '# set term x11'
  write(20,*) 'set term postscript landscape monochrome dashed "Helvetica" 22'
  write(20,*)
  write(20,*) 'set xlabel "Time (s)"'
  write(20,*) 'set ylabel "Total energy"'
  write(20,*)
  write(20,*) 'set output "compare_total_energy_semilog.eps"'
  write(20,*) 'set logscale y'
  write(20,*) 'plot "energy.dat" us 1:4 t ''Total energy CPML'' w l lc 1, &
              & "../collino/energy.dat" us 1:4 t ''Total energy Collino'' w l lc 2'
  write(20,*) 'pause -1 "Hit any key..."'
  write(20,*)
  close(20)

! create script for Gnuplot
  open(unit=20,file='plotgnu',status='unknown')
  write(20,*) 'set term x11'
  write(20,*) '# set term postscript landscape monochrome dashed "Helvetica" 22'
  write(20,*)
  write(20,*) 'set xlabel "Time (s)"'
  write(20,*) 'set ylabel "Amplitude (m / s)"'
  write(20,*)

  write(20,*) 'set output "v_sigma_Vx_receiver_001.eps"'
  write(20,*) 'plot "Vx_file_001.dat" t ''Vx C-PML'' w l lc 1'
  write(20,*) 'pause -1 "Hit any key..."'
  write(20,*)

  write(20,*) 'set output "v_sigma_Vy_receiver_001.eps"'
  write(20,*) 'plot "Vy_file_001.dat" t ''Vy C-PML'' w l lc 1'
  write(20,*) 'pause -1 "Hit any key..."'
  write(20,*)

  write(20,*) 'set output "v_sigma_Vx_receiver_002.eps"'
  write(20,*) 'plot "Vx_file_002.dat" t ''Vx C-PML'' w l lc 1'
  write(20,*) 'pause -1 "Hit any key..."'
  write(20,*)

  write(20,*) 'set output "v_sigma_Vy_receiver_002.eps"'
  write(20,*) 'plot "Vy_file_002.dat" t ''Vy C-PML'' w l lc 1'
  write(20,*) 'pause -1 "Hit any key..."'
  write(20,*)

  close(20)

  print *
  print *,'End of the simulation'
  print *

  end program seismic_CPML_2D_iso_second

!----
!----  save the seismograms in ASCII text format
!----

  subroutine write_seismograms(sisvx,sisvy,nt,nrec,DELTAT)

  implicit none

  integer nt,nrec
  double precision DELTAT

  double precision sisvx(nt,nrec)
  double precision sisvy(nt,nrec)

  integer irec,it

  character(len=100) file_name

! X component
  do irec=1,nrec
    write(file_name,"('Vx_file_',i3.3,'.dat')") irec
    open(unit=11,file=file_name,status='unknown')
    do it=1,nt
      write(11,*) sngl(dble(it-1)*DELTAT),' ',sngl(sisvx(it,irec))
    enddo
    close(11)
  enddo

! Y component
  do irec=1,nrec
    write(file_name,"('Vy_file_',i3.3,'.dat')") irec
    open(unit=11,file=file_name,status='unknown')
    do it=1,nt
      write(11,*) sngl(dble(it-1)*DELTAT),' ',sngl(sisvy(it,irec))
    enddo
    close(11)
  enddo

  end subroutine write_seismograms

!----
!----  routine to create a color image of a given vector component
!----  the image is created in PNM format and then converted to GIF
!----

  subroutine create_color_image(image_data_2D,NX,NY,it,ISOURCE,JSOURCE,ix_rec,iy_rec,nrec, &
              NPOINTS_PML,USE_PML_XMIN,USE_PML_XMAX,USE_PML_YMIN,USE_PML_YMAX,field_number)

  implicit none

! non linear display to enhance small amplitudes for graphics
  double precision, parameter :: POWER_DISPLAY = 0.30d0

! amplitude threshold above which we draw the color point
  double precision, parameter :: cutvect = 0.01d0

! use black or white background for points that are below the threshold
  logical, parameter :: WHITE_BACKGROUND = .true.

! size of cross and square in pixels drawn to represent the source and the receivers
  integer, parameter :: width_cross = 5, thickness_cross = 1, size_square = 3

  integer NX,NY,it,field_number,ISOURCE,JSOURCE,NPOINTS_PML,nrec
  logical USE_PML_XMIN,USE_PML_XMAX,USE_PML_YMIN,USE_PML_YMAX

  double precision, dimension(NX,NY) :: image_data_2D

  integer, dimension(nrec) :: ix_rec,iy_rec

  integer :: ix,iy,irec

  character(len=100) :: file_name,system_command

  integer :: R, G, B

  double precision :: normalized_value,max_amplitude

! open image file and create system command to convert image to more convenient format
! use the "convert" command from ImageMagick http://www.imagemagick.org
  if(field_number == 1) then
    write(file_name,"('image',i6.6,'_Vx.pnm')") it
    write(system_command,"('convert image',i6.6,'_Vx.pnm image',i6.6,'_Vx.gif ; rm image',i6.6,'_Vx.pnm')") it,it,it
  else if(field_number == 2) then
    write(file_name,"('image',i6.6,'_Vy.pnm')") it
    write(system_command,"('convert image',i6.6,'_Vy.pnm image',i6.6,'_Vy.gif ; rm image',i6.6,'_Vy.pnm')") it,it,it
  endif

  open(unit=27, file=file_name, status='unknown')

  write(27,"('P3')") ! write image in PNM P3 format

  write(27,*) NX,NY ! write image size
  write(27,*) '255' ! maximum value of each pixel color

! compute maximum amplitude
  max_amplitude = maxval(abs(image_data_2D))

! image starts in upper-left corner in PNM format
  do iy=NY,1,-1
    do ix=1,NX

! define data as vector component normalized to [-1:1] and rounded to nearest integer
! keeping in mind that amplitude can be negative
    normalized_value = image_data_2D(ix,iy) / max_amplitude

! suppress values that are outside [-1:+1] to avoid small edge effects
    if(normalized_value < -1.d0) normalized_value = -1.d0
    if(normalized_value > 1.d0) normalized_value = 1.d0

! draw an orange cross to represent the source
    if((ix >= ISOURCE - width_cross .and. ix <= ISOURCE + width_cross .and. &
        iy >= JSOURCE - thickness_cross .and. iy <= JSOURCE + thickness_cross) .or. &
       (ix >= ISOURCE - thickness_cross .and. ix <= ISOURCE + thickness_cross .and. &
        iy >= JSOURCE - width_cross .and. iy <= JSOURCE + width_cross)) then
      R = 255
      G = 157
      B = 0

! display two-pixel-thick black frame around the image
  else if(ix <= 2 .or. ix >= NX-1 .or. iy <= 2 .or. iy >= NY-1) then
      R = 0
      G = 0
      B = 0

! display edges of the PML layers
  else if((USE_PML_XMIN .and. ix == NPOINTS_PML) .or. &
          (USE_PML_XMAX .and. ix == NX - NPOINTS_PML) .or. &
          (USE_PML_YMIN .and. iy == NPOINTS_PML) .or. &
          (USE_PML_YMAX .and. iy == NY - NPOINTS_PML)) then
      R = 255
      G = 150
      B = 0

! suppress all the values that are below the threshold
    else if(abs(image_data_2D(ix,iy)) <= max_amplitude * cutvect) then

! use a black or white background for points that are below the threshold
      if(WHITE_BACKGROUND) then
        R = 255
        G = 255
        B = 255
      else
        R = 0
        G = 0
        B = 0
      endif

! represent regular image points using red if value is positive, blue if negative
    else if(normalized_value >= 0.d0) then
      R = nint(255.d0*normalized_value**POWER_DISPLAY)
      G = 0
      B = 0
    else
      R = 0
      G = 0
      B = nint(255.d0*abs(normalized_value)**POWER_DISPLAY)
    endif

! draw a green square to represent the receivers
  do irec = 1,nrec
    if((ix >= ix_rec(irec) - size_square .and. ix <= ix_rec(irec) + size_square .and. &
        iy >= iy_rec(irec) - size_square .and. iy <= iy_rec(irec) + size_square) .or. &
       (ix >= ix_rec(irec) - size_square .and. ix <= ix_rec(irec) + size_square .and. &
        iy >= iy_rec(irec) - size_square .and. iy <= iy_rec(irec) + size_square)) then
! use dark green color
      R = 30
      G = 180
      B = 60
    endif
  enddo

! write color pixel
    write(27,"(i3,' ',i3,' ',i3)") R,G,B

    enddo
  enddo

! close file
  close(27)

! call the system to convert image to GIF (can be commented out if "call system" is missing in your compiler)
! call system(system_command)

  end subroutine create_color_image

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!       determine the ideas and principles behind any or all constituent
!       elements of said Software. This shall apply when the Licensee
!       carries out any or all loading, displaying, running, transmission
!       or storage operation as regards the Software, that it is entitled
!       to carry out hereunder.
!
!       5.2 ENTITLEMENT TO MAKE CONTRIBUTIONS
!
! The right to make Contributions includes the right to translate, adapt,
! arrange, or make any or all modifications to the Software, and the right
! to reproduce the resulting software.
!
! The Licensee is authorized to make any or all Contributions to the
! Software provided that it includes an explicit notice that it is the
! author of said Contribution and indicates the date of the creation thereof.
!
!       5.3 RIGHT OF DISTRIBUTION
!
! In particular, the right of distribution includes the right to publish,
! transmit and communicate the Software to the general public on any or
! all medium, and by any or all means, and the right to market, either in
! consideration of a fee, or free of charge, one or more copies of the
! Software by any means.
!
! The Licensee is further authorized to distribute copies of the modified
! or unmodified Software to third parties according to the terms and
! conditions set forth hereinafter.
!
!         5.3.1 DISTRIBUTION OF SOFTWARE WITHOUT MODIFICATION
!
! The Licensee is authorized to distribute true copies of the Software in
! Source Code or Object Code form, provided that said distribution
! complies with all the provisions of the Agreement and is accompanied by:
!
!    1. a copy of the Agreement,
!
!    2. a notice relating to the limitation of both the Licensor's
!       warranty and liability as set forth in Articles 8 and 9,
!
! and that, in the event that only the Object Code of the Software is
! redistributed, the Licensee allows future Licensees unhindered access to
! the full Source Code of the Software by indicating how to access it, it
! being understood that the additional cost of acquiring the Source Code
! shall not exceed the cost of transferring the data.
!
!         5.3.2 DISTRIBUTION OF MODIFIED SOFTWARE
!
! When the Licensee makes a Contribution to the Software, the terms and
! conditions for the distribution of the resulting Modified Software
! become subject to all the provisions of this Agreement.
!
! The Licensee is authorized to distribute the Modified Software, in
! source code or object code form, provided that said distribution
! complies with all the provisions of the Agreement and is accompanied by:
!
!    1. a copy of the Agreement,
!
!    2. a notice relating to the limitation of both the Licensor's
!       warranty and liability as set forth in Articles 8 and 9,
!
! and that, in the event that only the object code of the Modified
! Software is redistributed, the Licensee allows future Licensees
! unhindered access to the full source code of the Modified Software by
! indicating how to access it, it being understood that the additional
! cost of acquiring the source code shall not exceed the cost of
! transferring the data.
!
!         5.3.3 DISTRIBUTION OF EXTERNAL MODULES
!
! When the Licensee has developed an External Module, the terms and
! conditions of this Agreement do not apply to said External Module, that
! may be distributed under a separate license agreement.
!
!         5.3.4 COMPATIBILITY WITH THE GNU GPL
!
! The Licensee can include a code that is subject to the provisions of one
! of the versions of the GNU GPL in the Modified or unmodified Software,
! and distribute that entire code under the terms of the same version of
! the GNU GPL.
!
! The Licensee can include the Modified or unmodified Software in a code
! that is subject to the provisions of one of the versions of the GNU GPL,
! and distribute that entire code under the terms of the same version of
! the GNU GPL.
!
!     Article 6 - INTELLECTUAL PROPERTY
!
!       6.1 OVER THE INITIAL SOFTWARE
!
! The Holder owns the economic rights over the Initial Software. Any or
! all use of the Initial Software is subject to compliance with the terms
! and conditions under which the Holder has elected to distribute its work
! and no one shall be entitled to modify the terms and conditions for the
! distribution of said Initial Software.
!
! The Holder undertakes that the Initial Software will remain ruled at
! least by this Agreement, for the duration set forth in Article 4.2.
!
!       6.2 OVER THE CONTRIBUTIONS
!
! The Licensee who develops a Contribution is the owner of the
! intellectual property rights over this Contribution as defined by
! applicable law.
!
!       6.3 OVER THE EXTERNAL MODULES
!
! The Licensee who develops an External Module is the owner of the
! intellectual property rights over this External Module as defined by
! applicable law and is free to choose the type of agreement that shall
! govern its distribution.
!
!       6.4 JOINT PROVISIONS
!
! The Licensee expressly undertakes:
!
!    1. not to remove, or modify, in any manner, the intellectual property
!       notices attached to the Software;
!
!    2. to reproduce said notices, in an identical manner, in the copies
!       of the Software modified or not.
!
! The Licensee undertakes not to directly or indirectly infringe the
! intellectual property rights of the Holder and/or Contributors on the
! Software and to take, where applicable, vis-a-vis its staff, any and all
! measures required to ensure respect of said intellectual property rights
! of the Holder and/or Contributors.
!
!     Article 7 - RELATED SERVICES
!
! 7.1 Under no circumstances shall the Agreement oblige the Licensor to
! provide technical assistance or maintenance services for the Software.
!
! However, the Licensor is entitled to offer this type of services. The
! terms and conditions of such technical assistance, and/or such
! maintenance, shall be set forth in a separate instrument. Only the
! Licensor offering said maintenance and/or technical assistance services
! shall incur liability therefor.
!
! 7.2 Similarly, any Licensor is entitled to offer to its licensees, under
! its sole responsibility, a warranty, that shall only be binding upon
! itself, for the redistribution of the Software and/or the Modified
! Software, under terms and conditions that it is free to decide. Said
! warranty, and the financial terms and conditions of its application,
! shall be subject of a separate instrument executed between the Licensor
! and the Licensee.
!
!     Article 8 - LIABILITY
!
! 8.1 Subject to the provisions of Article 8.2, the Licensee shall be
! entitled to claim compensation for any direct loss it may have suffered
! from the Software as a result of a fault on the part of the relevant
! Licensor, subject to providing evidence thereof.
!
! 8.2 The Licensor's liability is limited to the commitments made under
! this Agreement and shall not be incurred as a result of in particular:
! (i) loss due the Licensee's total or partial failure to fulfill its
! obligations, (ii) direct or consequential loss that is suffered by the
! Licensee due to the use or performance of the Software, and (iii) more
! generally, any consequential loss. In particular the Parties expressly
! agree that any or all pecuniary or business loss (i.e. loss of data,
! loss of profits, operating loss, loss of customers or orders,
! opportunity cost, any disturbance to business activities) or any or all
! legal proceedings instituted against the Licensee by a third party,
! shall constitute consequential loss and shall not provide entitlement to
! any or all compensation from the Licensor.
!
!     Article 9 - WARRANTY
!
! 9.1 The Licensee acknowledges that the scientific and technical
! state-of-the-art when the Software was distributed did not enable all
! possible uses to be tested and verified, nor for the presence of
! possible defects to be detected. In this respect, the Licensee's
! attention has been drawn to the risks associated with loading, using,
! modifying and/or developing and reproducing the Software which are
! reserved for experienced users.
!
! The Licensee shall be responsible for verifying, by any or all means,
! the suitability of the product for its requirements, its good working
! order, and for ensuring that it shall not cause damage to either persons
! or properties.
!
! 9.2 The Licensor hereby represents, in good faith, that it is entitled
! to grant all the rights over the Software (including in particular the
! rights set forth in Article 5).
!
! 9.3 The Licensee acknowledges that the Software is supplied "as is" by
! the Licensor without any other express or tacit warranty, other than
! that provided for in Article 9.2 and, in particular, without any warranty
! as to its commercial value, its secured, safe, innovative or relevant
! nature.
!
! Specifically, the Licensor does not warrant that the Software is free
! from any error, that it will operate without interruption, that it will
! be compatible with the Licensee's own equipment and software
! configuration, nor that it will meet the Licensee's requirements.
!
! 9.4 The Licensor does not either expressly or tacitly warrant that the
! Software does not infringe any third party intellectual property right
! relating to a patent, software or any other property right. Therefore,
! the Licensor disclaims any and all liability towards the Licensee
! arising out of any or all proceedings for infringement that may be
! instituted in respect of the use, modification and redistribution of the
! Software. Nevertheless, should such proceedings be instituted against
! the Licensee, the Licensor shall provide it with technical and legal
! assistance for its defense. Such technical and legal assistance shall be
! decided on a case-by-case basis between the relevant Licensor and the
! Licensee pursuant to a memorandum of understanding. The Licensor
! disclaims any and all liability as regards the Licensee's use of the
! name of the Software. No warranty is given as regards the existence of
! prior rights over the name of the Software or as regards the existence
! of a trademark.
!
!     Article 10 - TERMINATION
!
! 10.1 In the event of a breach by the Licensee of its obligations
! hereunder, the Licensor may automatically terminate this Agreement
! thirty (30) days after notice has been sent to the Licensee and has
! remained ineffective.
!
! 10.2 A Licensee whose Agreement is terminated shall no longer be
! authorized to use, modify or distribute the Software. However, any
! licenses that it may have granted prior to termination of the Agreement
! shall remain valid subject to their having been granted in compliance
! with the terms and conditions hereof.
!
!     Article 11 - MISCELLANEOUS
!
!       11.1 EXCUSABLE EVENTS
!
! Neither Party shall be liable for any or all delay, or failure to
! perform the Agreement, that may be attributable to an event of force
! majeure, an act of God or an outside cause, such as defective
! functioning or interruptions of the electricity or telecommunications
! networks, network paralysis following a virus attack, intervention by
! government authorities, natural disasters, water damage, earthquakes,
! fire, explosions, strikes and labor unrest, war, etc.
!
! 11.2 Any failure by either Party, on one or more occasions, to invoke
! one or more of the provisions hereof, shall under no circumstances be
! interpreted as being a waiver by the interested Party of its right to
! invoke said provision(s) subsequently.
!
! 11.3 The Agreement cancels and replaces any or all previous agreements,
! whether written or oral, between the Parties and having the same
! purpose, and constitutes the entirety of the agreement between said
! Parties concerning said purpose. No supplement or modification to the
! terms and conditions hereof shall be effective as between the Parties
! unless it is made in writing and signed by their duly authorized
! representatives.
!
! 11.4 In the event that one or more of the provisions hereof were to
! conflict with a current or future applicable act or legislative text,
! said act or legislative text shall prevail, and the Parties shall make
! the necessary amendments so as to comply with said act or legislative
! text. All other provisions shall remain effective. Similarly, invalidity
! of a provision of the Agreement, for any reason whatsoever, shall not
! cause the Agreement as a whole to be invalid.
!
!       11.5 LANGUAGE
!
! The Agreement is drafted in both French and English and both versions
! are deemed authentic.
!
!     Article 12 - NEW VERSIONS OF THE AGREEMENT
!
! 12.1 Any person is authorized to duplicate and distribute copies of this
! Agreement.
!
! 12.2 So as to ensure coherence, the wording of this Agreement is
! protected and may only be modified by the authors of the License, who
! reserve the right to periodically publish updates or new versions of the
! Agreement, each with a separate number. These subsequent versions may
! address new issues encountered by Free Software.
!
! 12.3 Any Software distributed under a given version of the Agreement may
! only be subsequently distributed under the same version of the Agreement
! or a subsequent version, subject to the provisions of Article 5.3.4.
!
!     Article 13 - GOVERNING LAW AND JURISDICTION
!
! 13.1 The Agreement is governed by French law. The Parties agree to
! endeavor to seek an amicable solution to any disagreements or disputes
! that may arise during the performance of the Agreement.
!
! 13.2 Failing an amicable solution within two (2) months as from their
! occurrence, and unless emergency proceedings are necessary, the
! disagreements or disputes shall be referred to the Paris Courts having
! jurisdiction, by the more diligent Party.
!
! Version 2.0 dated 2006-09-05.
!