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FWI_time.jl
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FWI_time.jl
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# This file contains some functions needed in FWI algorithm.
include("AcousticWaveSolver.jl");
function make_data(vel, Nx, Ny, h, Nt, dt, source_vec, source_coor, receiver_coor, pml_alpha, pml_len)
# println("Making data.")
# wavefield = SharedArray{Float32}(Nx,Ny,Nt,source_num);
# recorded_data = SharedArray{Float32}(receiver_num,Nt,source_num);
wavefield = zeros(Float32,Nx,Ny,Nt,source_num);
recorded_data = zeros(Float32,receiver_num,Nt,source_num);
for ind_source = 1:source_num
source_vec0 = source_vec[ind_source,:]';
source_coor0 = source_coor[ind_source,:]';
wavefield[:,:,:,ind_source], recorded_data[:,:,ind_source] = AcousticWaveSolver2d_PML(vel, Nx, Ny, h, Nt, dt, source_vec0, source_coor0, receiver_coor, pml_alpha, pml_len, true);
# println(" Source ", ind_source, " done.")
end
# println("Data has been made.")
return wavefield, recorded_data;
end
function compute_gradient(vel_init, Nx, Ny, h, Nt, dt, source_vec, source_coor, source_num, receiver_coor, pml_alpha, pml_len, recorded_data_true)
println("Computing gradient.")
# gradient = SharedArray{Float32}(Nx,Ny,source_num);
gradient = zeros(Float32,Nx,Ny,source_num);
# Forward
wavefield_forward, recorded_data_forward = make_data(vel_init, Nx, Ny, h, Nt, dt, source_vec, source_coor, receiver_coor, pml_alpha, pml_len);
local forward_wavefield_tt = zeros(Float32, Nx, Ny, Nt, source_num);
forward_wavefield_tt[:,:,2:end-1,:] = (wavefield_forward[:,:,3:end,:] - 2*wavefield_forward[:,:,2:end-1,:] + wavefield_forward[:,:,1:end-2,:])/(dt^2);
# source loop
for ind_source = 1:source_num
source_vec0 = source_vec[ind_source,:]';
source_coor0 = source_coor[ind_source,:]';
# Backward
adjoint_source = flipdim(recorded_data_true[:,:,ind_source] - recorded_data_forward[:,:,ind_source],2);
wavefield_back, recorded_data_back = AcousticWaveSolver2d_PML(vel_init, Nx, Ny, h, Nt, dt, adjoint_source, receiver_coor, source_coor0, pml_alpha, pml_len, false);
wavefield_back = flipdim(wavefield_back,3);
# Gradient
gradient0 = - forward_wavefield_tt[:,:,:,ind_source] .* wavefield_back;
gradient0 = sum(gradient0,3);
gradient0 = gradient0[:,:,1];
gradient[:,:,ind_source] = gradient0;
println(" Source ", ind_source, " done.")
end
gradient = sum(gradient,3);
gradient = gradient[:,:,1];
gradient = gradient ./ maximum(gradient);
# misfit func
J = 1/2 * sum((recorded_data_forward - recorded_data_true).^2);
println("Finish gradient.")
return J, gradient;
end
function source_loop(vel_init, Nx, Ny, h, Nt, dt, pml_len, pml_alpha, source_coor, source_vec, receiver_coor, received_data)
S = zeros(Nx,Ny);
# Forward and backward
println("Source loop started. Computing sensitivity.")
forward_wavefield, received_data_forward = make_data(vel_init,Nx,Ny,h,Nt,dt,pml_len,pml_alpha,source_coor,source_vec,receiver_coor)
for ind_source = 1:source_num
# adjoint source
# println("Start backward.")
adjoint_source = received_data_forward[:,:,ind_source]-received_data[:,:,ind_source];
adjoint_source = adjoint_source[:,:,1];
adjoint_source = -flipdim(adjoint_source, 2);
# draw_real(adjoint_source)
backward_wavefield, received_data1 = wave_solver_2d_pml(vel_init,Nx,Ny,h,Nt,dt,pml_len,pml_alpha,receiver_coor,adjoint_source,source_coor[ind_source,:]');
backward_wavefield = flipdim(backward_wavefield,3);
# draw_real(backward_wavefield[:,:,700])
# println("Build sensitivity")
forward_wavefield_tt = zeros(Nx, Ny, Nt);
forward_wavefield_tt[:,:,2:Nt-1] = (forward_wavefield[:,:,1:Nt-2,ind_source] - 2*forward_wavefield[:,:,2:Nt-1,ind_source] + forward_wavefield[:,:,3:Nt,ind_source])/(dt^2);
S0 = forward_wavefield_tt .* backward_wavefield;
S0 = sum(S0,3);
S0 = S0[:,:,1];
S0 = -2 ./ (vel_init).^3 .* S0;
# S0 = S0 ./ maximum(abs.(S0));
S = S + S0;
println(" Source: ", ind_source, " done.")
end
S = S./maximum(S);
println("Finish source loop.")
return S, received_data_forward;
end
# That is not a backtracking line search method. Just some poor algorithm which works...
function line_search(vel, recorded_data_true, vel_new, Nx, Ny, h, Nt, dt, source_vec, source_coor, receiver_coor, pml_alpha, pml_len)
println("Start line search")
N_alpha = 10;
Max_alpha = 200;
alpha_vec = linspace(Max_alpha,0,N_alpha);
J_vec = zeros(N_alpha)
for i = 1:N_alpha-1
alpha = alpha_vec[i];
vel_new = vel - alpha * gradient;
J_vec[i] = misfit_func(recorded_data_true, vel_new, Nx, Ny, h, Nt, dt, source_vec, source_coor, receiver_coor, pml_alpha, pml_len);
end
println("alpha: ", alpha_vec)
println("J: ", J_vec)
alpha = J_vec[indmin(alpha)]
return alpha
end
# function backtracking_line_search(vel0, gradient,c,tau,iter_max,alpha,received_data_forward, received_data, Nx,Ny,h,Nt,dt,pml_len,pml_alpha,source_coor,source_vec,receiver_coor)
# println("Start backtracking line search")
# J0 = sum((received_data_forward - received_data).^2);
# gradient_vec = reshape(gradient,Nx*Ny,1);
# p = -1*gradient_vec;
# m = p'*gradient_vec;
# t = -c*m;
# alpha = alpha / tau;
# for i = 1:iter_max
# alpha = tau * alpha;
# vel_new = vel0 - alpha * gradient;
# wavefield_new, received_data_new = make_data(vel_new,Nx,Ny,h,Nt,dt,pml_len,pml_alpha,source_coor,source_vec,receiver_coor);
# wavefield_new = [];
# J = sum((received_data_forward - received_data_new).^2);
# println("J0 - J is ", J0-J, " αt is ", alpha*t[1])
# println("Iter time: ", i, " alpha: ", alpha, " J0: ", J0, " J: ", J)
# if (J0-J) >= (alpha*t[1])
# println("Line search done.")
# break;
# end
# println("Line search done.")
# end
# return alpha
# end