计算脉冲在非线性耦合器中演化的Matlab 程序 ]5QXiF8`�� ]!�s�C��WR % This Matlab script file solves the coupled nonlinear Schrodinger equations of
E"p� _!!�1 % soliton in 2 cores coupler. The output pulse evolution plot is shown in Fig.1 of
�HLq�N=vE6 % Youfa Wang and Wenfeng Wang, “A simple and effective numerical method for nonlinear
�1��+-Go}I % pulse propagation in N-core optical couplers”, IEEE Photonics Technology lett. Vol.16, No.4, pp1077-1079, 2004
��~ L%,�9 k���ZG;�\ %fid=fopen('e21.dat','w');
�n=JV*�h0� N = 128; % Number of Fourier modes (Time domain sampling points)
ga\���s5�
M1 =3000; % Total number of space steps
$rk=#;6]v; J =100; % Steps between output of space
Q.eD:�@%iE T =10; % length of time windows:T*T0
3]9w�fT%d T0=0.1; % input pulse width
qzO�����Rv MN1=0; % initial value for the space output location
�qv�o!n�r7 dt = T/N; % time step
�w<THPFFF" n = [-N/2:1:N/2-1]'; % Index
9�#1?Pt^{< t = n.*dt;
'�[8w8�,v( u10=1.*sech(1*t); % input to waveguide1 amplitude: power=u10*u10
/*fx`0mY�) u20=u10.*0.0; % input to waveguide 2
{a��V,h�@> u1=u10; u2=u20;
LNR1��YC1c U1 = u1;
(��z)#}TC� U2 = u2; % Compute initial condition; save it in U
>� �O?<?� ww = 4*n.*n*pi*pi/T/T; % Square of frequency. Note i^2=-1.
zQ,M795@EA w=2*pi*n./T;
"{���E%�Y* g=-i*ww./2; % w=2*pi*f*n./N, f=1/dt=N/T,so w=2*pi*n./T
q]�pHD�})O L=4; % length of evoluation to compare with S. Trillo's paper
Z]{=�Jy�!F dz=L/M1; % space step, make sure nonlinear<0.05
Ws2?sn�#x for m1 = 1:1:M1 % Start space evolution
PB"=\>]`�N u1 = exp(dz*i*(abs(u1).*abs(u1))).*u1; % 1st sSolve nonlinear part of NLS
|ITCw$�T� u2 = exp(dz*i*(abs(u2).*abs(u2))).*u2;
�V\L%�*�6O ca1 = fftshift(fft(u1)); % Take Fourier transform
H)Me!^@[D� ca2 = fftshift(fft(u2));
@N<h`�vD�a c2=exp(g.*dz).*(ca2+i*1*ca1.*dz); % approximation
A9]&����w� c1=exp(g.*dz).*(ca1+i*1*ca2.*dz); % frequency domain phase shift
Kwa�x�Nb5 u2 = ifft(fftshift(c2)); % Return to physical space
'J0I$�-QYk u1 = ifft(fftshift(c1));
ws�Q�uJ�rG if rem(m1,J) == 0 % Save output every J steps.
�sl@>�GbnS U1 = [U1 u1]; % put solutions in U array
o/�a2n��<4 U2=[U2 u2];
�7D>_<)%d= MN1=[MN1 m1];
Hb�Pn<�x^7 z1=dz*MN1'; % output location
��ADO�A&r[ end
u' �kG(<0Y end
%zY5'$v��` hg=abs(U1').*abs(U1'); % for data write to excel
�\v=@�'��� ha=[z1 hg]; % for data write to excel
Crj7n/mp]s t1=[0 t'];
bFL2�NH��5 hh=[t1' ha']; % for data write to excel file
�vN_ 8qzWk %dlmwrite('aa',hh,'\t'); % save data in the excel format
; }T+ImjA� figure(1)
m}D;�=>�2$ waterfall(t',z1',abs(U1').*abs(U1')) % t' is 1xn, z' is 1xm, and U1' is mxn
=~�W=��}�� figure(2)
J�Jg;�X :p waterfall(t',z1',abs(U2').*abs(U2')) % t' is 1xn, z' is 1xm, and U1' is mxn
Ylu\]pr9|C n�TtEv~a_n 非线性超快脉冲耦合的数值方法的Matlab程序 OJA_OqVp$K !�fe_w5S�^ 在研究脉冲在非线性耦合器中的演变时,我们需要求解非线性偏微分方程组。在如下的
论文中,我们提出了一种简洁的数值方法。 这里我们提供给大家用Matlab编写的计算程序。
#1*�7eANfr Youfa Wang and Wenfeng Wang, “A simple and effective numerical method for nonlinear pulse propagation in N-core optical couplers”, IEEE Photonics Technology lett. Vol.16, No.4, pp1077-1079, 2004
�0:I�<TJ~P P'}B��5�I~ �EB�L-+%J8 3'i(wI~�<[ % This Matlab script file solves the nonlinear Schrodinger equations
k$f2i,7�'� % for 3 cores nonlinear coupler. The output plot is shown in Fig.2 of
E8�nj_�^�Z % Youfa Wang and Wenfeng Wang, “A simple and effective numerical method for nonlinear
��O/#uQ�n} % pulse propagation in N-core optical couplers”, IEEE Photonics Technology lett. Vol.16, No.4, pp1077-1079, 2004
d)Z&_v�<�| B�1U!*yzG6 C=1;
`x�>6Wk�1 M1=120, % integer for amplitude
�ue+{djz[4 M3=5000; % integer for length of coupler
rx9y^E5T`; N = 512; % Number of Fourier modes (Time domain sampling points)
{SXSQ�'=�� dz =3.14159/(sqrt(2.)*C)/M3; % length of coupler is divided into M3 segments, make sure nonlinearity<0.05.
n�nT��#��S T =40; % length of time:T*T0.
c1a��$�J�` dt = T/N; % time step
T�jv�'S
�< n = [-N/2:1:N/2-1]'; % Index
�]�=i('|YG t = n.*dt;
�:O&jm.2m� ww = 4*n.*n*pi*pi/T/T; % Square of frequency. Note i^2=-1.
B�Avz� @�H w=2*pi*n./T;
P�r�f���G� g1=-i*ww./2;
i0+e3!QU�� g2=-i*ww./2; % w=2*pi*f*n./N, f=1/dt=N/T,so w=2*pi*n./TP=0;
[kxO�v7a�� g3=-i*ww./2;
R6;#+ 1D� P1=0;
z'1%%.r;FM P2=0;
0m>��� �8� P3=1;
}hg2}g9��9 P=0;
%-K���5sIz for m1=1:M1
0�&Ftx%6%� p=0.032*m1; %input amplitude
#�6D>e�~>n s10=p.*sech(p.*t); %input soliton pulse in waveguide 1
KDP�4��7�A s1=s10;
,:'J�JZg@� s20=0.*s10; %input in waveguide 2
b$*2bSdv0< s30=0.*s10; %input in waveguide 3
]�&D=��*:c s2=s20;
3�}mg7K�V& s3=s30;
Rmn{Vui�9\ p10=dt*(sum(abs(s10').*abs(s10'))-0.5*(abs(s10(N,1)*s10(N,1))+abs(s10(1,1)*s10(1,1))));
�H7Z`a��QC %energy in waveguide 1
�
qbS6#�7D p20=dt*(sum(abs(s20').*abs(s20'))-0.5*(abs(s20(N,1)*s20(N,1))+abs(s20(1,1)*s20(1,1))));
Rcw[`��q3/ %energy in waveguide 2
4�<E� <�sD p30=dt*(sum(abs(s30').*abs(s30'))-0.5*(abs(s30(N,1)*s30(N,1))+abs(s30(1,1)*s30(1,1))));
�2.MUQ;OX %energy in waveguide 3
-�}!mi���V for m3 = 1:1:M3 % Start space evolution
�5�2#�6uBe s1 = exp(dz*i*(abs(s1).*abs(s1))).*s1; % 1st step, Solve nonlinear part of NLS
�~&M�Dfpl s2 = exp(dz*i*(abs(s2).*abs(s2))).*s2;
#l�:�
1R&F s3 = exp(dz*i*(abs(s3).*abs(s3))).*s3;
6P>}7��R}� sca1 = fftshift(fft(s1)); % Take Fourier transform
�&�)���||~ sca2 = fftshift(fft(s2));
�ohe[rV>EX sca3 = fftshift(fft(s3));
�N�R8`nc1~ sc1=exp(g1.*dz).*(sca1+i*C*sca2.*dz); % 2nd step, frequency domain phase shift
6~W@$SP,F� sc2=exp(g2.*dz).*(sca2+i*C*(sca1+sca3).*dz);
��!plu;�w� sc3=exp(g3.*dz).*(sca3+i*C*sca2.*dz);
9x�zo�w,mi s3 = ifft(fftshift(sc3));
�z9OpxW@Ou s2 = ifft(fftshift(sc2)); % Return to physical space
`\;Z&jlpT� s1 = ifft(fftshift(sc1));
�VE��I�ct{ end
>D~8iuy]8. p1=dt*(sum(abs(s1').*abs(s1'))-0.5*(abs(s1(N,1)*s1(N,1))+abs(s1(1,1)*s1(1,1))));
F$�'��u�`� p2=dt*(sum(abs(s2').*abs(s2'))-0.5*(abs(s2(N,1)*s2(N,1))+abs(s2(1,1)*s2(1,1))));
�$>�yfu=]? p3=dt*(sum(abs(s3').*abs(s3'))-0.5*(abs(s3(N,1)*s3(N,1))+abs(s3(1,1)*s3(1,1))));
X��9FO"(J� P1=[P1 p1/p10];
sb8bCEm-�\ P2=[P2 p2/p10];
�>� 3(,�s^ P3=[P3 p3/p10];
5%fW�X'�mS P=[P p*p];
GU��@#�\3� end
��yx4pQ�L7 figure(1)
N#e9w3Rli plot(P,P1, P,P2, P,P3);
2@z�.ory.� G
