[分享]利用MATLAB光学仿真（1） [复制链接]

利用菲涅尔公式计算光波在两种介质表面折反射率及折反射能流密度 b_vKP  
 X`20=x  
1、光疏射向光密 K(,MtY*  
,m Nd#  
clear Ea)=K'Pz  
IhHKRb[  
close all Yosfk\D  
@u@,Edh  
n1=1,n2=1.45; $ ~%w21?&  
%Jji<M]  
theta=0:0.1:90; /Un\P  
,R\ex =c  
a=theta*pi/180; \1O wZ@  
y(wb?86#W5  
rp=(n2*cos(a)-n1*sqrt(1-(n1/n2*sin(a)).^2))./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); 25j?0P"&  
QM24cm T  
rs=(n1*cos(a)-n2*sqrt(1-(n1/n2*sin(a)).^2))./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); H]}mg='kI  
NY6;\ 7!n  
tp=2*n1*cos(a)./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); }X6w"  
"/ySHB[  
ts=2*n1*cos(a)./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); kX2Z@ w`  
\S_Ae;  
figure(1) >K<cc#Aa  
lA`qB1x  
subplot(1,2,1); =$y;0]7Lwi  
mT/^F{c  
plot(theta,rp,'-',theta,rs,'--',theta,abs(rp),':',theta,abs(rs),'-.','LineWidth',2) R=3|(R+kA  
~d3|zlh  
legend('r_p','r_s','|r_p|','|r_s|') _<GXR ?  
q|}O-A*wa  
xlabel('\theta_i') z(u,$vZ_  
qu\U^F  
ylabel('Amplitude') D_?dy4\  
r PTfwhs  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) Ng2Z7k  
?[|A sw1t  
axis([0 90 -1 1]) H.;2o(vD  
HV'M31m~q  
grid on /BN=Kl]  
Y4+]5;B8  
subplot(1,2,2); j/jFS]
iC  
$DaQM'-  
plot(theta,tp,'-',theta,ts,'--',theta,abs(tp),':',theta,abs(ts),'-.','LineWidth',2) _F(Np\%_  
C[';B)a  
legend('t_p','t_s','|t_p|','|t_s|') kxR!hA8wv4  
bXeJk]#y  
xlabel('\theta_i') k[}WYs+r  
}lXor~_i  
ylabel('Amplitude') H& $M/`  
H|$ *HQm  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) #Cx#U"~G`  
jZQ{XMF  
axis([0 90 0 1]) A)gSOC{3F)  
e _(';Lk  
grid on Qp7F3,/#  
j"jQiL_*  
Rp=abs(rp).^2; LqXVi80  
l$kO%E'  
Rs=abs(rs).^2; Fn0|v66  
\mTi@T!&  
Rn=(Rp+Rs)/2; N{}8Zh4op  
'BUfdb8d  
Tp=1-Rp; Nobu= Z  
*8+HQ[[
#  
Ts=1-Rs; q{%~(A5*H  
;W|GUmADf  
Tn=(Tp+Ts)/2; `EfFyhG$  
3}8L!2_p  
figure(2) L]H' ]wpn=  
`\P1Ff@z0  
subplot(1,2,1); `Z#':0Z  
.'.bokl/  
plot(theta,Rp,'-',theta,Rs,'--',theta,Rn,':','LineWidth',2) zC*dJXt@  
YNl".c  
legend('R_p','R_s','R_n') ll[&O4.F  
itE/QB  
xlabel('\theta_i') Wsp c;]&  
+]( #!}oH  
ylabel('Amplitude') E^gN]Z"O  
&*E! %57  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) +J~%z*A  
>$yA ,N  
axis([0 90 0 1]) :x
Tm-L  
o~W,VhCP
 
grid on k7{|\w%  
a@Zolz_Z  
subplot(1,2,2); *_d N9  
#z70:-`.[M  
plot(theta,Tp,'-',theta,Ts,'--',theta,Tn,':','LineWidth',2) Um4DVg5  
2ga8 G4dU  
legend('T_p','T_s','T_n') %!AzFL J|Z  
wW8[t8%43  
xlabel('\theta_i') s|:1z"q  
kma>'P`G  
ylabel('Amplitude') fFoZ!H  
OHW|?hI=[  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) @Kn@j D;  
*z#du*f[  
axis([0 90 0 1]) QC!SgV  
S{v]B_N[M  
grid on KK5_;<  
00s)=A_  
A|]#b?-  
_~D#?cFY6  
-rjQ^ze  

2、光密射向光疏 OB\ZT@l  
1 ?Zw  
clear L, #|W  
<%`Rku  
close all ij~-  
]NI CQ9  
n1=1.45,n2=1; ggitUQ+t;G  
f[.'V1  
theta=0:0.1:90; -meY[!"X  
^W9O_5\g4a  
a=theta*pi/180; diVg|Z3T  
L;y BZLM  
rp=(n2*cos(a)-n1*sqrt(1-(n1/n2*sin(a)).^2))./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); =$L+J O  
2K o]Q_,~  
rs=(n1*cos(a)-n2*sqrt(1-(n1/n2*sin(a)).^2))./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); 3&5b!Y  
ZZHzC+O#^  
tp=2*n1*cos(a)./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); ;+|Z5+7!6  
|5:2?S2R  
ts=2*n1*cos(a)./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); } XhL`%  
dKC*QHU  
figure(1) N
P.i,H  
6>;OVX  
subplot(1,2,1); wfEL .h  
)G?\{n-  
plot(theta,rp,'-',theta,rs,'--',theta,abs(rp),':',theta,abs(rs),'-.','LineWidth',2) tg==Qgz  
guGX  G+  
legend('r_p','r_s','|r_p|','|r_s|') b SgbvnJ  
surNJ,)  
xlabel('\theta_i') bu<d>XR  
%n8CK->  
ylabel('Amplitude') V=th-o3[  
?6nB=B)/  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) {^(uoB C/  
&7>]# *  
axis([0 90 -1.5 1.5]) cQ1Axs TO  
vr{|ubG]d  
grid on  qsXkm4  
^Go,HiB  
subplot(1,2,2); 5/i/. 0?n  
T0"nzukd  
plot(theta,tp,'-',theta,ts,'--',theta,abs(tp),':',theta,abs(ts),'-.','LineWidth',2) v_pe=LC{-e  
/]j
{P4  
legend('t_p','t_s','|t_p|','|t_s|') }$L1A  
8 l)K3;q_  
xlabel('\theta_i') <uJ {>~  
e
yp_.1C~  
ylabel('Amplitude') $d])>4eQ  
`GY3H3B  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) XTk :lzFH  
0*tnJB  
axis([0 90 -0.5 3]) o<Mccj  
$'_Q@ZBq  
grid on lo'#dpt<  
b?Uk%Z]+v  
Rp=abs(rp).^2; 3D!7,@&>3  
&~/g[\Y  
Rs=abs(rs).^2; Ta/zDc"e  
 [OUV!o  
Rn=(Rp+Rs)/2; W2h4ej\s  
;S$  
Tp=1-Rp; 7][fciZN  
tjB)-=j[  
Ts=1-Rs; S{8-XiL,  
fp\mBe
i  
Tn=(Tp+Ts)/2; D
O-M0L  
9
xq3>(  
figure(2) wb(S7OsMO  
IemhHf ^l  
subplot(1,2,1); GHn0(o&K  
z"\w9 @W  
plot(theta,Rp,'-',theta,Rs,'--',theta,Rn,':','LineWidth',2) %saP>]o  
5 -|7I7(G$  
legend('R_p','R_s','R_n') htL1aQ.  
`8O Bw  
xlabel('\theta_i') N%Y!{k5T7  
!\d~9H%`B  
ylabel('Amplitude') ,30lu a  
:E|Jqi\  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) islHtX V
E  
]+a~/  
axis([0 90 0 1]) SSla^,MHef  
4gev^/^^  
grid on /ar0K9`c  
=-/'$7R,  
subplot(1,2,2); Q
(aNa!  
,xrA2  
plot(theta,Tp,'-',theta,Ts,'--',theta,Tn,':','LineWidth',2) v@SHR0  
Sw; kUJ  
legend('T_p','T_s','T_n') 8(y%]#n  
L
Jb=9tp~  
xlabel('\theta_i') j7a}<\  
dqQJC qc!  
ylabel('Amplitude') 2ib,33 Z  
mOHOv61  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) nsXG@CS:  
AY<L8  
axis([0 90 0 1]) 6LCR ;~ ]  
1BW9,Xr  
grid on ,YBO}l  
Bfo#N31F}  
o@dTiQK_  
J?dz>3Rhx9  

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这个在《MATLAB在光学中的应用》这本书里都有

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