[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 ;Kf|a}m-  
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1、光疏射向光密 3CE8+PnT  
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clear $<cZ<g5)  
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close all  IR LPUP  
L0kNt &di  
n1=1,n2=1.45; tD]&et  
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theta=0:0.1:90; AD\<}/3U  
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a=theta*pi/180; &-fx=gq=  
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rp=(n2*cos(a)-n1*sqrt(1-(n1/n2*sin(a)).^2))./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); N%f!B"NQ  
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rs=(n1*cos(a)-n2*sqrt(1-(n1/n2*sin(a)).^2))./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); V]]qu:Mh8  
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tp=2*n1*cos(a)./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); |y%].y)  
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ts=2*n1*cos(a)./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); Qu,k  
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figure(1) dz|*n'd  
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subplot(1,2,1); xLI{=sL  
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plot(theta,rp,'-',theta,rs,'--',theta,abs(rp),':',theta,abs(rs),'-.','LineWidth',2) Pp_3 nyQ  
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legend('r_p','r_s','|r_p|','|r_s|') 1N!g`=}  
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xlabel('\theta_i') <j\;>3Q  
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ylabel('Amplitude') n[Iu!v\/*  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) ?=!XhU .  
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axis([0 90 -1 1]) "O[76}I+.q  
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grid on '$XHRS/q]  
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subplot(1,2,2); (?BgT i\  
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plot(theta,tp,'-',theta,ts,'--',theta,abs(tp),':',theta,abs(ts),'-.','LineWidth',2) 5^K#Tj ;2  
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legend('t_p','t_s','|t_p|','|t_s|') 
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xlabel('\theta_i') h ^h-pd  
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ylabel('Amplitude') 0BB@E(*  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) Hu9R.[u  
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axis([0 90 0 1]) P%`R7yk  
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grid on V$<G)dwUG5  
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Rp=abs(rp).^2; ]KK ZbEO  
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Rs=abs(rs).^2; L%K_.!d^  
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Rn=(Rp+Rs)/2; Flujwh@rg  
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Tp=1-Rp; >3`ctbe  
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Ts=1-Rs; [Ht."Vx
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Tn=(Tp+Ts)/2; :.S41S   
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figure(2) ]X: rby$  
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subplot(1,2,1); 4 ?@uF[  
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plot(theta,Rp,'-',theta,Rs,'--',theta,Rn,':','LineWidth',2) ?gR\A8:8  
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legend('R_p','R_s','R_n') }1]!#yMfq  
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xlabel('\theta_i') UiK+c30FU  
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ylabel('Amplitude') c,+(FQ9  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) KBr5bcm4u  
kh?#={]Z  
axis([0 90 0 1]) e.}3OK  
R)d99j^"  
grid on K_&c5(-
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subplot(1,2,2); g;-+7ViIr  
h#@4@x{  
plot(theta,Tp,'-',theta,Ts,'--',theta,Tn,':','LineWidth',2) XJJ[F|k~  
l<aqiZSY  
legend('T_p','T_s','T_n') HhWwc#B  
Vgqvvq<S  
xlabel('\theta_i') u_
4:#~b  
#U$YZ#B  
ylabel('Amplitude') /+4^.Q*  
%%as>}.  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) 2%5^Fi  
KO-Zz&2f  
axis([0 90 0 1]) ^/%o%J&Hz  
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grid on tIxhSI^  
npO@Haw  
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2、光密射向光疏 j}rgO
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clear @4/~~  
$@[dm)M  
close all ~t{D5#LVHa  
9?u9wuH  
n1=1.45,n2=1; Em~7D]Y  
P9 {}&z%:  
theta=0:0.1:90; z'?7]C2b  
iUeV5c
B  
a=theta*pi/180; WZ^
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}mKGuCoH>  
rp=(n2*cos(a)-n1*sqrt(1-(n1/n2*sin(a)).^2))./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); U8-Q'1IT&  
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rs=(n1*cos(a)-n2*sqrt(1-(n1/n2*sin(a)).^2))./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); yxaT7Oqh%  
ZR!cQ oV=  
tp=2*n1*cos(a)./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); h^o+E2<]  
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ts=2*n1*cos(a)./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); L
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figure(1) W<\kf4Y  
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subplot(1,2,1); &
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plot(theta,rp,'-',theta,rs,'--',theta,abs(rp),':',theta,abs(rs),'-.','LineWidth',2) Q^$ghZ6V  
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legend('r_p','r_s','|r_p|','|r_s|') 9U#\nXM  
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xlabel('\theta_i') |RR"'o_E  
a$C2}  
ylabel('Amplitude') 0zg2g!lh  
#d7N| 9_  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) I*^5'N'  
4^0d)+Ff  
axis([0 90 -1.5 1.5]) 8K|J:[7  
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grid on Ap11b|v  
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subplot(1,2,2); 8 ne/=N|,  
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plot(theta,tp,'-',theta,ts,'--',theta,abs(tp),':',theta,abs(ts),'-.','LineWidth',2) nAIH`L"X  
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legend('t_p','t_s','|t_p|','|t_s|') gzVtxDh  
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xlabel('\theta_i') MVeFe\r  
ki\B!<uv  
ylabel('Amplitude') X.s*>'  
sB?2*S"X)<  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) *R5`.j =  
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axis([0 90 -0.5 3]) RTK}mhnV  
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grid on p={Jf}v  
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Rp=abs(rp).^2; 24//21m  
`q%U{IR  
Rs=abs(rs).^2; C`dkD0_  
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Rn=(Rp+Rs)/2; v9u<F6  
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Tp=1-Rp; CK2B  
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Ts=1-Rs; doBNghS  
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Tn=(Tp+Ts)/2; ndr)3tuYu  
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figure(2) RL6Vkd?  

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subplot(1,2,1); }7.#Dj/r6  
;>DHD*3X  
plot(theta,Rp,'-',theta,Rs,'--',theta,Rn,':','LineWidth',2) 8q0I:SJy  
jO=*:{#x  
legend('R_p','R_s','R_n') _mXs4  
Zb."*zL  
xlabel('\theta_i') YJd8l>mz  
<|a=hHPi:  
ylabel('Amplitude') zDB
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) (_K_`5d;QI  
ur6e&bTp  
axis([0 90 0 1]) cJ. 7Mt  
\ZMP_UU(  
grid on -j&
Vtr  
qbb6,DL7J  
subplot(1,2,2); |H W( vA  
1fY>>*oP  
plot(theta,Tp,'-',theta,Ts,'--',theta,Tn,':','LineWidth',2) ]KWK}Zyi  
l xe`u}[  
legend('T_p','T_s','T_n') LKx`v90p  
vG~+r<:  
xlabel('\theta_i') !{(ls<  
tw<P)V\h  
ylabel('Amplitude') 3V}(fnv  
7Lg7ei2mN7  
title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) V.8%|-d  
Q.A \U>AgV  
axis([0 90 0 1]) ;'}'5nO=$  
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grid on Iyyo3awc  
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感谢楼主分享

这个在《MATLAB在光学中的应用》这本书里都有

谢谢了楼主分享

thanks

谢谢了楼主分享

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学习学习 [<c&|tfl  

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