[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 K
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1、光疏射向光密 xGk4KcxKs  
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clear (fb\A6  
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close all @b({QM|  
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n1=1,n2=1.45; ~[6|VpGc:  
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theta=0:0.1:90;  p$v +L  
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a=theta*pi/180; oPZ4}>uV  
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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)); F'*4:WD7  
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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)); FQl|<l6  
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tp=2*n1*cos(a)./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); x*V<afLY[  
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ts=2*n1*cos(a)./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); )5x?Qn(B
 
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figure(1) DJUtuex  
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subplot(1,2,1); !~v>&bCG>9  
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plot(theta,rp,'-',theta,rs,'--',theta,abs(rp),':',theta,abs(rs),'-.','LineWidth',2) gu&oCT  
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legend('r_p','r_s','|r_p|','|r_s|') ]aL}&GlHt  
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xlabel('\theta_i') 0k [6  

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ylabel('Amplitude') E~^'w.1  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) h65j,v6B  
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axis([0 90 -1 1]) q5PYc.E([  
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grid on #CmBgxg+M  
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subplot(1,2,2); YZ@-0_Z  
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plot(theta,tp,'-',theta,ts,'--',theta,abs(tp),':',theta,abs(ts),'-.','LineWidth',2) l-EQh*!j  
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legend('t_p','t_s','|t_p|','|t_s|') 5;Xrf=  
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xlabel('\theta_i') 4uA^/]ygo  
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ylabel('Amplitude') <&iBR  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) @35shLs  
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axis([0 90 0 1]) H;1}Nvvd  
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grid on M-Bw9`#Jw  
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Rp=abs(rp).^2; 4aC#Cv:0  
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Rs=abs(rs).^2; }__+[-  
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Rn=(Rp+Rs)/2; r8rR_M{P  
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Tp=1-Rp; )RFeF!("  
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Ts=1-Rs; Z]<_a)>  
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Tn=(Tp+Ts)/2; HV@:!zM  
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figure(2) >YLm]7v}  
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subplot(1,2,1); j$6}r  
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plot(theta,Rp,'-',theta,Rs,'--',theta,Rn,':','LineWidth',2) >q`X%&l_  
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legend('R_p','R_s','R_n') MXb(Z9)]kw  
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xlabel('\theta_i') YVT^}7#
  
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ylabel('Amplitude') '#PT C,0UJ  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) \+xsJbEV  
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axis([0 90 0 1]) rAKdf??  
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grid on ;QYK {3R?  
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subplot(1,2,2); jJ|;Nwm<[  
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plot(theta,Tp,'-',theta,Ts,'--',theta,Tn,':','LineWidth',2) art{PV
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legend('T_p','T_s','T_n') *D,T}N  
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xlabel('\theta_i') L6m'u6:1{  
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ylabel('Amplitude') 'g#GUSXfj  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) =u(fP" |{  
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axis([0 90 0 1]) Q*I/mUP&f  
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grid on h>wU';5#f  
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2、光密射向光疏 fRiHs\+  
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clear FQ5# v{  
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close all e*tOXXY1  
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n1=1.45,n2=1; HkrNt/]  
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theta=0:0.1:90; j'Fni4;  
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a=theta*pi/180; aePk^?KbB  
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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)); &:rf80`z.  
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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)); sS._N@f  
$3So`8Bm[$  
tp=2*n1*cos(a)./(n2*cos(a)+n1*sqrt(1-(n1/n2*sin(a)).^2)); [8ih-k  
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ts=2*n1*cos(a)./(n1*cos(a)+n2*sqrt(1-(n1/n2*sin(a)).^2)); qg_=5s  
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figure(1) [|v
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subplot(1,2,1); 2?&h{PA+  
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plot(theta,rp,'-',theta,rs,'--',theta,abs(rp),':',theta,abs(rs),'-.','LineWidth',2) +S$x}b'5q  
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legend('r_p','r_s','|r_p|','|r_s|') r'&VH]m  
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xlabel('\theta_i') GE|V^_|i  
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ylabel('Amplitude') -0Ps.B  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) 2vynz,^ET  
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axis([0 90 -1.5 1.5]) uKK+V6}!kj  
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grid on ]`LMy
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subplot(1,2,2); \]zHM.E1  
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plot(theta,tp,'-',theta,ts,'--',theta,abs(tp),':',theta,abs(ts),'-.','LineWidth',2) V V<Zl  
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legend('t_p','t_s','|t_p|','|t_s|') %5'6^bT  
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xlabel('\theta_i') O9bIo]B  
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ylabel('Amplitude')
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) YH@^6Be9  
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axis([0 90 -0.5 3]) 3:s!0ty"  
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grid on `2G 0B@  
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Rp=abs(rp).^2; T)MKhK9\Ab  
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Rs=abs(rs).^2; o!:   
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Rn=(Rp+Rs)/2; O|d"0P  
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Tp=1-Rp; idEhxvAo  
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Ts=1-Rs; J
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Tn=(Tp+Ts)/2; ",Mr+;;:[  
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figure(2) N:_.z~>%  
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subplot(1,2,1); 7*.nd
 
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plot(theta,Rp,'-',theta,Rs,'--',theta,Rn,':','LineWidth',2) 3VaL%+T$,  
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legend('R_p','R_s','R_n') -e(e;e  
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xlabel('\theta_i') 3s;^p,9 Y  
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ylabel('Amplitude') DZ"'GQSg  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) g%TOYZr!X  
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axis([0 90 0 1]) .~u[rc|<  
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grid on fN&@y$  
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subplot(1,2,2); )Vd^#p  
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plot(theta,Tp,'-',theta,Ts,'--',theta,Tn,':','LineWidth',2) e>0gE`8A  
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legend('T_p','T_s','T_n') cDS\=Bf  
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xlabel('\theta_i') xu\s2x$  
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ylabel('Amplitude') Q<0X80w>  
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title(['n_1=',num2str(n1),',n_2=',num2str(n2)]) fYSH]!  
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axis([0 90 0 1]) Uo?4o*}  
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grid on ox*1F+Xri  
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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

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谢谢了楼主分享

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