[讨论]公差分析结果的疑问 [复制链接]

我现在在初学zemax的公差分析，找了一个双胶合透镜 D\-\U E/  
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图片:1.JPG

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然后添加了默认公差分析，基本没变 dM^Z,;u  
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图片:2.jpg

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然后运行分析的结果如下： ud$-A  
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Analysis of Tolerances ^.!jD+=I  
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File : E:\光学设计资料\zemax练习\f500.ZMX ?}4,s7PR  
Title: KRC"3Qt  
Date : TUE JUN 21 2011 7<] EH:9  
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Units are Millimeters.
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All changes are computed using linear differences. h7UNmwj  
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Paraxial Focus compensation only. lt&(S)  
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WARNING: Solves should be removed prior to tolerancing. kY~4AH  
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Mnemonics: Ct w<-'  
TFRN: Tolerance on curvature in fringes. ,dCEy+  
TTHI: Tolerance on thickness. i#`q<+/q  
TSDX: Tolerance on surface decentering in x. 8'8`xu$  
TSDY: Tolerance on surface decentering in y. 0yI1r7yNB+  
TSTX: Tolerance on surface tilt in x (degrees). @I`^\oJ  
TSTY: Tolerance on surface tilt in y (degrees). ujX;wGje  
TIRR: Tolerance on irregularity (fringes). _NsEeKU  
TIND: Tolerance on Nd index of refraction. !{t|z=Qg  
TEDX: Tolerance on element decentering in x. Ey|_e3Lf[  
TEDY: Tolerance on element decentering in y. f|~{j(.v  
TETX: Tolerance on element tilt in x (degrees). 7PX`kI  
TETY: Tolerance on element tilt in y (degrees). 3uqhYT;  
F#sm^%_2  
WARNING: RAY AIMING IS OFF. Very loose tolerances may not be computed accurately. Ic0Y  
-{xk&EB^$5  
WARNING: Boundary constraints on compensators will be ignored. rm,`M  
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Criterion           : Geometric MTF average S&T at 30.0000 cycles per mm 0- )K_JV  
Mode                : Sensitivities [7FG;}lB-  
Sampling            : 2 4V')FGB$  
Nominal Criterion   : 0.54403234 0 Uropam  
Test Wavelength     : 0.6328 `x`[hJ?i  
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,|({[9jA  
Fields: XY Symmetric Angle in degrees 9qB0F_xl  
#      X-Field      Y-Field       Weight    VDX    VDY    VCX    VCY I4X9RYB6c  
1   0.000E+000   0.000E+000   1.000E+000  0.000  0.000  0.000  0.000 dz] 5s  
l4oyF|oJTH  
Sensitivity Analysis: !w
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                 |----------------- Minimum ----------------| |----------------- Maximum ----------------| fORkH^Y(&  
Type                      Value      Criterion        Change          Value      Criterion        Change g"ev
np  
Fringe tolerance on surface 1 `OBzOM  
TFRN   1            -1.00000000     0.54257256    -0.00145977     1.00000000     0.54548607     0.00145374 8Y?M:^f~  
Change in Focus                :      -0.000000                            0.000000 XVYFyza;  
Fringe tolerance on surface 2 }'$PYAf6  
TFRN   2            -1.00000000     0.54177471    -0.00225762     1.00000000     0.54627463     0.00224230 N]A# ecm  
Change in Focus                :       0.000000                            0.000000 "<!U  
Fringe tolerance on surface 3 MEiP&=gX!  
TFRN   3            -1.00000000     0.54779866     0.00376632     1.00000000     0.54022572    -0.00380662 lir=0oq<  
Change in Focus                :      -0.000000                            0.000000 ::|~tLFu  
Thickness tolerance on surface 1 z~ cW,  
TTHI   1   3        -0.20000000     0.54321462    -0.00081772     0.20000000     0.54484759     0.00081525 dI{DiPho  
Change in Focus                :       0.000000                            0.000000 t<!;shH,s  
Thickness tolerance on surface 2 bO=|utpk  
TTHI   2   3        -0.20000000     0.54478712     0.00075478     0.20000000     0.54327558    -0.00075675 2s\ClT  
Change in Focus                :       0.000000                           -0.000000 #X}HF$t{=  
Decenter X tolerance on surfaces 1 through 3 6l]X{A.  
TEDX   1   3        -0.20000000     0.54401464   -1.7700E-005     0.20000000     0.54401464   -1.7700E-005 1UP=(8j/  
Change in Focus                :       0.000000                            0.000000 ~zqb{o^pT  
Decenter Y tolerance on surfaces 1 through 3 +WH\,E  
TEDY   1   3        -0.20000000     0.54401464   -1.7700E-005     0.20000000     0.54401464   -1.7700E-005 ]ordqulq1  
Change in Focus                :       0.000000                            0.000000 @Jzk2,rI  
Tilt X tolerance on surfaces 1 through 3 (degrees) ]:|
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TETX   1   3        -0.20000000     0.54897548     0.00494314     0.20000000     0.54897548     0.00494314 P0m3IH)  
Change in Focus                :       0.000000                            0.000000 H@Z_P p?  
Tilt Y tolerance on surfaces 1 through 3 (degrees) /T w{JO#Q  
TETY   1   3        -0.20000000     0.54897548     0.00494314     0.20000000     0.54897548     0.00494314 !(GyOAb  
Change in Focus                :       0.000000                            0.000000 HZyA\FS  
Decenter X tolerance on surface 1 m\L`$=eO8  
TSDX   1            -0.20000000     0.53999563    -0.00403671     0.20000000     0.53999563    -0.00403671 m@td[^O-  
Change in Focus                :       0.000000                            0.000000 e8F]m`{_"  
Decenter Y tolerance on surface 1 ;w7mr1  
TSDY   1            -0.20000000     0.53999563    -0.00403671     0.20000000     0.53999563    -0.00403671 ] G&*HMtp  
Change in Focus                :       0.000000                            0.000000 [n2B6Px  
Tilt X tolerance on surface (degrees) 1 utlr|m Xc  
TSTX   1            -0.20000000     0.42678383    -0.11724851     0.20000000     0.42678383    -0.11724851 wVBKVb9N  
Change in Focus                :       0.000000                            0.000000 EuK}L[Kl  
Tilt Y tolerance on surface (degrees) 1 ~KBa-i%o  
TSTY   1            -0.20000000     0.42678383    -0.11724851     0.20000000     0.42678383    -0.11724851 Hr|f(9xA  
Change in Focus                :       0.000000                            0.000000 i9;  
Decenter X tolerance on surface 2 UVo`jb|> o  
TSDX   2            -0.20000000     0.51705427    -0.02697807     0.20000000     0.51705427    -0.02697807 /( Wq  
Change in Focus                :       0.000000                            0.000000 T8XrmR&?PX  
Decenter Y tolerance on surface 2 ge~@}&#iO@  
TSDY   2            -0.20000000     0.51705427    -0.02697807     0.20000000     0.51705427    -0.02697807 IiU>VLa  
Change in Focus                :       0.000000                            0.000000 7'G;ijx  
Tilt X tolerance on surface (degrees) 2 8tj]@
GE  
TSTX   2            -0.20000000     0.35349910    -0.19053324     0.20000000     0.35349910    -0.19053324 qX\*lm/l  
Change in Focus                :       0.000000                            0.000000 Fc~G*Gz~Z|  
Tilt Y tolerance on surface (degrees) 2 SH%NYjj  
TSTY   2            -0.20000000     0.35349910    -0.19053324     0.20000000     0.35349910    -0.19053324 )4yP(6|lx  
Change in Focus                :       0.000000                            0.000000 )PX VR T  
Decenter X tolerance on surface 3 C8U3+ s  
TSDX   3            -0.20000000     0.53419039    -0.00984195     0.20000000     0.53419039    -0.00984195 `Ij@;=(  
Change in Focus                :       0.000000                            0.000000 k9Pvh,_wp  
Decenter Y tolerance on surface 3 @(t3<g  
TSDY   3            -0.20000000     0.53419039    -0.00984195     0.20000000     0.53419039    -0.00984195 6d-\+t8  
Change in Focus                :       0.000000                            0.000000 ;*A'2ymXUT  
Tilt X tolerance on surface (degrees) 3 |7qt/z  
TSTX   3            -0.20000000     0.42861670    -0.11541563     0.20000000     0.42861670    -0.11541563 .ZTvOm'mB^  
Change in Focus                :       0.000000                            0.000000 E9:@H;Gc  
Tilt Y tolerance on surface (degrees) 3 -$Oh.B`i  
TSTY   3            -0.20000000     0.42861670    -0.11541563     0.20000000     0.42861670    -0.11541563 $R9D L^iD  
Change in Focus                :       0.000000                            0.000000 380`>"D  
Irregularity of surface 1 in fringes u,^CFws_  
TIRR   1            -0.20000000     0.50973587    -0.03429647     0.20000000     0.57333868     0.02930634 HK;NR.D  
Change in Focus                :       0.000000                            0.000000 FY1iY/\Cn  
Irregularity of surface 2 in fringes 9]4
Q@%  
TIRR   2            -0.20000000     0.53400904    -0.01002330     0.20000000     0.55360281     0.00957047 lA
^1}  
Change in Focus                :       0.000000                            0.000000 ]; w 2YR  
Irregularity of surface 3 in fringes {)[o*+9  
TIRR   3            -0.20000000     0.58078982     0.03675748     0.20000000     0.49904394    -0.04498840 v=U<exM6%  
Change in Focus                :       0.000000                            0.000000 ]3KeAJ  
Index tolerance on surface 1 ]PXM;w  
TIND   1            -0.00100000     0.52606778    -0.01796456     0.00100000     0.56121811     0.01718578 M(%H  
Change in Focus                :       0.000000                            0.000000 [9m3@Yd'  
Index tolerance on surface 2 |Y9>kXMl  
TIND   2            -0.00100000     0.55639086     0.01235852     0.00100000     0.53126361    -0.01276872 W }NU
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Change in Focus                :       0.000000                           -0.000000 oaIk1U;g  
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Worst offenders: TEtmmp0OD  
Type                      Value      Criterion        Change u47<J?!Q  
TSTY   2            -0.20000000     0.35349910    -0.19053324 8=8hbdy;  
TSTY   2             0.20000000     0.35349910    -0.19053324 eg0_ <  
TSTX   2            -0.20000000     0.35349910    -0.19053324 T5XXC1+  
TSTX   2             0.20000000     0.35349910    -0.19053324 :U6`
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TSTY   1            -0.20000000     0.42678383    -0.11724851 p.DQ|?  
TSTY   1             0.20000000     0.42678383    -0.11724851 6Yu:v  
TSTX   1            -0.20000000     0.42678383    -0.11724851 V6]6KP#D  
TSTX   1             0.20000000     0.42678383    -0.11724851 wlS/(:02  
TSTY   3            -0.20000000     0.42861670    -0.11541563 =pH2V^<<#  
TSTY   3             0.20000000     0.42861670    -0.11541563 R9J!}az'  
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Estimated Performance Changes based upon Root-Sum-Square method: -f+#j
=FX  
Nominal MTF                 :     0.54403234 YT\`R  
Estimated change            :    -0.36299231 F/5&:e?( )  
Estimated MTF               :     0.18104003 Ji4p6$ .j-  
0At0`Q#  
Compensator Statistics: (3Db}Hnn  
Change in back focus: V9c.(QY|f  
Minimum            :        -0.000000 vFPY|Vzh  
Maximum            :         0.000000 MIMC(<  
Mean               :        -0.000000 9LR=>@Z  
Standard Deviation :         0.000000 [vg&E )V  
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Monte Carlo Analysis: X9x`i  
Number of trials: 20 A5<t>6Y  
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Initial Statistics: Normal Distribution waMF~#PJlt  
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  Trial       Criterion        Change dC=[o\  
      1     0.42804416    -0.11598818 lC<;Q*Y  
Change in Focus                :      -0.400171 i%2u>Ni^  
      2     0.54384387    -0.00018847 /%@;t@BK4  
Change in Focus                :       1.018470 epy2}TI  
      3     0.44510003    -0.09893230 C}huU  
Change in Focus                :      -0.601922 4cjfn'x  
      4     0.18154684    -0.36248550 -TUJ"ep]QJ  
Change in Focus                :       0.920681 L\Se ,  
      5     0.28665820    -0.25737414 ;ALWL~Xm  
Change in Focus                :       1.253875 8^7Oc,:~  
      6     0.21263372    -0.33139862 ORM>|&  
Change in Focus                :      -0.903878 Q}BMvR 9w  
      7     0.40051424    -0.14351809 ImXYI7PL  
Change in Focus                :      -1.354815 b8WtNVd  
      8     0.48754161    -0.05649072 1@]&i
Z]  
Change in Focus                :       0.215922 dNACE*g;q  
      9     0.40357468    -0.14045766 *`>BOl+ro  
Change in Focus                :       0.281783
L2H  
     10     0.26315315    -0.28087919 p9v:T1?  
Change in Focus                :      -1.048393 jJ$\WUQ.  
     11     0.26120585    -0.28282649 kK&w5'  
Change in Focus                :       1.017611 ?sN{U\  
     12     0.24033815    -0.30369419 B[b>T=  
Change in Focus                :      -0.109292 -Vn#Ab_C  
     13     0.37164046    -0.17239188 R)NSJ-A!2  
Change in Focus                :      -0.692430 R1];P*>%gZ  
     14     0.48597489    -0.05805744 =p5D

T  
Change in Focus                :      -0.662040 lQ8hY$  
     15     0.21462327    -0.32940907 
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Change in Focus                :       1.611296 F!+1w(b:  
     16     0.43378226    -0.11025008 '*J+mZtN  
Change in Focus                :      -0.640081 HTQZIm  
     17     0.39321881    -0.15081353 z8\YMr6o  
Change in Focus                :       0.914906 nFnM9 pdMK  
     18     0.20692530    -0.33710703 (Pc>D';{S  
Change in Focus                :       0.801607 +x]/W|5  
     19     0.51374068    -0.03029165 g~hMOI?KK^  
Change in Focus                :       0.947293 c'oiW)8;A  
     20     0.38013374    -0.16389860 O<S.fr,  
Change in Focus                :       0.667010 dq93P%X24  
UtQj<18<  
Number of traceable Monte Carlo files generated: 20 vJWBr:`L  
nCQtn%j't  
Nominal     0.54403234 )Q2IYCj{  
Best        0.54384387    Trial     2 "i0>>@NR'  
Worst       0.18154684    Trial     4 F0$w9p  
Mean        0.35770970 JFT$1^n  
Std Dev     0.11156454 .}==p
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bP18w0>,  
RpJ7.  
Compensator Statistics: {JE [  
Change in back focus: EI_-5TtRD  
Minimum            :        -1.354815 Oeh A3$|#  
Maximum            :         1.611296 z\ZnxZ@  
Mean               :         0.161872 hRf l\Q[  
Standard Deviation :         0.869664 wJC[[_"3 I  
lV\iYX2#  
90% >       0.20977951               64B.7S88  
80% >       0.22748071               VZ9 p "  
50% >       0.38667627               ZHTi4JY  
20% >       0.46553746               ~?\U];l  
10% >       0.50064115                f,G*e367:  
}0'LKwIR  
End of Run. {irc0gI  
]?6wU-a  
这就有了些疑问，为什么我选择的补偿器是近轴焦点，而分析结果近轴焦点都不变化？？应该是变得。另外最后的蒙特卡洛分析，只有10%的大于0.5（我用的是MTF作为评价方式），可是我设计的MTF如图 w6BBu0,KC  

图片:3.JPG

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是大于0.6左右的，难道我按照这个默认的公差来加工的话，只有10%的才可能大于0.5？那太低了啊，请问这该怎么进行进一步处理。或者之前哪有问题 En\@d@j<u  
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不吝赐教

我又试了试，原来是得根据上面的结果不断修改公差，放松或者变紧，然后在做公差分析，不断提高蒙特卡罗的结果。但是比如就拿我这个来说，理想是达到30lp处>0.6，那么实际做蒙特卡罗公差分析时，百分之多少以上的MTF是合格的呢？

90% >       0.20977951                 4X^$"lM  
80% >       0.22748071                 8dR `T}  
50% >       0.38667627                 }+@!c%TCx~  
20% >       0.46553746                 /9br&s$B  
10% >       0.50064115 x,C8):\t`B  
0/v]YK.  
最后这个数值是MTF值呢，还是MTF的公差？ YE`Y t  
l`"?KD  
也就是说，这到底是有90%的产品MTF大于0.20977951还是90%的产品的MTF变化量大于0.20977951？？？   /?;'y,(Q  
v~>Bbe  
怎么没人啊，大家讨论讨论吗

没有人啊？？？

引用第2楼sansummer于2011-06-22 08:56发表的  : R%KF/1;/  
90% >       0.20977951                 @Fc:9a@  
80% >       0.22748071                 xnMcxys~  
50% >       0.38667627                 O q$_ q  
20% >       0.46553746                 g4A{RI  
10% >       0.50064115 b$klm6nMvm  
....... (6$P/k8  

#_.JkY  
4-.W~C'Q  
这些数值都是MTF值

Criterion           : Geometric MTF average S&T at 30.0000 cycles per mm   AY5iTbL1  
Mode                : Sensitivities o=R(DK# U  
Sampling            : 2 7}VqXUwabx  
Nominal Criterion   : 0.54403234 fz^j3'!\  
Test Wavelength     : 0.6328 ^m%#1Zd  
#B5,k|"/,M  
波长632.8nm 时 mtf 是 0.54403234  没达到0.6

谢谢。您说的“波长632.8nm 时 mtf 是 0.54403234  没达到0.6”这是一个评价标准吧？ ?:wb#k)Z/  
I5M\PK/  
这个评价标准和我理想的设计结果的0.6有什么联系吗，另外这个 0.54403234  是这么来的？

你试试把原来的系统波长改成632.8nm，看看Geometric MTF    30 per mm 的mtf值是不是0.54403234

啊...这倒也是。换了波长的确可能有所变化。另外还有就是如果现在百分比太低，我是否应该考虑把最敏感的公差再紧一些，就会好了？

恩，多多尝试