[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 *LBF+L^C%  
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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 ".|8(Y  
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图片:2.jpg

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然后运行分析的结果如下： rMJ@oc  
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Analysis of Tolerances 'q;MhnU+  
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File : E:\光学设计资料\zemax练习\f500.ZMX jbe:"Stw  
Title: Wx3DWY;  
Date : TUE JUN 21 2011 |7,$.MK-@  
XN t` 4$L  
Units are Millimeters. -eV*I>G  
All changes are computed using linear differences. Ygg+=@].@  
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Paraxial Focus compensation only. ) C~#W  
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WARNING: Solves should be removed prior to tolerancing. )Rbt0   
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Mnemonics: [V?HK_~  
TFRN: Tolerance on curvature in fringes. rC|nE=i  
TTHI: Tolerance on thickness. yO8@.-jb  
TSDX: Tolerance on surface decentering in x. r*mYtS  
TSDY: Tolerance on surface decentering in y. q'H6oD`  
TSTX: Tolerance on surface tilt in x (degrees). |wb_im  
TSTY: Tolerance on surface tilt in y (degrees). o92BGqA>&  
TIRR: Tolerance on irregularity (fringes). >#r0k|3J^J  
TIND: Tolerance on Nd index of refraction. +fozE?  
TEDX: Tolerance on element decentering in x. g$)0E<  
TEDY: Tolerance on element decentering in y. Iw?^  
TETX: Tolerance on element tilt in x (degrees). <w~$S0_  
TETY: Tolerance on element tilt in y (degrees). })@xWU6!  
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WARNING: RAY AIMING IS OFF. Very loose tolerances may not be computed accurately. D6e?J.  
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WARNING: Boundary constraints on compensators will be ignored. _]'kw [  
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Criterion           : Geometric MTF average S&T at 30.0000 cycles per mm En-=z`j G  
Mode                : Sensitivities F\;l)  
Sampling            : 2 |,n(9Ix  
Nominal Criterion   : 0.54403234 f9_Pn'"I  
Test Wavelength     : 0.6328 Bf^K?:r"V  
?t\GHQ$$?  
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Fields: XY Symmetric Angle in degrees V0,5c`H c  
#      X-Field      Y-Field       Weight    VDX    VDY    VCX    VCY yP-$@Ry  
1   0.000E+000   0.000E+000   1.000E+000  0.000  0.000  0.000  0.000 [=.iJ5,{2  
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Sensitivity Analysis: IYptNR  
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                 |----------------- Minimum ----------------| |----------------- Maximum ----------------| $i8oLSRV  
Type                      Value      Criterion        Change          Value      Criterion        Change Zg= {  
Fringe tolerance on surface 1 +('xzW  
TFRN   1            -1.00000000     0.54257256    -0.00145977     1.00000000     0.54548607     0.00145374 pkG8g5(w  
Change in Focus                :      -0.000000                            0.000000 H_Hr=_8}-  
Fringe tolerance on surface 2 Gyi0SM6v5&  
TFRN   2            -1.00000000     0.54177471    -0.00225762     1.00000000     0.54627463     0.00224230 Qd3ppJn  
Change in Focus                :       0.000000                            0.000000 7PfNPz<4+  
Fringe tolerance on surface 3 .gRb'  
TFRN   3            -1.00000000     0.54779866     0.00376632     1.00000000     0.54022572    -0.00380662 ="@f~~  
Change in Focus                :      -0.000000                            0.000000 H,/=<Th;i  
Thickness tolerance on surface 1 0lqh;/  
TTHI   1   3        -0.20000000     0.54321462    -0.00081772     0.20000000     0.54484759     0.00081525 ;6]ag< Q  
Change in Focus                :       0.000000                            0.000000 rf^IJY[  
Thickness tolerance on surface 2 [ryI
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TTHI   2   3        -0.20000000     0.54478712     0.00075478     0.20000000     0.54327558    -0.00075675 Y>nQ<  
Change in Focus                :       0.000000                           -0.000000 ]U4C2}u  
Decenter X tolerance on surfaces 1 through 3
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TEDX   1   3        -0.20000000     0.54401464   -1.7700E-005     0.20000000     0.54401464   -1.7700E-005 :=quCzG  
Change in Focus                :       0.000000                            0.000000 E7SmiD@)  
Decenter Y tolerance on surfaces 1 through 3 SZxnYVY  
TEDY   1   3        -0.20000000     0.54401464   -1.7700E-005     0.20000000     0.54401464   -1.7700E-005 NS
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Change in Focus                :       0.000000                            0.000000 vls+E o]  
Tilt X tolerance on surfaces 1 through 3 (degrees) !YM:?%B  
TETX   1   3        -0.20000000     0.54897548     0.00494314     0.20000000     0.54897548     0.00494314 2B6y1"B  
Change in Focus                :       0.000000                            0.000000 j6*e^ B  
Tilt Y tolerance on surfaces 1 through 3 (degrees) ?v+el,  
TETY   1   3        -0.20000000     0.54897548     0.00494314     0.20000000     0.54897548     0.00494314 0|\A5 eG  
Change in Focus                :       0.000000                            0.000000 M6Ik'r"M  
Decenter X tolerance on surface 1 {>ghX_m|  
TSDX   1            -0.20000000     0.53999563    -0.00403671     0.20000000     0.53999563    -0.00403671 [w FK!?  
Change in Focus                :       0.000000                            0.000000 +WxD=|p;  
Decenter Y tolerance on surface 1 6_w~#86=  
TSDY   1            -0.20000000     0.53999563    -0.00403671     0.20000000     0.53999563    -0.00403671 K[V#Pj9  
Change in Focus                :       0.000000                            0.000000 ^m.%FIwR  
Tilt X tolerance on surface (degrees) 1 8RZqoQDH  
TSTX   1            -0.20000000     0.42678383    -0.11724851     0.20000000     0.42678383    -0.11724851 FYg{IKg  
Change in Focus                :       0.000000                            0.000000 T}'*Gry  
Tilt Y tolerance on surface (degrees) 1 [].euDrX  
TSTY   1            -0.20000000     0.42678383    -0.11724851     0.20000000     0.42678383    -0.11724851 zP!j {y4w  
Change in Focus                :       0.000000                            0.000000 BQgK<_  
Decenter X tolerance on surface 2 +I.{y  
TSDX   2            -0.20000000     0.51705427    -0.02697807     0.20000000     0.51705427    -0.02697807 r/+~4W5  
Change in Focus                :       0.000000                            0.000000 |t58n{V.O  
Decenter Y tolerance on surface 2 @C~gU@F  
TSDY   2            -0.20000000     0.51705427    -0.02697807     0.20000000     0.51705427    -0.02697807 -?)z@L
c  
Change in Focus                :       0.000000                            0.000000 QcdAg%"yy  
Tilt X tolerance on surface (degrees) 2 pe\]}&  
TSTX   2            -0.20000000     0.35349910    -0.19053324     0.20000000     0.35349910    -0.19053324 <{HV|B7  
Change in Focus                :       0.000000                            0.000000 ,G$<J0R1  
Tilt Y tolerance on surface (degrees) 2 %:-2P  
TSTY   2            -0.20000000     0.35349910    -0.19053324     0.20000000     0.35349910    -0.19053324 uH} }z!  
Change in Focus                :       0.000000                            0.000000 0bQ"s*K  
Decenter X tolerance on surface 3 99Nm?$g  
TSDX   3            -0.20000000     0.53419039    -0.00984195     0.20000000     0.53419039    -0.00984195 I^``x+a  
Change in Focus                :       0.000000                            0.000000 r;zG  
Decenter Y tolerance on surface 3 7*Gg#XQ>(  
TSDY   3            -0.20000000     0.53419039    -0.00984195     0.20000000     0.53419039    -0.00984195 T' )l  
Change in Focus                :       0.000000                            0.000000 V$MMK  
Tilt X tolerance on surface (degrees) 3 phcYQqR  
TSTX   3            -0.20000000     0.42861670    -0.11541563     0.20000000     0.42861670    -0.11541563 N/B-u
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Change in Focus                :       0.000000                            0.000000 EHq?yj;  
Tilt Y tolerance on surface (degrees) 3 0*/[z
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TSTY   3            -0.20000000     0.42861670    -0.11541563     0.20000000     0.42861670    -0.11541563 5q}7#{A  
Change in Focus                :       0.000000                            0.000000 Ch&2{ng  
Irregularity of surface 1 in fringes $)jf  
TIRR   1            -0.20000000     0.50973587    -0.03429647     0.20000000     0.57333868     0.02930634 ~5~Cpu
2v7  
Change in Focus                :       0.000000                            0.000000 Bh q]h  
Irregularity of surface 2 in fringes ~2 J!I^J  
TIRR   2            -0.20000000     0.53400904    -0.01002330     0.20000000     0.55360281     0.00957047 ? C6tYd  
Change in Focus                :       0.000000                            0.000000 [jKhC<t}  
Irregularity of surface 3 in fringes y>JSo9[@  
TIRR   3            -0.20000000     0.58078982     0.03675748     0.20000000     0.49904394    -0.04498840 7Y1FFw|  
Change in Focus                :       0.000000                            0.000000 KA9v?_@{F  
Index tolerance on surface 1 h}GzQry1  
TIND   1            -0.00100000     0.52606778    -0.01796456     0.00100000     0.56121811     0.01718578 T5TAkEVl  
Change in Focus                :       0.000000                            0.000000 v==/tr)  
Index tolerance on surface 2 2Ni
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TIND   2            -0.00100000     0.55639086     0.01235852     0.00100000     0.53126361    -0.01276872 OGnuBK
 
Change in Focus                :       0.000000                           -0.000000 GaOM|F'>  
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Worst offenders: r)f+j@KF  
Type                      Value      Criterion        Change f]kG%JEK  
TSTY   2            -0.20000000     0.35349910    -0.19053324 {60U6n  
TSTY   2             0.20000000     0.35349910    -0.19053324 f;a55%3c  
TSTX   2            -0.20000000     0.35349910    -0.19053324 c"S{5xh0&  
TSTX   2             0.20000000     0.35349910    -0.19053324 iq`caoi  
TSTY   1            -0.20000000     0.42678383    -0.11724851 ys}I~MK-  
TSTY   1             0.20000000     0.42678383    -0.11724851 6tBe,'*  
TSTX   1            -0.20000000     0.42678383    -0.11724851 N?mQ50o~C  
TSTX   1             0.20000000     0.42678383    -0.11724851 yH',vC.  
TSTY   3            -0.20000000     0.42861670    -0.11541563 p) m0\  
TSTY   3             0.20000000     0.42861670    -0.11541563 /qPhptV  
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Estimated Performance Changes based upon Root-Sum-Square method: YyD0g9{  
Nominal MTF                 :     0.54403234 %2`.*]L  
Estimated change            :    -0.36299231 T5+9#  
Estimated MTF               :     0.18104003 /9@VnM  
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Compensator Statistics: 3|1v)E  
Change in back focus: %1kIaYZ  
Minimum            :        -0.000000 !,cfA';S  
Maximum            :         0.000000 cFloaCz  
Mean               :        -0.000000 kuo!}QFL  
Standard Deviation :         0.000000 Hus.Jfam  
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Monte Carlo Analysis: PI$K+}E  
Number of trials: 20 C5EaP%s  
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Initial Statistics: Normal Distribution {*K7P>&  
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  Trial       Criterion        Change =]W[{@P  
      1     0.42804416    -0.11598818 g,}_&+q:.M  
Change in Focus                :      -0.400171 }<=_&n  
      2     0.54384387    -0.00018847 DAx
1  
Change in Focus                :       1.018470 nm]m!.$d  
      3     0.44510003    -0.09893230 o%[swoM@  
Change in Focus                :      -0.601922 >AUzsQ  
      4     0.18154684    -0.36248550 `E8D5'tt  
Change in Focus                :       0.920681 D`2w>{Y  
      5     0.28665820    -0.25737414 j4}Q  
Change in Focus                :       1.253875 H[U"eS."  
      6     0.21263372    -0.33139862
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Change in Focus                :      -0.903878 NbUbLzE  
      7     0.40051424    -0.14351809 a<lDT_2b  
Change in Focus                :      -1.354815 -$cO0RSY  
      8     0.48754161    -0.05649072 hf< [$B  
Change in Focus                :       0.215922 Nh"U~zlh  
      9     0.40357468    -0.14045766 OzUo}QN  
Change in Focus                :       0.281783 Nd%j0lj  
     10     0.26315315    -0.28087919 Mk!bmFZOZ  
Change in Focus                :      -1.048393 "*ww>0[  
     11     0.26120585    -0.28282649 sk7]s7  
Change in Focus                :       1.017611 *b\&R%6dR  
     12     0.24033815    -0.30369419 o8u;2gZx  
Change in Focus                :      -0.109292 A/88WC$v  
     13     0.37164046    -0.17239188 1}3tpO;  
Change in Focus                :      -0.692430 KLgg([  
     14     0.48597489    -0.05805744 [Lq9lw&   
Change in Focus                :      -0.662040 nG0R1<  
     15     0.21462327    -0.32940907 EjP9/VG@=  
Change in Focus                :       1.611296 d
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     16     0.43378226    -0.11025008 0n*D](/NK  
Change in Focus                :      -0.640081 I9*BTT]  
     17     0.39321881    -0.15081353 /-
Z}=  
Change in Focus                :       0.914906 U[W &D%'  
     18     0.20692530    -0.33710703 %{&,5|8  
Change in Focus                :       0.801607 -|
4 Oq  
     19     0.51374068    -0.03029165 KRb'kW  
Change in Focus                :       0.947293 a6\`r^@  
     20     0.38013374    -0.16389860 N."x@mV  
Change in Focus                :       0.667010 >Ft)v  
;Pe=cc"@  
Number of traceable Monte Carlo files generated: 20 4O
Fv#$[  
%BF,;(P  
Nominal     0.54403234 fw)Q1"|  
Best        0.54384387    Trial     2 hRZYvZ3  
Worst       0.18154684    Trial     4 "D'"uMS`H  
Mean        0.35770970 ji.T7wn1u  
Std Dev     0.11156454 C!)ZRuRv  
>35W{d  
JJy.)-R  
Compensator Statistics: /h9v'Y}c  
Change in back focus: 4`Lr^q}M+  
Minimum            :        -1.354815  w>\_d  
Maximum            :         1.611296 $N\k*=  
Mean               :         0.161872 `N8t2yF  
Standard Deviation :         0.869664 P|t2%:_  
fGoJP[ae  
90% >       0.20977951               ox5Wbo
L  
80% >       0.22748071               ~bsdy2&/q  
50% >       0.38667627               p4D.nB8  
20% >       0.46553746               ojc.ykP$  
10% >       0.50064115                U7HfDDh  
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End of Run. Ko0?c.l  
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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 `R!Q(rePx  

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 [9G=x[  
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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                 Uz~B`  
80% >       0.22748071                 TO.STK`  
50% >       0.38667627                 JI cm$  
20% >       0.46553746                 "U+c`V=w  
10% >       0.50064115 8!YQ9T[  
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最后这个数值是MTF值呢，还是MTF的公差？ ~!=Am:-wr  
#RbdQH !  
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？？？   ^4NRmlb  
{]dG 9  
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  : 5'+g[eNyBV  
90% >       0.20977951                 y9]7LETv\M  
80% >       0.22748071                 DBHHJD/q  
50% >       0.38667627                 0^Vw^]w  
20% >       0.46553746                 5+!yXkE^e  
10% >       0.50064115 Te~jYkCd  
....... rir,|y,  

Jk`Jv;  
wJJ|]^0.  
这些数值都是MTF值

Criterion           : Geometric MTF average S&T at 30.0000 cycles per mm   @ N'P?i  
Mode                : Sensitivities A{B$$7%  
Sampling            : 2 v(JjvN21  
Nominal Criterion   : 0.54403234 B*3_m _a  
Test Wavelength     : 0.6328 Ksh[I,+N\  
"
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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？ FMn|cO.vEP  
fM:bXR2Y'  
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