| infotek |
2022-01-24 09:30 |
十字元件热成像分析
简介:本文是以十字元件为背景光源,经过一个透镜元件成像在探测器上,并显示其热成像图。 :uB(PeAv* y1#*c$ O
成像示意图 O PJ(ub 首先我们建立十字元件命名为Target F!zGk(Pu $%.,=~W7 创建方法: .Z(Q7j^ NS){D7T 面1 : =F/ EzS 面型:plane 349BQ5ND 材料:Air <6.?:Jj 孔径:X=1.5, Y=6,Z=0.075,形状选择Box IubzHf =+w/t9I[
"1%\Fi l 辅助数据: FXh*!%"* 首先在第一行输入temperature :300K, OXS.CFZM emissivity:0.1; w}0rDWuR[ 3hfv^H $J =`fx 面2 :
3 EOuJ 面型:plane 2?kVbF 材料:Air -FQc_k?VF 孔径:X=1.5, Y=6,Z=0.075,形状选择Box ;^cMP1SH O:Wd
,3_ 2Ws'3Jz 位置坐标:绕Z轴旋转90度, X/FR e[R uTNy{RBD+
dpcU`$kt 辅助数据: X3HJ3F;== Uj^Y\w-@Z 首先在第一行输入temperature :300K,emissivity: 0.1; %e+{wU}w?2 py$i{v% ]-jaIvM Target 元件距离坐标原点-161mm; B/dJj# y(X^wC
)!=fy'] 单透镜参数设定:F=100, bend=0, 位置位于坐标原点 A`1-c ;i!$rL y=zs6HaS 探测器参数设定: <SiJA`(7 Sobp;OZ5 在菜单栏中选择Create/Element Primitive /plane 3j2d&*0 SK5__Ix
(5kL6d2 q+ka}@ F]cc?r312 kH?PEA! \ 元件半径为20mm*20,mm,距离坐标原点200mm。 FpZ5@ wlpcuz@ 光源创建: .J?RaH{i 7pM&))R 光源类型选择为任意平面,光源半角设定为15度。 ^ #3,*(S :=\`P Ct]? / 我们将光源设定在探测器位置上,具体的原理解释请见本章第二部分。 7-mo\jw< $]MOAj"LH 我们在位置选项又设定一行的目的是通过脚本自动控制光源在探测器平面不同划分区域内不同位置处追迹光线。
j]m|}n ~*L@|? \~.elKw<U 功率数值设定为:P=sin2(theta) theta为光源半角15度。我们为什么要这么设定,在第二部分会给出详细的公式推导。 YGhHIziI U["IXR# 创建分析面: ([]\7}+8 40$9./fe) wrVR[v>E< 到这里元件参数设定完成,现在我们设定元件的光学属性,在前面我们分别对第一和第二面设定的温度和发射系数,散射属性我们设定为黑朗伯,4%的散射。并分别赋予到面一和面二。 6>b'g
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i}@5<&J 到此,所有的光学结构和属性设定完成,通过光线追迹我们可以查看光线是否可以穿过元件。 ceAefKdb W=4|ahk$ FRED在探测器上穿过多个像素点迭代来创建热图 `[~LMV&2U r@ba1*y0 FRED具有一个内置的可编译的Basic脚本语言。从Visual Basic脚本语言里,几乎所有用户图形界面(GUI)命令是可用这里的。FRED同样具有自动的客户端和服务器能力,它可以被调用和并调用其他可启动程序,如Excel。因此可以在探测器像素点上定义多个离轴光源,及在FRED Basic脚本语言里的For Next loops语句沿着探测器像素点向上和向下扫描来反向追迹光线,这样可以使用三维图表查看器(Tools/Open plot files in 3D chart)调用和查看数据。 &Qt1~#1 将如下的代码放置在树形文件夹 Embedded Scripts, (, $Lp0mB7 ZVz*1]}
w[J.?v&^ 打开后清空里面的内容,此脚本为通用脚本适用于一切可热成像的应用。 7eG@)5Uy Tvw(Sq}; 绿色字体为说明文字, |UN#utw{^Y }3R:7N`,| '#Language "WWB-COM" l#a*w 'script for calculating thermal image map *-gmWATC6 'edited rnp 4 november 2005 Y{L|ja%9? =6BI[_0 'declarations d4o_/[ Dim op As T_OPERATION sNJ?Z"5k1h Dim trm As T_TRIMVOLUME JB HnJm Dim irrad(32,32) As Double 'make consistent with sampling d{DBG}/Yg Dim temp As Double \{1Vjo Dim emiss As Double !={QL : Dim fname As String, fullfilepath As String Ps~)l#gue ^@]yiED{g 'Option Explicit hcQv!!Q"k$ SpZmwa #\ Sub Main 94.M8 'USER INPUTS BF
U#FE)s nx = 31 >k(AQW5? ny = 31 D 66!C{ numRays = 1000 P>
~Lx minWave = 7 'microns I2C1mV maxWave = 11 'microns ,J'@e+jV sigma = 5.67e-14 'watts/mm^2/deg k^4 e_Q(l'f fname = "teapotimage.dat"
DIh[% 0!`!I0 Print "" Xa[lX8$zL Print "THERMAL IMAGE CALCULATION" g'V,K\TG !}HT&N8[r detnode = FindFullName( "Geometry.Detector.Surface" ) '找到探测器平面节点 l%7^'nDn c1StA Print "found detector array at node " & detnode < !]7Gt ~T&X#i srcnode = FindFullName( "Optical Sources.Source 1" ) '找到光源节点 KQ.cd]6 NjSjE_S2B8 Print "found differential detector area at node " & srcnode (rSBzM]H jce2lXMm GetTrimVolume detnode, trm b!g8NG detx = trm.xSemiApe
="]y^&(L( dety = trm.ySemiApe :N>s#{+"3 area = 4 * detx * dety a4N8zDS Print "detector array semiaperture dimensions are " & detx & " by " & dety ]yA_N>k2K Print "sampling is " & nx & " by " & ny .?.Q[ic YQ5d!a. 'reset differential detector area dimensions to be consistent with sampling sg,9{R ^ pixelx = 2 * detx / nx S;S_<GX pixely = 2 * dety / ny U6oab9C?k SetSourcePosGridRandom srcnode, pixelx / 2, pixely / 2, numRays, False CB?,[#r5f Print "resetting source dimensions to " & pixelx / 2 & " by " & pixely / 2 j(\jYH> ~kPZh1n` 'reset the source power Y--Uo|H SetSourcePower( srcnode, Sin(DegToRad(15))^2 ) P3V}cGZ Print "resetting the source power to " & GetSourcePower( srcnode ) & " units" L@6T~ c (0Ez@ 'zero out irradiance array wGnFDkCNz For i = 0 To ny - 1 WK 6|e[iP For j = 0 To nx - 1 5K?%Eo72!= irrad(i,j) = 0.0 84maX' Next j 1(WNrVm; Next i @KC;"u'C Q
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'main loop aD8r:S\ EnableTextPrinting( False ) Fv9n>%W& I ?i,21:5 ypos = dety + pixely / 2 C@s;0-qL For i = 0 To ny - 1 Hf$LWPL)lM xpos = -detx - pixelx / 2 yS(tF`H[ ypos = ypos - pixely yn-TN_/Y, JD$;6Jv3P EnableTextPrinting( True ) _M7NL^B& Print i 5*7
\Yjk? EnableTextPrinting( False ) <3c|S_|L*m 9`sIE _%+ UI.>BZ6} For j = 0 To nx - 1 *Ldno`1O :0B'
b xpos = xpos + pixelx
XvspE}~y .\+%Q)?h: 'shift source >vY5%%} LockOperationUpdates srcnode, True ZtqN8$[6n GetOperation srcnode, 1, op >pn5nn1a op.val1 = xpos 6)~J5Fb op.val2 = ypos ;p 'Ej'E SetOperation srcnode, 1, op @^kt[$X; LockOperationUpdates srcnode, False $N)b6(}F10 +cnBEv~y raytrace tB7g.)yZb DeleteRays knJoVo] CreateSource srcnode [boB4>. TraceExisting 'draw ~!{y3thZ :IlJQ{=W 'radiometry 7cJh^M For k = 0 To GetEntityCount()-1 =HkB>w)h If IsSurface( k ) Then 9n[ovX 7n! temp = AuxDataGetData( k, "temperature" ) E<XrXxS1O emiss = AuxDataGetData( k, "emissivity" ) /xcl0oe( If ( temp <> 0 And emiss <> 0 ) Then n:wZL&ZV0 ProjSolidAngleByPi = GetSurfIncidentPower( k ) /{d5$(Y" frac = BlackBodyFractionalEnergy ( minWave, maxWave, temp ) <i!7f26r irrad(i,j) = irrad(i,j) + frac * emiss * sigma * temp^4 * ProjSolidAngleByPi h\i>4^]X. End If !%4&O ESAFsJ$r;
End If 1WW`% B#U:6Ty Next k -<tfbaA O}IRM|r" Next j NYcF]K}[ I,xV&j+< Next i MKN],l
N EnableTextPrinting( True ) <^(g<B`> eDPmUlC+- 'write out file {g(-C& fullfilepath = CurDir() & "\" & fname I6E!$} Open fullfilepath For Output As #1 Mli`[8@( Print #1, "GRID " & nx & " " & ny %>G(2)Fb\\ Print #1, "1e+308" JxM[LvVi Print #1, pixelx & " " & pixely gP?uLnzvi Print #1, -detx+pixelx/2 & " " & -dety+pixely/2 !:^lTvYWZH b];p/V#
< maxRow = nx - 1 b:w {7 maxCol = ny - 1 otgU6S7F For rowNum = 0 To maxRow ' begin loop over rows (constant X) CUR70[pB) row = "" PHh&@: For colNum = maxCol To 0 Step -1 ' begin loop over columns (constant Y) "2'pS<| row = row & irrad(colNum,rowNum) & " " ' append column data to row string Tn7(A^h' Next colNum ' end loop over columns (;@\gRL xiW;Y{kZ Print #1, row a!US:^}lu 'sCj|=y2Qc Next rowNum ' end loop over rows ZRd,V~iz Close #1 Y@Zv52, &m>sGCZ Print "File written: " & fullfilepath VTt{0 ~ Print "All done!!" +w ]KK6 End Sub
jo_wBJKE *=X$j~#X 在输出报告中,我们会看到脚本对光源的孔径和功率做了修改,并最终经过31次迭代,将所有的热成像数据以dat的格式放置于: xC,;IS k, =#"ZO _26<}&]b* 找到Tools工具,点击Open plot files in 3D chart并找到该文件 TEK]$%2 1[;~>t@C 7:D@6<J? 打开后,选择二维平面图: +W6QtB6 C;6Nu W
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