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简介:FRED作为COM组件可以实现与Excel、VB、Matlab等调用来完成庞大的计算任务或画图,本文的目的是通过运行一个案例来实现与Matlab的相互调用,在此我们需要借助脚本来完成,此脚本为视为通用型脚本。 #2*l"3.$.R 5u�/d��r9n 配置:在执行调用之前,我们需要在Matlab命令行窗口输入如下命令: l%��vX$K�w enableservice('AutomationServer', true) ��tC;L�A 4 enableservice('AutomationServer') �-Jqm�0�)2  Gn*�cp�h�b 结果输出为1,这种操作方式保证了当前的Matlab实体可以用于通信。 m�|K"I3�W$ B4tC���3r� 在winwrp界面,为增加和使用Matlab类型的目录库,我们需要如下步骤: h"~i&T��
h 1. 在FRED脚本编辑界面找到参考. ����MW^(� 2. 找到Matlab Automation Server Type Library yT[CC�>]l 3. 将名字改为MLAPP 9f UD68Nob Q]44A+�M�] Q�a�AA�@l� 在Matlab里面有两种常用的数据发送选项PutWorkspaceData 及PutFullMatrix,PutWorkspaceData适用于存储一般的数据在工作区,并赋予其为变量,PutFullMatrix试用于复数数据。 ;/ wl.�'GA ��s
&4k��� 图 编辑/参考 #vwK��6'z� 54�[#&T$S 现在将脚本代码公布如下,此脚本执行如下几个步骤: �qp#Is�{=m 1. 创建Matlab服务器。 Uc>ki��WW� 2. 移动探测面对于前一聚焦面的位置。 �#&�v��8�6 3. 在探测面追迹光线 i}�&�&�rr 4. 在探测面计算照度 ibzcO,c� 5. 使用PutWorkspaceData发送照度数据到Matlab �%"<|u�)E 6. 使用PutFullMatrix发送标量场数据到Matlab中 _*&��I[%I5 7. 用Matlab画出照度数据 p\;\�hHa�i 8. 在Matlab计算照度平均值 #}M\ J0Q�G 9. 返回数据到FRED中 }%�8 :8_Ke u{|
Q[h�f[ 代码分享: F�~bD�A~�� pm��2��-F] Option Explicit HgGw�V;�W� ?�<F��=*eS Sub Main I{bD�a'rX� �$,�Eb�(�j Dim ana As T_ANALYSIS ^$F�Nu~�|K Dim move As T_OPERATION 0H$6_YX4�A Dim Matlab As MLApp.MLApp 7Sha�u%2�C Dim detNode As Long, detSurfNode As Long, anaSurfNode As Long PpXzWWU�": Dim raysUsed As Long, nXpx As Long, nYpx As Long %fbV\@jDCX Dim irrad() As Double, imagData() As Double, reals() As Double, imags() As Double `!Z0�;�qk� Dim z As Double, xMin As Double, xMax As Double, yMin As Double, yMax As Double �P}`|8b�1W Dim meanVal As Variant IOfxx�>�=3 �$o�l]G�`+ Set Matlab = CreateObject("Matlab.Application") 5ta�R�[ukM `Wl_yC_*G; ClearOutputWindow G_�m�$?0�\ H��bI�'n,+ 'Find the node numbers for the entities being used.
saRY�d{%+ detNode = FindFullName("Geometry.Screen") /b�1�+ ^|_ detSurfNode = FindFullName("Geometry.Screen.Surf 1") �us5<18�M5 anaSurfNode = FindFullName("Analysis Surface(s).Analysis 1") Ie<H4�G5Vh ��V),�wDyi 'Load the properties of the analysis surface being used. G�yC/�39<P LoadAnalysis anaSurfNode, ana �kk`K)PESi '2S/�FO��b 'Move the detector custom element to the desired z position. =,B�Dd��$e z = 50 ]KQ�v�]�' GetOperation detNode,1,move cp:�U@Nh( move.Type = "Shift" lG�lh/�B�% move.val3 = z k~0#Iy_{M SetOperation detNode,1,move �o�5�@d�1A Print "New screen position, z = " &z ��_ez*dE% b�I�-uF8�" 'Update the model and trace rays. Ao )\�/AR' EnableTextPrinting (False) o&t*[����# Update &%U�Z"CcA� DeleteRays q"�48U.�}T TraceCreateDraw A�=Y �A�#0 EnableTextPrinting (True) |Q(3rcOrV" ��4�-C�Ge 'Calculate the irradiance for rays on the detector surface. cMf�Jq}C<� raysUsed = Irradiance( detSurfNode, -1, ana, irrad ) } =�p� e;l Print raysUsed & " rays were included in the irradiance calculation. G�$^u2wz.� 9bQD"%ha=d 'When using real number data to send to MATLAB, it is simplest to use PutWorkspaceData. &wX5��68o� Matlab.PutWorkspaceData("irradiance_pwd","base",irrad) %A�3ci[$�g ynZ�p|'b?< 'PutFullMatrix is more useful when actually having complex data such as with p
uZY4}b_� 'scalar wavefield, for example. Note that the scalarfield array in MATLAB q�E��vbKy} 'is a complex valued array. �4C#r�=Uw` raysUsed = ScalarField ( detSurfNode, -1, ana, reals, imags ) |2Y�/�l~� Matlab.PutFullMatrix("scalarfield","base", reals, imags ) aD&4C��-,1 Print raysUsed & " rays were included in the scalar field calculation." 6Y%{ YQ}s| cq`!17�"k 'Calculate plot characteristics from the T_ANALYSIS structure. This information is used Al3��*? H& 'to customize the plot figure. �3Q�#�Tu�t xMin = ana.posX+ana.AcellX*(ana.Amin-0.5) [$�DI!%e|� xMax = ana.posX+ana.AcellX*(ana.Amax+0.5) "�C�.�c��U yMin = ana.posY+ana.BcellY*(ana.Bmin-0.5) S"c�im\9xP yMax = ana.posY+ana.BcellY*(ana.Bmax+0.5) }I�p�1�|Gj nXpx = ana.Amax-ana.Amin+1 � nb�\pB�l nYpx = ana.Bmax-ana.Bmin+1 ��F-�X��L� TFN��B��%| 'Plot the data in Matlab with some parameters calculated from the T_ANALYSIS 7�Y�%�S�i5 'structure. Set the axes labels, title, colorbar and plot view. =E$B0^_2RC Matlab.Execute( "figure; surf(linspace("&xMin &","&xMax &","&nXpx &"),linspace("& yMin &"," & yMax & "," & nYpx & "),irradiance_pwd, 'EdgeColor', 'None');" ) 2M�>`�W�5 Matlab.Execute( "xlabel('X Position (" & GetUnits() & ")')" ) : Matlab.Execute( "ylabel('Y Position (" & GetUnits() & ")')" ) : Matlab.Execute( "zLabel( 'Irradiance' )" ) +��MtxS l� Matlab.Execute( "title('Detector Irradiance')" ) dC/@OV)0#� Matlab.Execute( "colorbar" ) OJ1MV��7&� Matlab.Execute( "view(2)" ) �RhWW61!"� Print "" arc�{�:u.K Print "Matlab figure plotted..." m@y�<wk�(
��`J$7�X�� 'Have Matlab calculate and return the mean value. ��cX#U_U~d Matlab.Execute( "irrad = mean(mean(irradiance_pwd));" ) sd _DG8V Matlab.GetWorkspaceData( "irrad", "base", meanVal ) ��� \�62!{ Print "The mean irradiance value calculated by Matlab is: " & meanVal $!vK#8-�&{ �1d�!T�U=* 'Release resources J)EL<K�$Z[ Set Matlab = Nothing 7l�x]`�u> ��'-BD.^!! End Sub �3>6r�O4,� 4iv&!hAc;� 最后在Matlab画图如下: �#0:rBK�m, b�(Yx�sy{U 并在工作区保存了数据: ��Yw6uh4�� n= q7*��<l  R:`�)*=rL%
z~th{4#E�; 与FRED中计算的照度图对比: @Hl+]arU�h 1pz�-jo,2' 例: �&
h\!#X0� 2Z-QVwa*U
此例系统数据,可按照此数据建立模型 �61}e�B/;7
i�!*�8@:VI 系统数据 c5�Hyja�=
+*IR�I/KUD �3�TRG] �5 光源数据: �B%WkM\\!^ Type: Laser Beam(Gaussian 00 mode) T0@$6&b%\z Beam size: 5; D?G'1+RIT~ Grid size: 12; ��^��vJ�y< Sample pts: 100; |z�J2ZE��| 相干光; BZ,{gy7g7X 波长0.5876微米, :_h#A�}8Xd 距离原点沿着Z轴负方向25mm。 3a'#Z�4�Z- ?�p�h>:�M� 对于执行代码,如果想保存图片,请在开始之前一定要执行如下代码: 1/v��#Z#3[ enableservice('AutomationServer', true) 3p��e1"maP enableservice('AutomationServer') l����V9���
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