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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�mO#vT�X4 JA}�'d7yEa 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: h�K"=~��\, enableservice('AutomationServer', true) jy�sV%q 3� enableservice('AutomationServer') [�0L�qZ<\5  �aC�},�h�� 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。 h=t�u�+�pn c-T
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�aR 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: AN>`M?EQ�� 1. 在FRED脚本编辑界面找到参考. P�~<�9��3 2. 找到Matlab Automation Server Type Library CJ�Ol|"UyJ 3. 将名字改为MLAPP �##_Za6�/n StL�[\9�~: ) T��1�oDk 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。 �*�\�WI!%� �kn"�x[�{d 图 编辑/参考 ."X~��?N�k {|h�"�/�� 现在将脚本代码公布如下,此脚本执行如下几个步骤: "k�|`��xn� 1. 创建Matlab服务器。 h6e��$$�-_ 2. 移动探测面对于前一聚焦面的位置。 $te,\$&}�� 3. 在探测面追迹光线 ���EAB+�kY 4. 在探测面计算照度 l�nWi�E�}F 5. 使用PutWorkspaceData发送照度数据到Matlab F"H!CJ�Ju& 6. 使用PutFullMatrix发送标量场数据到Matlab中 ��w2+]C&B* 7. 用Matlab画出照度数据 aT�m.10�{^ 8. 在Matlab计算照度平均值 �j*u9+. � 9. 返回数据到FRED中 W~�F/ZrT3A ��\,�!q[nC 代码分享: SU'9+�=�_$ KaE�;4gw�M Option Explicit *`-29eR"8� �}�?J5!��X Sub Main BznA)EK�?@ y7-�:l u$9 Dim ana As T_ANALYSIS uW�~��,H}E Dim move As T_OPERATION �(VAL.v*�� Dim Matlab As MLApp.MLApp J_|}Xd)~t6 Dim detNode As Long, detSurfNode As Long, anaSurfNode As Long �8VmN?�"5v Dim raysUsed As Long, nXpx As Long, nYpx As Long t)Q�@sKT�6 Dim irrad() As Double, imagData() As Double, reals() As Double, imags() As Double !#I/b�e]�� Dim z As Double, xMin As Double, xMax As Double, yMin As Double, yMax As Double �U�_;J.�{n Dim meanVal As Variant �=k=��2~
j /VO@>�H�oh Set Matlab = CreateObject("Matlab.Application") �'?gI��cWM ��B��9Q.�s ClearOutputWindow &jZ�|@�K�? k3�[h�'.ps 'Find the node numbers for the entities being used. ]3�,.g)U*m detNode = FindFullName("Geometry.Screen") 9*+0j2uh�Q detSurfNode = FindFullName("Geometry.Screen.Surf 1") %D�ls36��F anaSurfNode = FindFullName("Analysis Surface(s).Analysis 1")
�z~e~�K`S @n��X2*j*u 'Load the properties of the analysis surface being used. w�LN2`u�cC LoadAnalysis anaSurfNode, ana ��ni�EEm`" -,A5^>}%,Y 'Move the detector custom element to the desired z position. \�e8��*vos z = 50 6q[�!X�0�u GetOperation detNode,1,move #K1BJ#KU�t move.Type = "Shift" �%
r��Y�8 move.val3 = z -f2`�qltjb SetOperation detNode,1,move 5�0GYL5�)q Print "New screen position, z = " &z ,e FQ}&^A UxcDDa/j2T 'Update the model and trace rays. ��9>�&tM�q EnableTextPrinting (False) �hAr[atu87 Update �@�D�u}
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DeleteRays EKd3$(�^�� TraceCreateDraw a!y,!EB+Qu EnableTextPrinting (True) V"by9p|V�` E'^]zW�=9� 'Calculate the irradiance for rays on the detector surface. :n4:�@L<%H raysUsed = Irradiance( detSurfNode, -1, ana, irrad ) h���@�,e`Z Print raysUsed & " rays were included in the irradiance calculation. zt[�4_;2Y ��XB�Q���< 'When using real number data to send to MATLAB, it is simplest to use PutWorkspaceData. e9`uD|KAS| Matlab.PutWorkspaceData("irradiance_pwd","base",irrad) �3h�XmYz�( �]6B�mC�h� 'PutFullMatrix is more useful when actually having complex data such as with )����ehB)X 'scalar wavefield, for example. Note that the scalarfield array in MATLAB 2WPF{�y%�/ 'is a complex valued array. .eabt�GO,� raysUsed = ScalarField ( detSurfNode, -1, ana, reals, imags ) [Ql?Y$QB`4 Matlab.PutFullMatrix("scalarfield","base", reals, imags ) %-�ZR~�*� Print raysUsed & " rays were included in the scalar field calculation." _�:g���GD8 'y6�!�%k�* 'Calculate plot characteristics from the T_ANALYSIS structure. This information is used /LI~�o~m1) 'to customize the plot figure. >�1r��[]&8 xMin = ana.posX+ana.AcellX*(ana.Amin-0.5) 9Z0CF~Y��5 xMax = ana.posX+ana.AcellX*(ana.Amax+0.5) 'lN*Ys iDi yMin = ana.posY+ana.BcellY*(ana.Bmin-0.5) 1t[;`���iZ yMax = ana.posY+ana.BcellY*(ana.Bmax+0.5) sUb�z)BS#. nXpx = ana.Amax-ana.Amin+1 C~KW��H��@ nYpx = ana.Bmax-ana.Bmin+1 �6A$_&�?�� ,%?; \?b%h 'Plot the data in Matlab with some parameters calculated from the T_ANALYSIS �&:DCtjK� 'structure. Set the axes labels, title, colorbar and plot view. ,_Qe�}q�FU Matlab.Execute( "figure; surf(linspace("&xMin &","&xMax &","&nXpx &"),linspace("& yMin &"," & yMax & "," & nYpx & "),irradiance_pwd, 'EdgeColor', 'None');" ) !�2X�r~u7a Matlab.Execute( "xlabel('X Position (" & GetUnits() & ")')" ) : Matlab.Execute( "ylabel('Y Position (" & GetUnits() & ")')" ) : Matlab.Execute( "zLabel( 'Irradiance' )" ) (~G�5�t(+� Matlab.Execute( "title('Detector Irradiance')" ) 2E�3?0DL", Matlab.Execute( "colorbar" ) [W9e>Nsp0 Matlab.Execute( "view(2)" ) K$�<`4#�i� Print "" S!jF:�Uc�� Print "Matlab figure plotted..." UA�x.Qq��� oEe�n�m\ZI 'Have Matlab calculate and return the mean value. 1 �;\]D9i� Matlab.Execute( "irrad = mean(mean(irradiance_pwd));" ) ���E/~"�j� Matlab.GetWorkspaceData( "irrad", "base", meanVal ) (�:?5 i` Print "The mean irradiance value calculated by Matlab is: " & meanVal +�~��w?Xw, ]_ejDN\>{V 'Release resources #QTfT&m+G} Set Matlab = Nothing rL%]S�&�M9 �FDF3zzP�0 End Sub g��[E�M]q, FJa[T�oZ4+ 最后在Matlab画图如下: bkr~1�3S{+ h�v�$uH7Fz 并在工作区保存了数据: S2rEy2\�}: �?iPZ�s��V  }u�F�[Ra��
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� 与FRED中计算的照度图对比: �q+A�<g(Xu %[]"�Qb�F? 例: dGbU{�#"3s �A�I�1��@- 此例系统数据,可按照此数据建立模型 [&h�#iTRT�
^&+zA,aL,A 系统数据 �u}K5�/hC�
'}j�f#C1$c �@J��b@��L 光源数据: �/d0Q�>v.g Type: Laser Beam(Gaussian 00 mode) I�aj�D;V�� Beam size: 5; ,wtFs!8�� Grid size: 12; �)XLj[6j0� Sample pts: 100; ?�^�%�YRB& 相干光; pN\)(:"�8v 波长0.5876微米, ��Gw��
~{V 距离原点沿着Z轴负方向25mm。 = EQN-{�#� �)K�SisE�L 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: .S~@BI(|<� enableservice('AutomationServer', true) j��0g�5�<M enableservice('AutomationServer') i\t753<�Ys
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