HFSS的后處理及場計算器的使用

1、4-1HFSS的后處理及的后處理及場計算器入門場計算器入門電子科技大學賈寶富4-2Ansoft HFSS的后處理（的后處理（Results） Create Report4-3可繪制圖形可繪制圖形 Eigenmode solution（本征模解）（本征模解）Eigenmode Parameters (modes)（本征模參數圖形）Driven Modal Solution（驅動模式解）（驅動模式解）S-parameters（S參數圖形）Y-parameters（Y參數圖形）Z-parameters（Z參數圖形）VSWR（駐波比） Gamma (complex propagation consta

2、nt)（復數形式的傳播常數）Port Zo（端口波阻抗）Driven Terminal Solution（終端驅動解）（終端驅動解）S-parameters（S參數圖形）Y-parameters（Y參數圖形）Z-parameters（Z參數圖形）VSWR（駐波比）Power（功率）Voltage Transform matrix (T)（電壓傳輸矩陣）Terminal Port Zo（端口波阻抗）4-4可繪制圖形可繪制圖形Fields(場)Mag_EMag_HMag_JvolMag_JsurfComplexMag_EComplexMag_HComplexMag_JvolComplexMag_J

3、surfLocal_SAR (Specific Absorption Rate)Average_SAR注：在繪制場圖前必須先選擇一個面或者一個多點線。 4-5Ansoft HFSS的后處理（的后處理（Results）Solution Data4-6Ansoft HFSS的后處理（的后處理（Results）Output Variables4-7Ansoft HFSS的后處理（的后處理（Fields）Fields4-84-9Ansoft HFSS的后處理（的后處理（Radiation）Radiation4-10What is Time Domain Reflectometry?Time Domai

4、n Reflectometry (TDR) measures the reflections that result from a signal travelling through a transmission environment of some kind a circuit board trace, a cable, a connector and so on. The TDR instrument sends a pulse through the medium and compares the reflections from the unknown transmission en

5、vironment to those produced by a standard impedance. 4-11The Reflection CoefficientTDR measurements are described in terms of a Reflection Coefficient, (rho). The coefficient r is the ratio of the reflected pulse amplitude to the incident pulse amplitude:4-124-13Calculating the Impedance of the Tran

6、smission Line and the Load4-14Short and open circuit terminations4-15Matched and mismatched load terminations4-16Capacitive and inductive load terminations4-17Capacitive and inductive discontinuities4-18Mixed capacitive and inductive loading4-19The TDR waveform reveals trace discontinuities4-20HFSS

7、Field Calculator: DefinitionA tool for performing mathematical operations on ALL saved field data in the modeled geometrynE,H,J, and Poynting data availablenPerform operations using drawing geometry or new geometry created in Post3nPerform operations at single frequency (interpolating or discrete sw

8、eeps) or other frequencies (fast sweep) nGenerate numerical , graphical, geometrical or exportable datanMacro-enabled 4-21表達式表達式操作區(qū)操作區(qū)指定數據指定數據關聯關聯場計算器場計算器操作區(qū)操作區(qū)場計算器分區(qū)4-22表達式操作區(qū)建立表達式建立表達式使用“Add”鍵，由場計算器堆棧導入表達式；使用“Load From”鍵，由場計算器表達式文件（*.clc）導入表達式；輸出表達式輸出表達式使用“Copy to stack”鍵，將已存在的表達式導出到場計算器堆棧；使用“Save

9、 to”鍵，將已存在的表達式保存成場計算器表達式文件（*.clc） ；4-23指定關聯區(qū)指定場計算器指定場計算器使用數據的出使用數據的出處。處。指定求解設置指定場類型；指定頻率指定相位4-24HFSS Field Calculator: Basic LayoutStack Operations:Button for manipulating stackData stack: Contains current and saved entries in a scrolling stack similar to a hand-held scientific caculator.Calculator

10、Functions:Orgnized groupings of all the avaliable calculator functions in button format. Some buttons contain further options as drop-down menusStatus Bar(not currently shown):4-25HFSS Field Caculator: Data TypesThe calculatiorv can manipulate many different types of datanGeometricnComplexnVectornSc

11、alarData types are indicated in the calculator stack for each entryMost calculator operations are only available on the appropriate data type(s)Geometric surface generated along E field iso-value contour Vector data output to a plane geometryScalar E-field data graphed along a line geometry4-26HFSS

12、Field Calculator: Data IndicatorsEach stack entry will be preceded by a unique code denoting its data typeMathematical:nCVc: Complex Vector nVec: VectornCSc: Complex ScalarnScl: ScalarGeometric:nPnt: PointnLin: LinenSrf: SourfacenVol: VolumeCombinations can also existnE.g. “SclSrf”: Scalar data dist

13、ributed on a Surface geometryCACULATOR USAGE HINT: Most data input types will be self-explanatory, e. g. E and H fields being phasor quantities will be Complex Vector (CVc). The only exception to this rule is the Poynting input, Which will show up as a “CVc” even though E X H* should have no imagina

14、ry component. The calculator only knows that two complex vector were crossed, and does not know ahead of time that the imaginary component has been zeroed.4-27HFSS Field Calculator: Detail Layout-StackAs data is entered into the calculator it appears at the TOP of the stack, pushing older entries DO

15、WNUNDO attempts to take back the last operation between stack enties. It may not work for all data types (e.g. the result of a pure math operation cannot be reversed)CLEAR deletes ALL entries from the stack upon confirmationEXCH exchanges or swaps the top two stack entriesPUSH duplicates the top sta

16、ck entryPOP deletes the top entry off the stackRLDN “rolls” the stack downward, moving the top entry to the bottomRLUP “rolls” the stack upward, moving the bottom entry to the top4-28HFSS Field Calculator: Detail Layout-OperationsSCALAR column operations can only be performed on Scalar data (not com

17、plex or vector data), such as finding the Cosine of a value using the trig functions. OUTPUT column operations result in the generation of calculator outputs, in either numerical, graphical (displayed as 2D graphs or in the 3Dview), or exported form.VECTOR column contains operations to be performed

18、on vector data such as converting to scalar, Dot and Cross products,and Unit Vector computationsGENERAL column contains operations which can be performed on many data types (e. g. adding scalar values or adding vectors)INPUT column contain all operations which input new data into the stack (field da

19、ta, constant, user-entered vector or complex numbers, etc.All calculator operations are orgnized into columns classifyying them by the type of operation and the type of the data upon which the operation can be performed.4-29HFSS Field Calculator: Detail Layout-Exploded View4-30HFSS Field Calculator:

20、 Usage-OverviewUse just like a scientific calculatorSimilar to HP scientific calculatorsn“First Quantity”, ”Second Quantity” Then “Operation”Remember stack fills from the Top and pushes older contents below.General use progresses from left to rightInput quantity or quantities at leftPerform operatio

21、ns in middlenOperate between quantities; apply quantities to geometries, etc.Define desired output type at right.Calculator Usage HINT: Any Time you use the field post processor to plot a quantity (PlotFields), you are actually performing operations using the calculator! To see the steps that went i

22、nto the generating the plot you just created, open the calculator interface and view the stack contents. This can often help guide you as you try to use the calculator to created your own custom outputs. 4-31HFSS Field Calculator: Usage-Changing Data TypesAs discussed previously, Many operations mus

23、t be on the correct data type.Many operations result in a different data type than the inputs.Ex1:The Dot product of two Vector is a Scalar.Ex2:Obtaining the Unit VecNormal to a Surf Generates a Vector.Some calculator buttons exist primarily to assist in type conversion.Vec? Converts Scl to Vec data

24、Scal? Does the reverseCmplxReal or CmplxImag takes a Scl component from a CSc or CVc.CmplxCmplxR or CmplxCmplxI take a Vec or Scl component and make it the real or imaginary part of a complex value CVc or CSc, respectively.Always think of what type of data you are working with and whether or not it

25、is compatible with your desired operation .For example, not the INTEGRAL sign is in the Scalar column, implying that to integrate complex numbers you will have to integrate the real and imaginary components separately, performing an integration by parts. 4-32HFSS Field Calculator: Usage-Input TypesT

26、he available field inputs areE: The complex vector E field data everywhere in the modeled geometry;H: The complex vector H field data everywhere in the modeled geometry;Poynting: The time-average Poynting vector computed from above as (EH*):Jvol: Current density in a volume, computed as (+j”)E which

27、 contain both conduction and displacement current ;Jsurf: Net surface current computed as n(H|top tetrahedra- H|bottom tetrahedra):Unlike other quantities, Jsurf can only be output on an object surface geometry.EHJsurfJvolPoyntingE and H are Peak Phasor representation of the steady state fields. The

28、refore the current representation J derived from nH or E are also peak phasor quantities. The Poynting Vector input is a time-averaged quantity.4-33HFSS Field Calculator: Usage-Output TypesDifferent data output can be generated depending on selected Output column button and stack content(s):Value is

29、 used to take the “value” of a field stack entry on a specific geometry;Eval turn stack placeholder text into final numerical answer;Write and Export outputs stack data to output file formats for use outside the calculator or current project.4-34HFSS Field Calculator: Usage-Possible OperationsAs lon

30、g as you can perform the math using the interface, there is no restriction on the possible calculator operations available:Outputs derived can be other than “Electromagnetic” in nature;nPure Geometric operations (vector and surface cross and dot products, generation of iso-surface contours from any scalar data field imported into the geometry, etc)nThermal heating computations derived from field values combined with thermal mass characteristics and equations;nIntegrations to obtain