Set lock-in amplifier parameters:
</p>
<ulol type="a">
<li>
<p>
Select the Lock-in Amplifiers for each channel using the Lock-in Amplifier Selector and set their corresponding parameters.
</p>
</p>
</li>
</ulol>
â
Other parameters that should be directly set on SR844 RF lock-in amplifier â since they are not controlled (see Figure 3.13 in section 3.2.2):
</li>
</ul>
</li>
<li>
To set translation stage speed settings:
<ol type="a">
<li>
<p>
From âVisa COMâ serial port drop-down list select the COM port that the X Linear Translation Stage is connected to. A COM port is a specific serial connection on a computer, such as COM3.
</p>
</li>
<li>
<p>
Set the speeds of translation stage from âTranslation Speedâ box (Figure 4.5). The default value is 10 mm/s â indicating that translation stage can move 10 mm per second.
</p>
</li>
<li>
<p>
Press âSet Speedâ button to save the new settings. The system will respond with confirmation message âSet Speed OKâ in information panel.
The Scan Speed is ~ 0.3 mm/s.
</p>
</li>
<li>
<p>
When translation stages power up, they need to be homed in order to get an accurate reference position. The home sensor is at the motor end of the stage. Press âHome Positionâ button.
</p>
</li>
</ol>
<li>
In order to displace translation stage to a defined position along X-axis, enter the appropriate X coordinate in the X Position Setting Entry Box and then press âMove along Xâ button as shown in Figure 4.6. Similarly, enter the appropriate Y coordinate in the Y Position Setting Entry Box and then press âMove along Yâ button to move to the defined position (see Appendix A-I for more details).
</li><li><p>
Use âSet Originâ button to define the starting point of the scanning area (Figure. 4.6). See Appendix A-I for more details.
</p></li><li><p>
To go to the origin, press âMove to Originâ button.
</p>
</li>
</ol>
<center>[[Image:neoscanfig_4_6.png|thumb|center|600px|<i><b>Figure 4.6</b>: HSetting X and Y position of translation stage (left), and setting the origin (right) in NeoScan Mapping Utility program.</i>]]</center>
==== Height Settings Page ====
Set the probe height â the distance between the probe and the DUT surface â using the knob (Figure 4.7). If you are interested in high resolution scanning, you may skip the other parameters, which will be discussed later in the chapter on Far Field Measurements.
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<center>[[Image:neoscanfig_4_7.png|thumb|center|600px|<i><b>Figure 4.7</b>: NeoScan Mapping Utility program: Probe Height Settings Page.</i>]]</center>
==== Scan Settings Page ====
In order to scan the distribution of electric field on a DUT, three parameters are needed to be known:
<ul><li><p> Dimensions of the probed (scanned) area in X and Y directions (D_PXD<sub>PX</sub>, D_PYD<sub>PY</sub>);</p></li><li><p>
The step size âX and âY that represents the spacing between points along X-axis and Y-axis, respectively;
</p>
</li>
<li>
<p>
Probe height or the distance of the probe to the DUT surface.
</p>
</li>
</ul>
To be more precise, one needs N_(N<sub>x )ï´ N_y </sub> x N<sub>y</sub> points to scan the whole area, where N_x=D_XPD<sub>XP</sub>/âX and N_Y=D_YPD<sub>YP</sub>/âY. For instance, 4624 points (68 ï´ x 68) are needed in order to scan a 34 mm ï´ x 34 mm Patch Antenna with resolution of 0.5 mm (500 μm). The effects of the Step Size (scan resolution) and Probe Height on the 2D Amplitude near field maps for 2.349 GHz Patch Antenna are shown in Figure 4.8. <center>[[Image:neoscanfig_4_8.png|thumb|center|530px|<i><b>Figure 4.8</b>: The effects of the Step Size (scan resolution) and Probe Height on the 2D Amplitude near field maps for 2.349 GHz Patch Antenna.</i>]]</center>
To set scan parameters, press âScan Settingsâ tab in [[NeoScan]] Mapping Utility program (Figure 4.9).
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<center>[[Image:neoscanfig_4_9.png|thumb|center|600px|<i><b>Figure 4.9</b>: NeoScan Mapping Utility program: Scan Settings Tab.</i>]]</center>
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<ol>
<li>
<p>
Switch ON mode enable the user to scan the three channels simultaneously using a single Lock-in Amplifier.
</p>
</li>
<li>
<p>
Select the channel(s) you want to scan by checking the check boxes (Figure 4.10).
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<center>[[Image:neoscanfig_4_10.png|thumb|center|600px|<i><b>Figure 4.10</b>: Setting Scan Parameters in Scan Settings Tab.</i>]]</center>
</p>
</li>
<li>
<p>
Use the Data Label text boxes to choose a name of the files the data to be written. By default the program automatically reads the current working channel. âInformationâ editor enables a user to add a text on the data file header.
</p>
Â
<ul>
<li>
<p>
The Data Label should have a maximum of 25 characters. Do not use âEmpty Spaceâ or any of the following characters: ` ! @ " # $ % ^ & * ( ) + = \ | / { } [ ] , > < : ; ?. Note that it is allowed to use âdotâ in project name.
</p></li></ul>Â </li><li><p> Enter the number of points you want to scan in X and Y direction in entry boxes labeled âNo. Point Xâ and âNo. Point Y,â respectively (Figure 4.10).</p></li><li><p>
Set the step size in each direction in entry boxes labeled âStep Size Xâ and âStep Size Y,â respectively. These values are in mm.
</p>
</li>
<li>
<p>
Select âWhat Axis to Scan First?â By default the program start scanning Y-axis first. In either case the scan data is written in a file in the same format, see Figure 4.11.
 <center>[[Image:neoscanfig_4_11.png|thumb|center|450px|<i><b>Figure 4.11</b>: Setting directions of scan using âWhat Axis to Scan First?â.</i>]]</center></p> <ul><li><p> The information panel will display the total number of points that has to be scanned (N_x ï´ N_xN<sub>x</sub> x N<sub>y</sub>) in the box labeled âTotal No. of Pointsâ.</p></li><li><p>
The program will also calculate the âSingle Move Timeâ for each scan point (without delay) and displays the âEstimated Scan Timeâ.
</p>
</li>
<li>
<p>
The user can control the dwell time from âDwell Controlâ key (Figure 4.12). The Dwell Time is the amount of time spent recording the signal for one data point for a channel before moving to the next point. By default, âDwell Controlâ key is set to âAutoâ. This introduces few msec dwell time during the scan. To change the dwell time, select the âManualâ option from âDwell Controlâ button and enter the desired value in box labeled âManual Move Timeâ in âManual Move Settingâ section (Figure 4.12). You can view the new âEstimated Scan Timeâ by pressing the âUpdate Scan Timeâ button.
â</p>â</li></ul>
<center>[[Image:neoscanfig_4_12.png|thumb|center|600px|<i><b>Figure 4.12</b>: Manual Move Settings in Scan Settings Tab.</i>]]</center>
</li></ol>â ==== Scan Control Page====
It is assumed that the scan parameters are set and the scan measurement setup has been setup. In order to start the scan, press âScan Controlâ tab in [[NeoScan]] Mapping Utility program (Figure 4.13).
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<center>[[Image:neoscanfig_4_13.png|thumb|center|600px|<i><b>Figure 4.13</b>: Scan Control Tap in NeoScan Mapping Utility Program.</i>]]</center>
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<ol>
<li>
<p>
Press âStart Scanâ button to start the scan.
</p>
</li>
<li>
<p>
The program displays 2D Amplitude and 2D phase contour plots of the measured amplitude and phase during the scan, as shown in Figure 4.14. Graphs are rescaled continuously during the scan. This enables the users to monitor the status of the scan. For instance, any sudden change or any instrumental failure can appears as anomalous pattern in either 2D plots.
</p>
</li>
<li>
<p>
The âPause Scanâ and âStop Scanâ buttons control the scan process. During scanning, use âPause Scanâ to pause temporarily the scanning. Pressing the âStop Scanâ button during scanning, will stop the scanning process.
</p>
</li>
<li>
<p>
The âPlot Display?â key allows a user to display 2D Amplitude graph in dBm or μV unit. Similarly, âCurrent Signalâ and âCurrent phaseâ in information panel present the lock-in amplifier current readings during the scan (Figure 4.15).
</p>
<center>
[[Image:neoscanfig_4_14.png|thumb|center|600px|<i><b>Figure 4.14</b>: 2D Amplitude (in dBm unit) and 2D phase contour plots of the measured amplitude and phase during the scan.</i>]]
<br>
[[Image:neoscanfig_4_15.png|thumb|center|600px|<i><b>Figure 4.15</b>: 2D Amplitude (in μV unit) and 2D phase contour plots of the measured amplitude and phase during the scan.</i>]]
</center>
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<ul>
<li>
<p>
A user can check the âElapsed Scan Timeâ and view the current X and Y position of the probe from the information panel (see Figure 4.16).
</p>
</li>
<li>
<p>
During the scan, there is no access to other tabs or pages in [[NeoScan]] Mapping Utility program.
</p>
</li>
<li>
<p>
When a signal falls below -150 dBm, a warning message appear in Information Panel indicates that âDetected a signal < -150 dBm in Ch 1 -- much below the noise level.â You may check the data later.
</p>
</li>
</ul>
</li>
</ol>
â During The âStopâ button stops the application. To close (kill) the scan, there is no access to other tabs or pages in [[NeoScan]] Mapping Utility window click on exit button [[Image:icon_Exit.png]] on the top far right in the LabView user interface. To re-start running the programpress the start button [[Image:icon_Start.png]] located on the top left in the LabView window, see Figures 4.5 and 4.16.
When a signal falls below -150 dBm, a warning message appear in Information Panel indicates that âDetected a signal < -150 dBm in Ch 1 -- much below the noise levelcenter>[[Image:neoscanfig_4_16.â You may check the data laterpng|thumb|center|600px|<i><b>Figure 4.16</b>: A completed scan of a Patch Antenna by NeoScan system.</i>]]</center>
The âStopâ button stops the application. To close (kill) the [[NeoScan]] window click on exit button on the top far right in the LabView user interface. To re-start running the program press the start button located on the top left in the LabView window, see Figures 4.5 and 4.16.4.3 === The [[NeoScan]] Scan Data===
During each scan, both the magnitude and the phase of a particular electric field component at a plane are measured. When the scan is completed, data are written in .DAT files in your defined (created) project folder, say âpatch_2.349GHz,â in the parent folder, i.e.
During a scan, data is collected and immediately displayed by [[NeoScan]] Mapping Utility program. However, data will be written into the files at the end of the scan.
<center>[[Image:neoscanfig_4_17.png|thumb|center|600px|<i><b>Figure 4.17</b>: Contents of data file E_X_Dir.DAT in patch_2.349GHz folder</i>]]</center>
â
== [[NeoScan]] Visualization Utility ==
During each scan, both the magnitude and the phase of a particular electric field component at a plane are measured. Measured data can easily be interpreted and understood when displayed as 2D or 3D graphs. Visualization of the [[NeoScan]] scan data are realized by LabVIEW based programs. It plots the amplitude and the phase of the measured field distribution on a horizontal plane after the scan. [[NeoScan]] Visualization Utility includes three pages: Settings, Near Field Maps, and Far Field Patterns.
[[Image:icon_Plot.png|right]] Open the [[NeoScan]] Visualization Utility program from Desktop or Windows Explorer by double clicking on the NeoScanVisual icon [[Image:icon_Plot_small.png]]. By default, [[NeoScan]] Visualization Utility program opens up with âSettingsâ page (Figure 5.1).
<center>[[Image:neoscanfig_5_1.png|thumb|center|600px|<i><b>Figure 5.1</b>: NeoScan Visualizarion Utility Program.</i>]]</center>
==== Settings Page ====
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Â
Â
Â
Â
Â
Â
Â
Â
Â
Â
Â
Â
Â
Â
â
[[NeoScan]] Visualization Utility
During each scan, both the magnitude and the phase of a particular electric field component at a plane are measured. Measured data can easily be interpreted and understood when displayed as 2D or 3D graphs. Visualization of the [[NeoScan]] scan data are realized by LabVIEW based programs. It plots the amplitude and the phase of the measured field distribution on a horizontal plane after the scan. [[NeoScan]] Visualization Utility includes three pages: Settings, Near Field Maps, and Far Field Patterns.
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Open the [[NeoScan]] Visualization Utility program from Desktop or Windows Explorer by double clicking on the NeoScanVisual icon. By default, [[NeoScan]] Visualization Utility program opens up with âSettingsâ page (Figure 5.1).
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5.1.1 Settings Page
By default [[NeoScan]] Visualization Utility program consider the âProject Folderâ:
Â
C:\Users\[[NeoScan|neoscan]]\Documents\[[NeoScan]]\Projects
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as the parent folder in which all saved data are stored.
In order to view the plots of scan data:
<ol>
<li>
<p>
Press âOpen File 1â button as shown in Figure 5.1. This opens up the dialog window, where direct you to the project in parent folder where you want to open a data file, see Figure 5.2.
<center>[[Image:neoscanfig_5_2.png|thumb|center|600px|<i><b>Figure 5.2</b>: Selecting a data file (E_X_Dir.DAT) from project folder (patch2.349GHZ) from the dialog window.</i>]]</center>
</p>
</li>
<li>
<p>
Choose the desired data file â e.g., E_X_Dir.DAT in project folder patch2.349GHz â and then press âOKâ button in the dialog window.
</p>
<ul>
<li>
<p>
âInformation Panelâ and âProject Descriptionâ will display all scan information regarding the selected project and scan (Figure 5.3).
Similarly, the user can open file 2, and <center>[[Image:neoscanfig_5_3.png|thumb|center|600px|<i><b>Figure 5.3 to display simultaneously</b>: Project Description Panel and Information Panel in NeoScan Visualization Utility program.</i>]]</center></p></li></ul>
</li>
<li>
<p>
Similarly, the user can open file 2, and 3 to display simultaneously.
</p>
</li>
<li>
<p>
Press âNear Field Mapsâ tab from [[NeoScan]] Visualization Utility program to view the plots.
</p>
</li>
</ol>
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==== Near Field Maps Page ====
5.1.2 Near Field Maps Page
[[NeoScan]] Near Field Maps page displays either 2D or 3D plots of the amplitude and phase distribution of the scanned field from saved files. It includes 2D Plot page and 3D Plot page.
â
â 5.1.3 ==== 2D Plots Page====
When you enter â2D Plotâ page, 2D contour plots for amplitude and phase distributions of the scanned field are plotted and the maximum and minimum of their values are displayed in the boxes next to the graphs (Figure 5.4).
<center>[[Image:neoscanfig_5_4.png|thumb|center|600px|<i><b>Figure 5.4</b>: 2D plots in NeoScan Near Field Maps Page.</i>]]</center>
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<ul>
<li>
<p>
By default, the program plots fields in V/m units. You can use the key labeled âAmplitude Unit?â to display them in dBV/m (Figures 5.4 and 5.5).
<center>[[Image:neoscanfig_5_5.png|thumb|center|600px|<i><b>Figure 5.5</b>: 2D Amplitude graphs in units of dBV/m (left) and V/m (right).</i>]]</center>
</p>
</li>
<li>
<p>
The âPhase Shiftâ knob adds an angular shift (in degree) to the phase distribution (Figure 5.6).
<center>[[Image:neoscanfig_5_6.png|thumb|center|600px|<i><b>Figure 5.6</b>: Effect of 90° phase shift on 2D Phase graph.</i>]]</center>
</p>
</li>
<li>
<p>
The Phase Threshold knob will sets any phase below a minimum field threshold (in V/m) to zero. Figure 5.7 compares the 2D Phase graph without a phase threshold (left) with the one with a phase threshold when the minimum field is set to 10 V/m (right).
<center>[[Image:neoscanfig_5_7.png|thumb|center|600px|<i><b>Figure 5.7</b>: 2D Phase graphs without (left) and with a phase threshold, setting the minimum field to 10 V/m (right).</i>]]</center></p></li><li><p> By default, [[NeoScan]] Visualization Utility program fits the 2D graphs into the square window. If the DUT is other than a circle or regular polygon such as square, equilateral triangle, etc. you must choose the âMaintain Ratioâ option in âView Fit?â in order to keep the object proportional. As an illustration, Figure 5.8 presents the comparison of 2D amplitude plots for field distribution of a 12 mm à 220 mm (rectangular) slotted waveguide antenna with different view options when âView Fit?â key is set to âFit to Windowâ (left plot) and when âMaintain Ratioâ option is chosen (right plot).
<center>[[Image:neoscanfig_5_8.png|thumb|center|600px|<i><b>Figure 5.8</b>: Comparison of 2D amplitude plots for field distribution of a slotted rectangular waveguide antenna with different view options; When âView Fit?â key is set to âFit to Windowâ (left plot) and when âMaintain Ratioâ option is chosen (right plot).</i>]]</center>
</p>
</li>
<li>
<p>
Press âSave Graphsâ button to save all plots. The plots associated with a project are saved in a folder called âPlotsâ within the same folder.
</p></li><li><p>
You can zoom in and out the graphs by clicking on the zoom button (Figure 5.4).
</p></li>Â Â Â Â Â Â </ul>
â
 ââ ==== 3D Plots Page====
To view 3D plots, press the â3D Plotsâ tab in Near Field Maps page (Figure 5.9).
<ul>
<li>
<p>
3D Amplitude graphs can be plotted either in dBV/m or V/m using the key labeled âAmplitude Unit?â
</p>
</li>
<li>
<p>
The âPhase Shiftâ knob adds an angular shift (in degree) to the phase distribution.
</p></li><li><p>
Users can choose the plot style using âPlot Styleâ dropdown window (Figure 5.10). It includes:
</p>
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<ul>
<li>
cwLine
</li>
<li>
cwPoint
</li>
<li>
cwLinePoint
</li>
<li>
cwHiddenLine
</li>
<li>
cwSurface
</li>
<li>
cwSurfaceLine
</li>
<li>
cwSurfaceNormal
</li>
<li>
cwContourLine
</li>
<li>
cwSurfaceContour
</li>
</ul>
The default format is âcwSurface.â
</li><li><p>
To adjust the graph degree of transparency use âTransparencyâ knob or Transparency Entry Box as shown in Figure 5.11.
</p>
</li>
</ul>
<center>
[[Image:neoscanfig_5_9.png|thumb|center|600px|<i><b>Figure 5.9</b>: 3D plots in NeoScan Plot Utility Page (with cwSurface plot style).</i>]]
<br>
[[Image:neoscanfig_5_10.png|thumb|center|600px|<i><b>Figure 5.10</b>: 3D plots in Fig. 5.9 with cwPoint plot style.</i>]]
<br>
[[Image:neoscanfig_5_11.png|thumb|center|600px|<i><b>Figure 5.11</b>: Effect of transparency level on 3D plots: 0% transparency level (left) and 50% transparency level (right).</i>]]
</center>
The âStopâ button stops the application. To close (kill) the [[NeoScan]] window click on exit button [[Image:icon_Exit.png]] on the top far right in the LabView user interface. To re-start running the program press the start button [[Image:icon_Start.png]] located on the top left in the LabView window, see Figure 5.1.
5.1.5 ==== Far Field Patterns Page The far field pattern measurement and utility are discussed in details in section 6.====
The far field pattern measurement and utility are discussed in details in section 6.
â
â