Create Antenna Model from Gerber Files
This example shows you how to create an antenna model from Gerber files and subsequently analyze the antenna. The Gerber file format is used in printed circuit board (PCB) manufacturing and is available in two formats: RS-274D, which was the initial release standard, and RS-274X, which is the newer extended Gerber format. The Antenna Toolbox™ supports the newer RS-274X format both to generate Gerber files from an antenna model as well as to create an antenna model from a set of Gerber files.
A set of Gerber files includes information about layer geometry, layer mask, solder paste usage on the layers, drill file and so on. To create a PCB antenna model out of these files, you need layer files that specify the antenna geometry, and if available a drill file to specify any plated through-hole (PTH) vias. The geometry of the layers is specified through either a top and a bottom layer file, with extensions .gtl and .gbl, or a Gerber file, with the extension .gbr. The Antenna Toolbox supports the Excellon format to specify drill information with file extensions .txt or .drl. To create an antenna model, import up to two layers and an optional drill file.
This example will generate an antenna model using a single layer file and a two-layer file.
Import Single Layer Design and Analysis
While you can specify several antennas that are specified on a single side of a PCB, this example uses the design for an inverted-L antenna. The first step is to import a top-layer Gerber file into the workspace using the
gerberRead function. This will create a
PCBReader object. The
PCBReader object provides access to the stackup that holds the information on the metal and dielectric layers and also any drill files that describe a PTH via from one metal layer to another. The GTL file that this example provides is held in the stackup as
Layer2. If a second layer is present, you can specify it as Layer4 directly through the
stackUp object or by passing it to the
gerberRead function as the second input.
P1 = gerberRead('ILA_coplanar.gtl'); P1.StackUp
ans = stackUp with properties: NumLayers: 5 Layer1: [1x1 dielectric] Layer2: 'ILA_coplanar.gtl' Layer3: [1x1 dielectric] Layer4:  Layer5: [1x1 dielectric]
PCBReader object also provides a property to control the discretization on any curved segments in the imported layer. By default, the value of this property,
NumPointsOnCurves, is set to 50 in this example.
The next step is to create the antenna model. To do so, pass the
PCBReader object as an input to the
pb = pcbStack(P1); figure show(pb)
The Gerber file format does not provide information regarding a feed. By default, the feed is located at the origin in the created model. In order to make this model usable, modify the feed location on the layer.
pb.FeedDiameter = .001; pb.FeedLocations(1:2) = [0,0.035]; figure show(pb)
Import Two-Layer Design and Analysis
Import a two-layer design to create the antenna model. As before, you can use the
gerberRead function to create the
PCBReader object. Pass in the top and bottom layers as inputs to the function.
P2 = gerberRead('UWBVivaldi.gtl','UWBVivaldi.gbl'); P2.StackUp
ans = stackUp with properties: NumLayers: 5 Layer1: [1x1 dielectric] Layer2: 'UWBVivaldi.gtl' Layer3: [1x1 dielectric] Layer4: 'UWBVivaldi.gbl' Layer5: [1x1 dielectric]
Modify the third layer in the stack, which is the dielectric layer between the top and bottom metal layers.
S = P2.StackUp; S.Layer3 = dielectric('Name','FR4','EpsilonR', 4.4, 'Thickness', 0.8e-3); P2.StackUp = S;
Create the antenna model by passing
pcbStack object as an input to the
PCBReader object. In addition, modify the feed information such as the coordinates, layer, and the feed diameter.
pb2 = pcbStack(P2); pb2.BoardThickness = 0.8e-3; pb2.FeedLocations=[-(44e-3/2), -(40e-3/2 - 11.2e-3 - 1.5e-3/2), 2, 4]; pb2.FeedDiameter = 1.5e-3/2; figure show(pb2) axis equal;
figure mesh(pb2, 'MaxEdgeLength',5e-3,'MinEdgeLength',0.8e-3);
gerberRead function, you can create a
PCBReader object, and subsequently use that object to generate the antenna model using a
stackUp | Design, Analysis, and Prototyping of Microstrip-Fed Wide-Slot Antenna