This example shows how to visualize a radiation pattern and vector fields from user data. To plot a 3D field data, use the
patternCustom function. This function also allows the user to slice the data and see it. To visualize just 2D polar data use
polarpattern function. The function allows you to interact with the data as well as perform antenna specific measurements. The user can also plot the vector fields at a point in space using the
3D Radiation pattern data stored in a csv file format can be read using the csvread function. In the first part of this example we use the patternCustom function to visualize the 3D data. The function can be used to visualize 2D slices of the 3D data as well.
M = csvread('CustomPattern_testfile.csv',1,0);
To plot the 3D radiation pattern on a polar coordinate system, specify the MagE vector/matrix and theta and phi vectors. If MagE is a matrix, it should be of size phi x theta. If MagE is a vector, all 3 arguments MagE, phi and theta should be of same size.
To plot the 3D radiation pattern on rectangular coordinate system, you modify the CoordinateSystem flag. By default, the flag is set to polar. Change it to rectangular to visualize the data in the rectangular coordinate system.
To plot a 2D slice on polar coordinate system, modify the Slice flag to either 'phi' or 'theta', depending on the plane you want to view data in. You should also modify the SliceValue flag to give a vector of phi or theta values for the slices. The slice values should be in the input data. Specify the CoordinateSystem flag as polar to view using a polar plot.
patternCustom(M(:,3),M(:,2),M(:,1),'CoordinateSystem','polar','Slice', ... 'phi','SliceValue',[45 90 180 360]);
Specify the CoordinateSystem flag as rectangular to view the above case using a rectangular plot.
patternCustom(M(:,3),M(:,2),M(:,1),'CoordinateSystem','rectangular', ... 'Slice','phi','SliceValue',[45 90 180 360]);
To plot a 2D polar data, you can use the
polarpattern function as shown below. The plot generated is an interactive plot that allows the user to perform antenna specific measurements as well. The data in this case is stored in a .mat file. The file contains directivity values calculated over 360 degrees with one degree seperation.
load polardata p = polarpattern(ang, D);
Right click in the figure window to interact with the plot. The figure below shows s screen shot of the context menu. The contect menus can be used to do measurements such as peak detection, beamwidth calculation etc. You can laso add a cursor by right clicking inside the polar circle.
Select the Antenna Metrics option in the above contect menu, to visulaize the antenna specific measuremnets as shown below.
To plot vector electric and/or magnetic fields at any point in space, use the
fieldsCustom function as shown below. The EHfielddata contains the E and H field data as well as the points in space specified as x, y and z coordinates. The electric and magnetic fields are complex quantities and have x, y and z components at every point in space. The fields can be artificially scaled for better visualization.
load EHfielddata; figure; fieldsCustom(H, points, 5);
The function is used to plot one field quantity at a time. To plot both E and H fields on the same plot, use the hold on command.
figure; fieldsCustom(gca, E, points, 5); hold on; fieldsCustom(gca, H, points, 5); hold off; legend('E', 'H');