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Introduces graphical representation of data in LabVIEW MathScript.

Graphical representation of data in labview mathscript

LABVIEW MATHSCRIPT provides a great variety of functions and techniques for graphical display of data. The flexibility andease of use of LABVIEW MATHSCRIPT's plotting tools is one of its key strengths. In LABVIEW MATHSCRIPT graphs are shown in a figure window. Several figurewindows can be displayed simultaneously, but only one is active. All graphing commands are applied to the active figure. The command figure(n) will activate figure number n or create a new figure indexed by n .

Tools for plotting

In this section we present some of the most commonly used functions for plotting in LABVIEW MATHSCRIPT.

  • plot - The plot and stem functions can take a large number of arguments, see help plot and help stem. For example theline type and color can easily be changed. plot(y) plots the values in vector y versus their index. plot(x,y) plots the values in vector y versus x . The plot function produces a piecewise linear graph between its data values. With enough data points it lookscontinuous.
  • stem - Using stem(y) the data sequence y is plotted as stems from the x-axis terminated with circles for the data values. stem is the natural way of plotting sequences. stem(x,y) plots the data sequence y at the values specified in x .
  • xlabel('string') - Labels the x-axis with string .
  • ylabel('string') - Labels the y-axis with string .
  • title('string') - Gives the plot the title string .

To illustrate this consider the following example.

In this example we plot the function y = x2 for x 2 [-2; 2].

x = -2:0.2:2;

y = x.^2;

figure(1);

plot(x,y);

xlabel('x');

ylabel('y=x^2');

title('Simple plot');

figure(2);

stem(x,y);

xlabel('x');

ylabel('y=x^2');

title('Simple stem plot');

This code produces the following two figures.

Some more commands that can be helpful when working with plots:

  • hold on / off - Normally hold is off. This means that the plot command replaces the current plot with the new one. To add anew plot to an existing graph use hold on . If you want to overwrite the current plot again, use hold off .
  • legend('plot1','plot2',...,'plot N') - The legend command provides an easy way to identify individual plots when there are more than one per figure. A legendbox will be added with strings matched to the plots.
  • axis([xmin xmax ymin ymax]) - Use the axis command to set the axis as you wish. Use axis on/off to toggle the axis on and off respectively.
  • subplot(m,n,p) -Divides the figure window into m rows, n columns and selects the p p'th subplot as the current plot, e.g subplot(2,1,1) divides the figure in two and selects the upper part. subplot(2,1,2) selects the lower part.
  • grid on/off - This command adds or removes a rectangular grid to your plot.

This example illustrates hold , legend and axis .

x = -3:0.1:3; y1 = -x.^2; y2 = x.^2;

figure(1);

plot(x,y1);

hold on;

plot(x,y2,'--');

hold off;

xlabel('x');

ylabel('y_1=-x^2 and y_2=x^2');

legend('y_1=-x^2','y_2=x^2');

figure(2);

plot(x,y1);

hold on;

plot(x,y2,'--');

hold off;

xlabel('x');

ylabel('y_1=-x^2 and y_2=x^2');

legend('y_1=-x^2','y_2=x^2');

axis([-1 1 -10 10]);

The result is shown below.

In this example we illustrate subplot and grid.

x = -3:0.2:3; y1 = -x.^2; y2 = x.^2;

subplot(2,1,1);

plot(x,y1);

xlabel('x'); ylabel('y_1=-x^2');

grid on;

subplot(2,1,2);

plot(x,y2);

xlabel('x');

ylabel('y_2=x^2');

Now, the result is shown below.

Printing and exporting graphics

After you have created your figures you may want to print them or export them to graphic files. In the "File"menu use "Print" to print the figure or "Save As" to save your figure to one of the many available graphics formats. Using theseoptions should be sufficient in most cases, but there are also a large number of adjustments available by using "Export setup","Page Setup" and "Print Setup".

3d graphics

We end this module on graphics with a sneak peek into 3D plots. The new functions here are meshgrid and mesh . In the example below we see that meshgrid produces x and y vectors suitable for 3D plotting and that mesh(x,y,z) plots z as a function of both x and y .

Example: Creating our first 3D plot.

[x,y] = meshgrid(-3:.1:3);

z = x.^2+y.^2;

mesh(x,y,z);

xlabel('x');

ylabel('y');

zlabel('z=x^2+y^2');

This code gives us the following 3D plot.

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Source:  OpenStax, Introduction to labview mathscript. OpenStax CNX. Aug 06, 2006 Download for free at http://cnx.org/content/col10370/1.3
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