Difference between revisions of "Lab-in-a-Box"

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(Software Oscilloscope on Linux)
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To compile the modified source, simply run <code>make</code>. To run the newly compiled binary, run <code>./xoscope</code>. Refer to the [[xoscope article]] for instructions on using the scope.
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To compile the modified source, simply run <code>make</code>. To run the newly compiled binary, run <code>./xoscope</code>. Refer to the [[xoscope|xoscope article]] for instructions on using the scope.
  
 
=External Links=
 
=External Links=
 
* [http://www.vtnews.vt.edu/story.php?relyear=2009&itemno=20 VT news story]
 
* [http://www.vtnews.vt.edu/story.php?relyear=2009&itemno=20 VT news story]
 
* [[CEL]] listing of the [http://www.ece.vt.edu/cel/Kits/ECE-Lab-Kits.html#ECE2074ECE3074 lab kit]
 
* [[CEL]] listing of the [http://www.ece.vt.edu/cel/Kits/ECE-Lab-Kits.html#ECE2074ECE3074 lab kit]

Revision as of 20:48, 14 December 2009

The Lab-in-a-Box is an introductory electrical engineering project kit and accompanying textbook used for ECE 2074 Electric Circuit Analysis Laboratory and ECE 3074 AC Circuit Analysis Laboratory. It includes a breadboard called the A&D or "ANDY" board.

ANDY Board

The ANDY board has ±9V and +5V sources, clock signal, sine/square wave signal generator, 16 dipswitches, 16 LEDs, and two pushbutton switches. The dipswitches and LEDs are used for digital applications in ECE 2504 Introduction to Computer Engineering. The signal generator is for RC circuits in the ECE 2074.

Parts Kit

The parts included with the kit include resistors, capacitors, inductors, light emitting diodes, and a handful of integrated circuits including operational amplifiers, and digital logic chips.

Software Oscilloscope on Linux

While xoscope or the Lab-in-a-Box attenuator circuit could use some tweaking to work out of the box together, xoscope can be readily modified to display scaled maximum, minimum and peak-to-peak values. The first step is to obtain the program source code. On a Debian-based systems like Ubuntu, just run sudo apt-get source xoscope.

Once the source has been downloaded and unpacked, edit sc_linux.c to use /dev/dsp1 rather than /dev/dsp:

sed -ir 's%(#define SOUNDDEVICE "/dev/dsp)(")%\11\2%'

Next, modify the display code in display.c to display a scaled value. Around line 186, change the code to read something like the snippet below. Use your multimeter to measure the the RMS voltage, calculate the peak-to-peak that should be displayed and tweak the divisor, re-compile and re-run until the value is correct.

    else
        sprintf(string, " Max:%f - Min:%f = %f Pk-Pk ",
                (float)stats.max / 3.2, (float)stats.min / 3.2,
                ((float)stats.max - (float)stats.min) / 3.2 );
    gtk_label_set_text(GTK_LABEL(LU("min_max_label")), string);

To compile the modified source, simply run make. To run the newly compiled binary, run ./xoscope. Refer to the xoscope article for instructions on using the scope.

External Links