Notes:
Built around a single 8038 waveform generator IC, this circuit produces sine, square or triangle waves from 20Hz to 200kHz in four switched ranges. There are both high and low level outputs which may be adjusted with the level control. This project makes a useful addition to any hobbyists workbench as well.
Built around a single 8038 waveform generator IC, this circuit produces sine, square or triangle waves from 20Hz to 200kHz in four switched ranges. There are both high and low level outputs which may be adjusted with the level control. This project makes a useful addition to any hobbyists workbench as well.
Allof the waveform generation is produced by IC1. This versatile
IC even has a sweep input, but is not used in this circuit. The IC contains an
in`ternal squarewave oscillator, the frequency of which is controlled by timing
capacitors C1 - C4 and the 10k potentiometer. The tolerance of the capacitors
should be 10% or better for stability. The squarewave is differentiated to
produce a triangular wave, which in turn is shaped to produce a sine wave. All
this is done internally, with a minimum of external components. The purity of
the sine wave is adjusted by the two 100k preset resistors.
The wave shape switch is a single pole 3 way rotary switch, the
wiper arm selects the wave shape and is connected to a 10k potentiometer which
controls the amplitude of all waveforms. IC2 is an LF351 op-amp wired as a
standard direct coupled non-inverting buffer, providing isolation between the
waveform generator, and also increasing output current. The 2.2k and 47 ohm
resistors form the output attenuator. At the high output, the maximum amplitude
is about 8V pk-pk with the square wave. The maximum for the triangle and sine
waves is around 6V and 4V respectively. The low amplitude controls is useful
for testing amplifiers, as amplitudes of 20mV and 50mV are easily achievable.
Setting Up:
The two 100k preset resistors adjust the purity of the sine wave. If adjusted correctly, then the distortion amounts to less than 1%. The output waveform ideally needs to be monitored with an oscilloscope, but most people reading this will not have access to one. There is however, an easy alternative:- Winscope. This piece of software uses your soundcard and turns your computer into an oscilloscope. It even has storage facility and a spectrum analyser, however it will only work up to around 20KHz or so. Needless to say, this is more than adequate for this circuit, as alignment on any range automatically aligns other ranges as well. Winscope is available at my download page click here. Winscope is freeware and designed by Konstantin Zeldovich. After downloading, read the manual supplied with winscope and make up a lead to your soundcard. My soundcard is a soundblaster with a stereo line input, i made up a lead with both left and right inputs connected together. Connect the lead to the high output of the function genereator, set the output level to high, shape to sine, and use the 1k to 10k range, (22nF capacitor). A waveform should be displayed, see the Figure 1 below:-
The two 100k preset resistors adjust the purity of the sine wave. If adjusted correctly, then the distortion amounts to less than 1%. The output waveform ideally needs to be monitored with an oscilloscope, but most people reading this will not have access to one. There is however, an easy alternative:- Winscope. This piece of software uses your soundcard and turns your computer into an oscilloscope. It even has storage facility and a spectrum analyser, however it will only work up to around 20KHz or so. Needless to say, this is more than adequate for this circuit, as alignment on any range automatically aligns other ranges as well. Winscope is available at my download page click here. Winscope is freeware and designed by Konstantin Zeldovich. After downloading, read the manual supplied with winscope and make up a lead to your soundcard. My soundcard is a soundblaster with a stereo line input, i made up a lead with both left and right inputs connected together. Connect the lead to the high output of the function genereator, set the output level to high, shape to sine, and use the 1k to 10k range, (22nF capacitor). A waveform should be displayed, see the Figure 1 below:-
Figure 1.
Here an undistorted sine wave is being displayed. The display on
winscope may flicker, this is normal as it uses your soundcard to take samples
of the input waveform. The "hold" button on winscope will display a
steady waveform.
Alignment:
First adjust the 100k preset connected to Pin 1 of the 8038. An incorrect setting will look similar to the waveform below:-
First adjust the 100k preset connected to Pin 1 of the 8038. An incorrect setting will look similar to the waveform below:-
Adjust the preset so that
the top of the sine wave has a nicely rounded peak. Then adjust the other
preset, again an incorrectly adjusted waveform is shown below:
The two presets work
together, so adjusting one affects the other. A little is all that's needed.
When your waveform is asjusted and looks similar to Figure 1 press the FFT
button on winscope. This will preform a fast fourier transform and the
displayed output will be a spectrogram of the input. For a pure sine wave, only
one signal is present, the fundamental frequency, no harmonics will be present
and so a spectrogram for a pure sine should contain a single spike, see Figure
2 below:-
Figure 2.
A
distorted sine wave will contain odd and even harmonics, and although the shape
of the sine may look good, the spectrogram will reveal spikes at the hormonics,
see below:-
Once alignment of the sine wave
is complete, the other wave shapes will also be set up correctly. Below is a
picture of the triangle waveform generated from my circuit:-
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