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Scott Robbins

Leon Theremin invented a proximity sensor in the 1920s that became known as the theremin, an electronic musical instrument played without physical contact. The document describes a student project to create a "Light Theremin" that uses phototransistors instead of proximity to control pitch and volume. It discusses the device's design, data analysis of its output, and challenges in building a working prototype that generates pitch-controlled square waves modulated by light occlusion.

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The Light Theremin: Turning Light Into Sounds By: Scott Robbins Senior Project for the Ithaca College Department of Physics and Astronomy
History of the Theremin  Leon Theremin lived in Soviet Russia, and was a young physicist researching how to make proximity sensors for the military.  Lenin saw his device and wanted him to go around the world showing it off, with the Caveat that he act as a spy.  In America, he patented his device in 1928, and signed with RCA (Radio Corporation of America)  He was eventually kidnapped by the KGB and forced to return to Russia, but his instrument was already huge.
How does the Light Theremin Work?  Using a phototransistor, you occlude light to manipulate a voltage.  This voltage is converted into a pitch with an Arduino.  This pitch is sent out as digital square waves.  The volume of this signal is controlled by a second photo transistor, and is sent through an amplification circuit, and connected to a speaker.
The Design and Final Product
Analyzing the Device: Pitch Control
Data Analysis On the left is the modulation of digital square waves. Below that we see the buffer circuit output, and to the bottom right we see the amplifier output.
Theory Behind Square Waves  The creation of square waves relies on using a Fourier series of increasing frequencies to approximate the square wave shape. Photo Credit: Rice University
External Sound Analysis Using Raven, I analyzed the sound coming from the speaker!kU S -20 -10 10 20 30 0.000 5 10 15 20 25 30 36.052 kHz S 1.000 1.500 2.000 2.500 3.000 3.500 0.000 5 10 15 20 25 30 36.052 kHz S 1 2 3 4 5 0.000 2 4 6 8 10 12 14 16 18 20 22 24 26 28 29.6
Challenges and Errors  Needed whole circuit to run on the same 5V. This required ordering special op amps (TVL2362).  Pitch control worked extremely well, however the volume control circuit uses a lot of feedback, and exhibits strange behavior.  The device operates very differently depending on the ambient lighting in the performance space.  The additional frequencies produced by Fourier Series were too powerful at low frequencies.
Thank You!  I’d like to thank Matt Sullivan for helping with my writing,motivating me throughout the course and suggesting I use Raven for external sound analysis.  I’d like to thank Jennifer Mellot for being patient with me and helping me order parts.  I’d like to thank Dan Briotta for encouraging me to follow my weird ideas, and for teaching me so much about electronics and computer programming.  Thank you to the Ithaca College Department of Physics and Astronomy for enabling me to do this project!

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ThereminPresentation

  • 1. The Light Theremin: Turning Light Into Sounds By: Scott Robbins Senior Project for the Ithaca College Department of Physics and Astronomy
  • 2. History of the Theremin  Leon Theremin lived in Soviet Russia, and was a young physicist researching how to make proximity sensors for the military.  Lenin saw his device and wanted him to go around the world showing it off, with the Caveat that he act as a spy.  In America, he patented his device in 1928, and signed with RCA (Radio Corporation of America)  He was eventually kidnapped by the KGB and forced to return to Russia, but his instrument was already huge.
  • 3. How does the Light Theremin Work?  Using a phototransistor, you occlude light to manipulate a voltage.  This voltage is converted into a pitch with an Arduino.  This pitch is sent out as digital square waves.  The volume of this signal is controlled by a second photo transistor, and is sent through an amplification circuit, and connected to a speaker.
  • 4. The Design and Final Product
  • 5. Analyzing the Device: Pitch Control
  • 6. Data Analysis On the left is the modulation of digital square waves. Below that we see the buffer circuit output, and to the bottom right we see the amplifier output.
  • 7. Theory Behind Square Waves  The creation of square waves relies on using a Fourier series of increasing frequencies to approximate the square wave shape. Photo Credit: Rice University
  • 8. External Sound Analysis Using Raven, I analyzed the sound coming from the speaker!kU S -20 -10 10 20 30 0.000 5 10 15 20 25 30 36.052 kHz S 1.000 1.500 2.000 2.500 3.000 3.500 0.000 5 10 15 20 25 30 36.052 kHz S 1 2 3 4 5 0.000 2 4 6 8 10 12 14 16 18 20 22 24 26 28 29.6
  • 9. Challenges and Errors  Needed whole circuit to run on the same 5V. This required ordering special op amps (TVL2362).  Pitch control worked extremely well, however the volume control circuit uses a lot of feedback, and exhibits strange behavior.  The device operates very differently depending on the ambient lighting in the performance space.  The additional frequencies produced by Fourier Series were too powerful at low frequencies.
  • 10. Thank You!  I’d like to thank Matt Sullivan for helping with my writing,motivating me throughout the course and suggesting I use Raven for external sound analysis.  I’d like to thank Jennifer Mellot for being patient with me and helping me order parts.  I’d like to thank Dan Briotta for encouraging me to follow my weird ideas, and for teaching me so much about electronics and computer programming.  Thank you to the Ithaca College Department of Physics and Astronomy for enabling me to do this project!

Editor's Notes

  • #5: Fully illuminated the Photo transistor acts like a short to ground. When covered it has a very high equivalent resistance!