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Active Noise Control. By: Jon Samuelson, Tyler Mose , Greg White, Logan Jennyc , Michael Krawczyk. Advisor: Norm Bartley. Sponsor: Noise Solutions Inc. EE22 Active Noise Control System. Why Active Noise Control?. Our Design Process. Signal Flow.
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Active Noise Control By: Jon Samuelson, Tyler Mose, Greg White, Logan Jennyc, Michael Krawczyk Advisor: Norm Bartley Sponsor: Noise Solutions Inc. EE22 Active Noise Control System • Why Active Noise Control? • Our Design Process • Signal Flow • Our device actively cancels out sound by following this process: • Measuring sound from the noise source with a microphone. • Processing the sound signal and reproducing it with a phase delay. • Measuring the resultant sound wave to analyze the amplitude. • The computer cycles through the phase delay time and continuously measures the resultant noise level. • When the lowest noise level is measured, the computer locks onto that exact phase delay. In modern society, machinery is frequently used to make our lives simpler, and to help us carry out tasks quickly. Unfortunately, a noticeable inconvenience of machinery is the loud noise they produce. Our goal was to design a computerized active noise control device that will attenuate the noise created by machine engines while keeping the whole system less expensive than conventional silencers. Our design involves the use of a computer to analyze an incoming sound wave and produce a similar sound wave that will interfere with it, cancelling out the noise. Figure 3: Signal Flow Diagram Waves are out of phase Incident Wave Destructive Wave • How does Active Noise Control work? • Future Goals Active noise control works through the use of phase cancellation. This essentially means having the peak of one sound wave meet with the trough of another sound wave. The amplitudes of each wave will add together, and the resultant wave will be lower in amplitude. • With the creation of our device, we have accomplished a great deal. However there is still much we can achieve. Possible future goals include: • Heat shielding the speaker(s) and microphone so the device can work in close proximity to exhaust flows. • Transferring the program onto a dedicated sound board to improve response time and decrease the size of the computing device. • Improving the algorithm to attain complete convergence on the required phase delay to remove noise artifacts. Phase delay adjusted as necessary Figure 2: Design Process Diagram • Design Requirements • Our device was created to meet these specifications: • Less than a 3 second response time to match a change in noise frequency. • Attenuate the incident waveform by at least 10dB. • Attenuate incident waveforms in the frequency range of 100Hz to 1.5kHz. Figure 1: How Active Noise Control Works Referenced from: www.loqu.com ENEL 583/589 Electrical, Computer, and Software Engineering