The discussion revolves around the auditory effects of striking two tuning forks of the same frequency simultaneously or sequentially, particularly focusing on the concept of sound wave interference and cancellation. Participants explore whether complete silence would result from such conditions and the implications of phase differences in sound waves.
The conversation is ongoing, with various perspectives being shared about the nature of sound cancellation and the role of perception in auditory experiences. Some participants suggest practical experiments to test the concepts discussed, while others reflect on the limitations of such experiments in achieving complete cancellation.
Participants note constraints such as the inability to conduct certain experiments due to equipment limitations and the complexity of achieving precise phase alignment in real-world scenarios. The discussion also touches on the influence of the auditory processing system on perceived sound.
needingtoknow said:... No mfb unfortunately I cannot try that experiment now b/c I'm at a laptop which has a single source of sound
needingtoknow said:Oh I thought you meant to play two separate sounds from two separate speakers, but what you're saying makes sense. I tried it with opening this in two separate tabs but I didn't get any cancellation. I heard some beats though or at least I think I did.
Yes, you'd need the sources to arrive exactly out of phase at each ear, preferably in an anechoic chamber.phinds said:that would depend on where you held them relative to your ear. Even if you got the best cancellation possible I think you'd likely still hear at least something. Real-world wave cancellation of this type is likely to be a bit messy
mfb said:Did you ever note interference effects with two speakers at a computer? You can let them play a sinus wave to simulate your experiment. Are there regions where you hear nothing?
It works very well, nice. You can even hear the influence of moving a hand around close to the ear or between ears and speakers (yes it can make the sound louder).B0b-A said:The cancellation is almost complete if you put your head exactly the right position.
Try playing the attached mp3 (in a zip file) through a device with stereo-speakers,
(not headphones), whilst slowly moving your head , e.g. rocking back and forth , and/or turning your head.
I don't see how cancellation can be annulled by perception considerations. If there's no net movement or pressure change of the air molecules, there's nothing to perceive.nsaspook said:Even if they were exactly out of phase and equal in amplitude at each ear in isolation the ear/brain interface still does the processing so much of what we hear is preconditioned and is a bit of an illusion of reality that can somewhat be changed with practice and concentration. Above 1khz we lose the ability to phase discriminate signals and mainly only sense frequency so full sound cancellation with stereo hearing is limited.
haruspex said:I don't see how cancellation can be annulled by perception considerations. If there's no net movement or pressure change of the air molecules, there's nothing to perceive.
You wrotensaspook said:I said in isolation (headphones with separate transducers in each ear). Your hearing can be adapted and retrained just like vision.
http://www.theguardian.com/education/2012/nov/12/improbable-research-seeing-upside-down
Doesn't that imply complete cancellation of the waveform at each ear? Nothing to hear?exactly out of phase and equal in amplitude at each ear in isolation
haruspex said:You wrote
Doesn't that imply complete cancellation of the waveform at each ear? Nothing to hear?
I repeat, you wrote:nsaspook said:Why? The separate conversion of acoustic energy in each ear to signals interpreted by the brain as sounds allows us to detect phase and aptitude differences across our head and normally we think of our ears as linked acoustically. Our hearing is not a simple algebraic mixer of two signals. You can be easily trained to listen to a voice in one ear and copy Morse code in the other for example. I often wore two set of headphones with each over only one ear to compare the signal quality of radio comm circuits transmitting the same signal when selecting which one to use. Changes in phasing due to HF skip were detected in my head as direction changes or beats not a null of the signals.
This means that, at each ear separately, the arriving waves completely cancel. Neither ear gets any signal. This has nothing to do with any subsequent processing by the nervous system.exactly out of phase and equal in amplitude at each ear