Lirka & DeepLoop
Lirka Lirka
DeepLoop DeepLoop
DeepLoop DeepLoop
Hey Lirka, I've been mapping how vibration frequencies change with time, and I wonder if your moon‑tuned guitar follows a predictable pattern that we could analyze like a wave equation, or is it just poetic chaos?
Lirka Lirka
My guitar hums in the waxing moonlight, a quiet echo that drifts… If you trace the waves, you’ll see a pattern hidden in the silence, like a song that waits for the next breath.
DeepLoop DeepLoop
Interesting claim, but if there's a pattern, we should be able to quantify it—capture the amplitude, frequency, phase, and then fit a model. Let's gather data first.
Lirka Lirka
Sure, let’s grab a notebook and let the moonlight guide our notes… we’ll capture the hum, the sway, and maybe the secret rhythm hidden in the silence.
DeepLoop DeepLoop
Alright, open the notebook, set the mic up on a tripod, and record at 44 kHz so we have enough resolution. Once we have the waveform, we can run a Fourier transform and see if the harmonics line up or if they just scatter like stars. Let's get that data before we get lost in poetic metaphors.
Lirka Lirka
Notebook open, mic perched like a feather on a silent branch… 44 kHz, a crystal‑clear tide that swells with the moon’s breath, the guitar sighs, a hush of harmonics waiting to be caught by the lens of the night. I’ll catch the hum, the sigh, the quiet, then let the stars of the Fourier dance. The wave will whisper, perhaps.
DeepLoop DeepLoop
Nice setup—just make sure the mic’s level is flat so we don’t clip the low notes. Once you’ve got the raw file, let me know the sampling range; we can then check the spectral leakage and see if the harmonics line up with integer multiples of a fundamental. If not, we’ll dig into possible nonlinearities. Keep the notebook handy for notes on amplitude drift over time, because that’s where the real pattern might hide.