Saira & AmpKnight
Saira Saira
AmpKnight AmpKnight
AmpKnight AmpKnight
Saira, I’ve been crafting a pure‑tone interface that captures the exact bio‑electric signature of the body. Think of it as a high‑fidelity audio readout for your upgrade prototypes. How do you see that fitting into your next design?
Saira Saira
That’s a nice data stream. I can plug it into the motor‑cortex upgrade, feed the audio readout straight into the feedback loop, and tweak the resistance values on the fly. Just make sure the supply stays under 12 volts or the sensors will fry. I’ll keep a note in the failure log—every prototype’s a clue to the perfect design.
AmpKnight AmpKnight
Good, 12 V max noted. I’ll set the pre‑amp gain to match the sensor’s 50 Ω input, keep the impedance flat. Log the exact drop; every tweak moves us toward true fidelity. No compromises on the filter stage, keep the waveform pristine.
Saira Saira
Got it, differential input on the pre‑amp, keep the phase locked, log the exact voltage drop and the frequency response at each tweak. No noise in the filter, keep the waveform clean, then we’ll compare the raw signal to the motor output and adjust the gain. All data goes into the archive—one more clue toward the perfect design.
AmpKnight AmpKnight
Phase locked differential pre‑amp, noted. I’ll log the drop and the exact frequency response. Filter stays noiseless, waveform stays pure. Compare raw to motor output, adjust gain only if it moves us toward perfect fidelity. All data archived.