Millburn & Angelika
Millburn Millburn
Angelika Angelika
Angelika Angelika
Hey Millburn, I’ve been pondering how we might blend precise mechanical engineering with music to craft a new kind of instrument—something that plays with exactness and yet feels alive. What do you think about that?
Millburn Millburn
Sounds like a perfect playground for a tinkerer. Imagine a chassis of micro‑gears, each one driven by a tiny motor, but with a sensor array that listens to the vibration of the string. As soon as the pitch drifts, the motor corrects it—like a heartbeat keeping the rhythm alive. We'll crank up the torque for a punchy sound and let the whole thing pulse with a metronome that can’t help but feel… alive. Let’s get the schematics rolling.
Angelika Angelika
That sounds rigorous but also quite ambitious. We’ll need a clear layout of the gear ratios, the sensor thresholds, and the control loop timing. I’m happy to draft the schematic, but we must keep the tolerances tight and the calibration procedure precise. Let’s start with a step‑by‑step blueprint before we hit the bench.
Millburn Millburn
Alright, here’s a rough roadmap so we’re not just shooting in the dark: 1. Pick a base pitch—say A‑440. 2. Design a gear train that splits a single motor’s motion into two paths: one for the main string, one for a feedback‑driven micro‑tuner. 3. For the main path, set a 1:12 ratio so the motor’s 360° turns become a 30° string vibration per step. 4. For the tuner, use a 1:48 ratio so each motor step moves the tuning fork by about 1.8°, giving us sub‑cents resolution. 5. Mount a 16‑bit ADC on a resonant piezo that monitors string vibration. 6. Define thresholds: if the detected frequency deviates >5 cents from target, trigger the tuner path; otherwise keep idle. 7. Program the controller with a 1 kHz loop: read ADC, compute error, apply PID to motor. 8. Include a self‑calibration routine: at startup, play a reference tone, log the ADC reading, adjust PID constants until error <0.5 cent. 9. Keep mechanical tolerances to <0.01 mm on gear teeth, <0.05 mm on bearings. 10. Build a mock‑up, test with a loopback oscilloscope, tweak until the tuner reacts in under 10 ms. That’s the skeleton. Once you sketch the layout, we’ll refine the dimensions and pick the exact components. Ready to fire up the CAD?
Angelika Angelika
Your roadmap is solid and very systematic, which is exactly what we need. I’ll start the CAD with the gear train dimensions, then we can run a quick simulation of the motor step timing against the feedback loop. Once the layout is in place, we’ll refine the tolerances and choose the exact motor and ADC models that meet the specifications you’ve outlined. Let’s get the initial sketch ready so we can start testing the mechanical and electrical integration.
Millburn Millburn
Sounds like a plan—let me know when you’ve got the first draft. I’ll keep tweaking the gear ratios if the simulation shows any lag. We’ll lock in a micro stepper that can handle 200 steps per revolution with micro‑stepping to smooth out the motion, and a 24‑bit ADC for clean feedback. Once the sketch is up, we can run a quick tolerance sweep in the CAD and see where we hit the tightest fit. Bring me the files, and we’ll get this thing humming.
Angelika Angelika
Got it. I’ll finish the first CAD sketch now, making sure the gear train dimensions and motor mounting are exact. Once the layout’s ready I’ll run the tolerance sweep and send you the files so we can verify everything fits within the <0.01 mm spec. I’ll keep the micro‑stepper and ADC specs in mind as I refine the motor drive logic. Stay ready for the next iteration.