The physics of the cold-cathode VR tube + the cardinal cap rule.
A cold-cathode VR tube is a gas-filled diode with two terminals and one job: clamp the voltage across itself to Vref. Add it to a single-tube CF regulator and the grid stops drifting with mains — line regulation improves by an order of magnitude.
ConceptStrike, run, hold
When Vraw across the tube reaches Vstrike(typically Vref + 30 V), the gas ionises and a glow discharge appears. The anode-cathode voltage collapses to Vref and stays there over the operating current band [Imin, Imax]. If current drops below the hold threshold the glow extinguishes and you need to re-strike — which means re-reaching Vstrike, not Vref.
ConceptDynamic resistance r_d
Vref isn't perfectly flat — it drifts ~2–4 V across the full current band. The slope ΔV / ΔI is the dynamic resistance rd, typically 80–300 Ω for service VR tubes, 1.5 kΩ for the 5651 precision reference. Stack two VR tubes and rd adds.
The series resistor R1 sets Itube. Size it so the tube stays inside [Imin, Imax] across the worst case of mains and load: low-line + high-load gives the lowest Itube, high-line + low-load gives the highest.
Cardinal rule
Never put a capacitor > 10 nF directly across a VR tube. At ignition the cap dumps current into the gas, triggering relaxation oscillation (visible flicker, audible buzz, eventual destruction). Filter after the VR tube through a series resistor — never across it.
The two-constraint geometry: R1,max from low-line + high-load, R1,min from high-line + low-load. If they cross, no R1 works — you need to tighten the spec or pick a wider-envelope tube.
Sweep Vraw and watch the VR tube strike at Vstrike, run at Vref, then extinguish below the hold threshold. The interactive I–V curve highlights the three regions.
Check yourself
Your 0A2 (V_ref = 150, V_strike = 185 V) feeds a single-tube CF. V_raw at cold start is 175 V. What happens at power-on?