What is a vacuum tube?

A vacuum tube is an electronic component that controls electron flow inside an evacuated glass envelope. A heated cathode emits electrons (thermionic emission), an anode collects them, and one or more grids modulate the current. Tubes are still used in audio amplifiers for their low-order harmonic distortion and soft clipping behaviour.

What is the difference between a triode and a pentode?

A triode has three electrodes (cathode, grid, anode) and produces low gain (μ ≈ 20 to 100) with predominantly second-harmonic distortion. A pentode adds a screen grid and a suppressor grid, raising plate impedance and gain (μ > 1000) but introducing more high-order harmonics. Triodes are preferred for single-ended output stages, pentodes for high-power push-pull.

How do I bias a vacuum tube?

Two common methods: cathode bias (a resistor on the cathode self-regulates grid voltage and is forgiving of tube variation) and fixed bias (a negative supply on the grid, used in high-power push-pull stages). The operating point should typically sit at 70 percent of the maximum plate dissipation for class-A audio operation. Use a loadline calculator to verify.

A loadline is a straight line drawn on a tube's plate-current vs plate-voltage characteristic curves. Its slope is -1/RL where RL is the load resistance, and it shows every operating point the tube can reach. The intersection with the bias curve is the quiescent point. Loadlines are essential for choosing operating point, predicting distortion, and matching output transformers.

Are vacuum tubes still made today?

Yes. Current production tubes come mainly from JJ Electronic (Slovakia), Electro-Harmonix and Sovtek (Russia), Shuguang and PSVANE (China), Western Electric (USA), and Linlai. They cover most audio receiving types — 12AX7, EL34, KT88, 300B, 6L6, EL84, 6V6 — and several high-end recreations of NOS classics. Quality varies; testing on arrival is recommended.

Is working with vacuum tube amplifiers dangerous?

Yes. Tube amplifiers run on plate voltages of 250 to 600 V DC, and reservoir capacitors can hold a lethal charge for minutes after power-off. Always discharge filter capacitors through a bleeder resistor before working inside, keep one hand behind your back when probing live circuits, and never work alone. Read the High Voltage Safety guide before opening any chassis.

The inverted picture — shunt regulators

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Chapter 7 / 83 min

The inverted picture — shunt regulators

When constant total current beats variable pass-tube current.

Flip everything: instead of varying the pass tube's current to absorb the difference between V_raw and V_out, vary a parallel tube's current to keep the total drawn from V_raw constant. That's a shunt regulator — and it has a few unique tricks.

ConceptThe geometry

A series ballast R₁ drops most of V_raw − V_out. A shunt element (VR tube, triode, or a diff-amp + triode) hangs off V_out to ground, drawing whatever current the load isn't. I_R1 = I_load + I_shunt stays roughly constant. V_out is wherever the shunt element clamps it.

ConceptWhat shunt buys

Bidirectional current: the shunt can SINK current — handy for inductive loads where back-EMF would force a series pass tube into cutoff.
Constant total bus current: V_raw doesn't change with load, so PSU ripple stays predictable.
Naturally low noise: the shunt operates at near-fixed current, so its own noise contribution is minimised.

ConceptVariant 1 — bare VR shunt

The simplest shunt: R₁ + one VR tube. The derivation below walks through the total-current invariant, R₁sizing, and the VR’s worst-case dissipation.

Σ Derivation

Shunt VR-only — derivation

The series ballast R1 sets a (nearly) constant bus current. The VR tube absorbs whatever the load does not draw. That gives the cardinal invariant:

Solve for R_ballast — the only sizing knob the designer has:

A VR tube needs a minimum current to stay struck. Size I_total so the worst-case (highest I_load) still leaves the VR above I_VR,min:

Worst-case dissipation in the VR happens at NO load — the VR alone carries the entire bus current:

Ballast resistor dissipation is constant (the upstream price):

Output impedance is dominated by the VR’s dynamic resistance r_d (≈ 100–200 Ω for an 0A2):

Ripple is divided by the ballast / r_d ratio:

Takeaway: a bare-VR shunt is a low-pass filter for noise plus a hard reference for V_out, but dissipation is permanent. Always vet P_VR,max before picking a tube.

ConceptVariant 2 — single-triode shunt

Swap the VR for a power triode (6080, 6AS7) and Z_outdrops dramatically — but the tube dissipation can shoot up at no load.

Σ Derivation

Single-triode shunt — derivation

Same invariant as the VR version: the ballast R1 enforces a (nearly) constant total current; the triode V1 absorbs the slack between I_total and I_load:

The triode bias point: cathode held at V_ref by the VR tube, anode at V_out, grid driven from a divided sample β·V_out — so V_gk stays a few volts, not the full V_ref:

Quiescent current from the triode small-signal parameters:

Output impedance — the triode acts like a current sink of internal resistance r_p; the cathode sits on the stiff VR reference, so a rise in V_out raises V_gk → more shunt current → V_out is pulled back:

If the grid follows V_ref directly (passive bias, no comparator), there is no error-amplification — the loop gain is just μ from grid to anode current:

Worst-case triode dissipation occurs at zero load (the triode swallows all of I_total):

Compare with P_diss,max of the chosen tube. For a 6080 / 6AS7 the rating is 13 W per section, ≈ 26 W per envelope.

Takeaway: Z_out drops by ~μ vs the bare VR, but with no comparator the line regulation is still modest — the diff-amp variant adds the loop gain.

ConceptVariant 3 — diff-amp-driven shunt

Close the loop with a 12AX7 long-tailed pair. The loop gain T divides Z_out and lifts PSRR by the same factor — the derivation works it all out and compares shunt vs series efficiency.

Σ Derivation

Diff-amp-driven shunt — derivation

The geometry and the bus-current invariant are unchanged — what changes is the feedback path. The diff-amp watches a divided sample β·V_out and reacts to any drift versus V_ref.

Feedback divider ratio sets the static V_out:

Open-loop gain of the diff-amp into its anode load Ra (the 12AX7 with μ = 100 is so close to a perfect amplifier that we take A ≈ μ here):

Loop gain — open-loop times the feedback ratio:

Closed-loop output impedance — the shunt triode’s native Z divided by 1+T:

Ripple rejection — passive (ballast/r_d) times the loop gain bonus:

η Efficiency — shunt vs series

A series regulator only burns what its load draws:

A shunt regulator pays for I_total whether the load is there or not:

Equality holds only when I_load = I_total — i.e. the shunt tube is starved. In normal operation the shunt is strictly less efficient.

With the bench numbers above:

— all the power dissipates in R1 + the shunt tube.

Takeaway: shunt is worth it only when I_load is rock-stable. Its strengths are micro-ohm Z_out, constant upstream bus current, and current-sinking — never raw efficiency.

WarningThe cost: efficiency

Shunts run hottest at NO load. P_diss = (V_raw − V_out) × I_nominal is permanent. A 350 → 250 V shunt at 50 mA dissipates 5 W in the shunt tube continuously. Series-pass regulators only dissipate when the load draws. For high-current rails (> 100 mA), series is almost always more efficient.

Calc · shunt-currents

Open →

Shunt currents view

Three bars: I_R1 (constant), I_load (your draw), I_shunt (the difference). Watch how I_shunt swings as you sweep the load.

Check yourself

When does a shunt regulator make more sense than series-pass?

The inverted picture — shunt regulators

The inverted picture — shunt regulators

Shunt VR-only — derivation

Single-triode shunt — derivation

Diff-amp-driven shunt — derivation

Output Transformers

Power Supply & Rectification

Single-Ended Triode (SET)