Active Loads
The technique that separates vintage design from modern design. Replace the plate resistor with a constant current source and unlock the tube's full potential: gain approaching µ, doubled voltage swing, and dramatically improved power supply rejection.
Why Active Loads?
The fundamental limitation of resistive plate loads
With a resistive plate load, the voltage gain formula tells the whole story: Av = \u00b5 \u00d7 RL / (rp + RL). Since RL / (rp + RL) is always less than 1, the gain Av is always less than \u00b5. For a 12AX7 with \u00b5 = 100 and a typical 100k\u03A9 plate resistor, you get Av \u2248 61 \u2014 barely 61% of the tube's amplification factor.
The resistor also wastes B+ voltage. At the quiescent point, the resistor drops a significant fraction of the supply. With B+ = 300V and a 100kΩ load, the plate voltage sits around 170V — the output can only swing 170V peak before hitting the supply rail, and even less in the other direction before grid current flows.
Now replace the resistor with a constant current source (CCS). A CCS has infinite impedance at AC \u2014 its loadline is perfectly horizontal on the plate curves. Result: RL \u2192 \u221e, the gain formula simplifies to Av \u2248 \u00b5. The full amplification factor is realized. The voltage swing approaches 2\u00d7B+ because the CCS maintains constant current regardless of plate voltage. Power supply rejection improves dramatically because supply ripple creates no current variation through the infinite-impedance load.
61 → ~100
(12AX7)
170Vpp → 450Vpp
(B+ = 300V)
~6dB → 50+dB
Dramatic
Loadline Comparison
Resistor load vs. constant current source
Pentode Constant Current Sources
Staying within the tube domain
The most elegant CCS uses what we already have: another tube. Pentodes make excellent constant current sources because their plate characteristic curves are nearly flat — once past the knee voltage, plate current barely changes with plate voltage. The screen grid voltage programs the operating current.
Suitable pentodes include the EF184 (sharp cutoff, low noise), EL83 (power pentode, handles high current), and the remarkable EL822 (frame-grid, extremely high output impedance). The operating current is set by: Ik \u2248 gm \u00d7 (Vg2 \u2212 |Vg1(cutoff)|), with fine adjustment via cathode resistor.
All-tube signal path. No solid-state devices in the audio chain. Very high output impedance (1MΩ+). Proven reliability over decades.
Requires additional heater supply. Microphonic sensitivity. Warm-up drift until thermal equilibrium. Large physical size.
Transistor Constant Current Sources
The hybrid approach — transistors serving tubes
Modern tube designers often use semiconductor CCS devices. The transistor handles the DC task of maintaining constant current while the tube does what it does best: amplify the signal. This hybrid philosophy accepts that the signal path is what matters sonically, and the DC biasing network can be solid-state without compromise.
The simplest semiconductor CCS is the depletion-mode MOSFET (DN2540N5, IXTP01N100D). Connect gate to source through a resistor \u2014 that's it. Two components. The DN2540N5 is rated at 400V and can be set from 1mA to 15mA by choosing Rs. I = Idss \u00d7 (1 \u2212 Vgs/Vp)\u00b2 with Vgs = \u2212I\u00d7Rs.
| Device | Output Z | V rating | Parts | Noise |
|---|---|---|---|---|
| BJT (MJE340) | ~500k\u03A9 | 300V | 3-4 | Low |
| JFET (J310) | ~1M\u03A9 | 25V | 1-2 | Very low |
| DN2540N5 | ~2M\u03A9 | 400V | 2 | Low |
| BJT cascode | ~50M\u03A9 | 600V | 5-6 | Lowest |
| Pentode (EL822) | ~5M\u03A9 | 550V | 3-4 | Moderate |
The µ-Follower
Horton's 1933 topology — the most important circuit in modern tube design
The µ-follower stacks two triodes: the lower tube amplifies while the upper tube acts as a CCS. The upper tube's cathode connects to the lower tube's plate, and its grid is decoupled to ground via a capacitor. The upper tube sees the output signal on its cathode and adjusts its current to maintain constant operation — presenting a very high impedance load to the lower tube.
The result is extraordinary: with a 12AX7 lower and 6J5 upper (\u00b5 = 20), the effective load impedance is \u00b5\u2082 \u00d7 rp\u2082 = 20 \u00d7 7.7k = 154k\u03A9. Gain rises from 61 to about 91. PSRR improves by 26dB \u2014 from 6dB to 32dB. With a pentode-connected upper tube (\u00b5 \u2248 500+), the loadline becomes essentially horizontal and Av approaches the full \u00b5 of 100.
Limitations: the µ-follower requires double the heater supply current and has slightly higher output impedance than a simple common cathode stage because the upper tube's rp appears in parallel. It is optimized for maximum gain, not for driving loads.
µ-Follower Designer
Compare with simple resistor load
SRPP (Shunt-Regulated Push-Pull)
Often confused with the µ-follower — but designed to drive loads
SRPP looks identical to the µ-follower in schematic — two triodes stacked with a shared plate/cathode node. The crucial difference is intent and loading. The µ-follower is optimized for high gain into a high-impedance input. The SRPP is designed to provide push-pull drive capability into a defined load impedance.
In SRPP, on positive signal swings the lower tube pulls more current (conventional common cathode), while on negative swings the upper tube pushes current into the load through its cathode follower action. This gives genuine push-pull operation from just two triodes. The optimal load impedance for balanced push-pull operation is: Rload = rp / 2.
For a 6922/E88CC with rp \u2248 2.6k\u03A9, the optimal SRPP load is about 1.3k\u03A9 \u2014 which is close to the impedance of a 600\u03A9 balanced line or a reasonable headphone. With a 12AU7 (rp \u2248 7.7k\u03A9), the optimal load is about 3.8k\u03A9. If the actual load differs significantly from rp/2, the push-pull symmetry degrades and one triode does most of the work, reducing the benefit over a simple common cathode stage.
A common misconception is using SRPP to drive a high-impedance grid — in that case, the upper tube barely participates and you get no push-pull benefit. Use a µ-follower instead. SRPP shines when you have a defined, moderate-impedance load to drive.
Maximum gain. High-Z load. Upper tube = CCS. Grid cap to ground. PSRR optimized.
Push-pull drive. Defined load (rp/2). Upper tube = active follower. Current drive on both halves.
White Cathode Follower
Output impedance in single-digit ohms — the basis of all OTL amplifiers
A simple cathode follower has output impedance Zout \u2248 1/gm, typically 200\u2013500\u03A9. The White cathode follower adds a second tube in a feedback arrangement that multiplies the effective transconductance. The output impedance drops to: Zout \u2248 1 / (gm\u2081 \u00d7 gm\u2082 \u00d7 Ra).
With two 6SN7 sections (gm ≈ 2.6 mA/V each) and Ra = 47kΩ, the White CF achieves Zout ≈ 3Ω. This is low enough to drive headphones, long cables, or serve as the output stage of an OTL (output-transformerless) amplifier. The White CF exists in two forms: self-contained (both tubes in one envelope) and with external gain stage feedback.
Both triodes in one dual envelope (e.g. 6SN7). V1a is the cathode follower, V1b senses the output and controls the current through the anode resistor Ra. No external feedback needed.
The White CF has unity gain (like any cathode follower) but its extraordinary low output impedance makes it ideal for headphone outputs, long interconnects, and as the output of OTL amplifiers like the Futterman design.
White Cathode Follower
Ultra-low output impedance
Cascode + CCS Combined
The ultimate voltage gain stage
The cascode amplifier stacks two triodes in series: a common cathode lower tube drives a common grid upper tube. The upper tube shields the lower tube from Miller capacitance and effectively multiplies the plate resistance. When you combine a cascode with a CCS load, you get a horizontal loadline on a tube pair with extremely high equivalent µ.
A practical example: 6SN7 (or 7N7) cascode with DN2540 depletion MOSFET CCS. The cascode runs at 8mA+ for maximum linearity. B+ = 400V. The CCS maintains perfectly constant current while the cascode pair provides an effective \u00b5 of \u00b5\u00b2 (20 \u00d7 20 = 400 for 6SN7). Gain exceeds 350, with voltage swing approaching 600Vpp.
Practical Applications
Where active loads make the biggest difference
Active loads transform every stage of a tube amplifier. Here are the applications where they matter most, with practical component values from proven designs.
Phono preamps benefit enormously from CCS loads: lower noise floor (no resistor thermal noise), improved PSRR (critical with MC cartridge sensitivity), and higher gain without sacrificing headroom.
Example: 12AX7 µ-follower → passive RIAA → 12AU7 µ-follower. B+ = 250V, CCS = DN2540 + 330Ω.
Driver stages for power tubes need maximum voltage swing. A CCS-loaded driver can swing nearly 2×B+, providing the 80–90Vpp needed to drive EL34/KT88 output tubes to full power without an interstage transformer.
Example: 6SN7 + MJE340 CCS. B+ = 350V. Swing = 240Vpp at 8mA.
A CCS tail current source in a long-tailed pair gives perfect common-mode rejection. The CCS forces I₁ + I₂ = constant, making CMRR approach infinity in theory. In practice, 80–90dB CMRR is achievable, compared to 20–30dB with a resistive tail.
Example: 12AT7 LTP + DN2540 tail CCS. Rk = 470Ω, Itail = 5mA. CMRR > 80dB.
| Application | Topology | Tubes | CCS | B+ |
|---|---|---|---|---|
| Phono MC | µ-Follower | 12AX7 + 12AX7 | Upper triode | 250V |
| Line stage | SRPP | 6922 / E88CC | Active SRPP | 280V |
| PP driver | CCS loaded | 6SN7 | MJE340 | 350V |
| Headphone | White CF | 6SN7 + 6SN7 | N/A | 300V |
| Max gain | Cascode+CCS | 7N7 / 6SN7 | DN2540 | 400V |
Key Equations
All the formulas for active load design
Active loads are the single most impactful technique in modern tube circuit design. A plate resistor wastes voltage, limits gain, and couples power supply noise. Replacing it with any form of constant current source \u2014 pentode, transistor, depletion MOSFET, or another triode in \u00b5-follower configuration \u2014 transforms the performance of every stage it touches.
Active Loads — Full Quiz
Test your knowledge of CCS, µ-follower, and active load topologies
With a resistive plate load, a 12AX7 (µ = 100, rp = 65kΩ) with a 100kΩ load resistor achieves what approximate gain?