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Understanding Loadlines

Technical · Interactive

Understanding Loadlines

The graphical key to amplifier design. Select a tube, set your supply voltage and load, and watch the loadline, operating point, and gain update in real time.

Select a tube — plate curves update live

12AX7Rich warm midrange. The gold standard.

μ100

rp63kΩ

Gm1.6 mA/V

Pd max1.2W

Va max300V

modelKoren SPICE

01 — Concept

What Is a Loadline?

The most powerful tool in tube amplifier design

Every tube has a family of plate characteristic curves — plots of plate current (Ia) vs plate voltage (Va) at different grid voltages (Vg). These curves are the tube. They contain everything you need to know about its behavior.

A loadline is a straight line drawn on these curves that represents your circuit constraints. Given a supply voltage B+ and a load resistance R_L, the loadline shows every possible combination of plate voltage and plate current the tube can operate at.

At Va = 0: Ia = B+ / R_L
Y-intercept (max current)

At Ia = 0: Va = B+
X-intercept (max voltage)

The operating point (Q-point) is where the loadline crosses the bias curve — the steady-state condition around which the signal swings. The signal swings the grid above and below bias, and you read the output swing directly from the loadline.

02 — Interactive Plotter

Live Loadline Calculator

Adjust B+, load resistance, and bias — the plot updates instantly

Plate Characteristics & Loadline — 12AX7

Parameters

B+250V

R load100kΩ

Vg-2V

Show AC loadline

Operating Point (Q)

Plate Voltage (Va)215.5V

Plate Current (Ia)0.34mA

Plate Dissipation0.07W

Cathode Bias Rk5.8kΩ

Small-Signal at Q

Voltage Gain (Av)40.3

μ at Q98.5

Gm at Q0.68mA/V

rp at Q144kΩ

03 — Analysis

Reading the Loadline

How to extract every design parameter from the graph

Once you have the Q-point, the loadline reveals everything about your amplifier stage:

Output Swing

The grid signal swings above and below bias. Follow the loadline up and down from Q to read the peak-to-peak output voltage swing.

Clipping Symmetry

If the tube clips harder on one side, 2nd harmonic dominates (triode). Symmetric clipping produces odd harmonics (push-pull behavior).

Voltage Gain

Av = μ × R_L / (rp + R_L)
Gain depends on where you are on the curves — it varies with the operating point.

Maximum Power

Pout = (V_swing × I_swing) / 8
Maximum undistorted power for Class A operation.

04 — Bias

Choosing the Q-Point

The bias point determines everything

Bias	Effect	Trade-off
Hot (high Ia)	More power, more gain	More heat, shorter tube life, thermal runaway risk
Center	Max symmetric swing	Optimal Class A — lowest distortion
Cold (low Ia)	Less power, cooler	Crossover distortion, thin sound, asymmetric clipping

The 70% Rule: Pd_idle ≈ 0.7 × Pd_max
Safe starting point — headroom for signal peaks

Use the interactive plotter above to experiment: drag the Vg slider and watch how the Q-point moves along the loadline. Notice how gain, plate current, and dissipation all change together.

05 — Safety

The Power Hyperbola

The curve you must never cross

Every tube has a maximum plate dissipation rating: Pd = Va × Ia. On the plate characteristics, this defines a hyperbola — a curve that the operating point must stay below at all times. The region above the hyperbola is the danger zone: operating there risks overheating the plate structure, outgassing, and destroying the tube.

When designing, your Q-point must sit below this curve, and the signal swing must not push instantaneous dissipation above the limit for extended periods. In Class A, the idle point is the maximum dissipation point (signal actually reduces average dissipation).

06 — Advanced

DC vs AC Loadline

Why the signal sees a different load than the DC bias

With a capacitor-coupled or transformer-coupled load, the AC load differs from the DC load. The plate resistor sets the DC operating point, but the signal sees the plate resistor in parallel with the next stage's input impedance (or the transformer's reflected impedance).

DC Load: R_L(DC) = Ra
Sets the Q-point

AC Load: R_L(AC) = Ra ‖ R_next
Sets the signal swing

The AC loadline pivots around the Q-point with a steeper slope (lower impedance). Enable the “Show AC loadline” checkbox in the plotter above to see this in action — the blue dashed line shows the AC load while the orange solid line shows the DC load.

This matters enormously for power stage design: the transformer reflects the speaker impedance back to the plate, creating an AC load that's typically much lower than the DC load through the output transformer primary winding.

07 — Reference

Key Equations

Everything you need for loadline analysis

Av = μ × R_L / (rp + R_L)

Z_out = rp ‖ R_L

Pd = Va × Ia

μ = Gm × rp

Rk = V_bias / Ia

Ck ≥ 1 / (2π × f_low × Rk)

P_out(max) = V_pp × I_pp / 8

R_L(AC) = Ra × R_next / (Ra + R_next)

The Koren SPICE model used in the interactive plotter calculates plate current from grid and plate voltage using the equation: Ia = (E1^Ex) / Kg1 where E1 is a function of Vp, Vg, μ, Kp, and Kvb. This gives accurate plate curves for circuit simulation without lookup tables.

Quiz de synthèse

Test Your Knowledge

Review the key concepts of loadline analysis for tube amplifier design.

Question 1 / 6

What two things define a DC loadline on the plate characteristics?

In the same category

Circuit Topologies

Understanding Loadlines

What Is a Loadline?

Live Loadline Calculator

Reading the Loadline

Choosing the Q-Point

The Power Hyperbola

DC vs AC Loadline

Key Equations

Test Your Knowledge

Amplifier Topologies

Phase Inverters

Feedback & Stability