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Push-Pull Amplifiers

The symmetrical output topology that enabled high-fidelity power amplification. From the Williamson to the Dynaco ST-70, push-pull defined an era of audio engineering.

Fundamentals

Why Push-Pull?

The topology that made high-fidelity power amplification practical

~Even Harmonic Cancellation

The symmetrical topology cancels 2nd, 4th, and 6th harmonics. Only odd harmonics remain, giving a cleaner signal at high power.

2xDouble the Power

Two tubes share the load. A pair of EL34s in push-pull can deliver 50W or more, versus 8-12W from a single-ended EL34.

0DC Cancellation in Transformer

Plate currents flow in opposite directions through the output transformer primary, cancelling DC magnetization and preventing core saturation.

FeBetter Transformer Utilization

No DC bias in the core means smaller transformers can handle more signal power. The full B-H curve is available for signal swing.

dBLower Hum

Power supply ripple is a common-mode signal that gets cancelled in the output transformer, significantly reducing residual hum.

ηHigher Efficiency

Class AB push-pull can reach 60-78% efficiency versus the 25-50% ceiling of single-ended Class A.

Single-ended: Pout ≈ Vswing² / (2 × Zload)    |    Push-Pull: Pout ≈ 2 × Vswing² / Zp-p
Topology

Push-Pull Circuit

Long-tailed pair phase inverter driving matched output tubes through a center-tapped transformer

B+B+Rp1Rp2VinRg2RtailLONG-TAILED PAIRV3V4B+RkRkB+OUT+OUT−▶ +signal▶ −signalPUSHPULL
Phase Inverter

The LTP splits the input into two equal, anti-phase signals. Grid 2 is AC-grounded; the shared tail resistor sets common-mode rejection.

Output Stage

Each tube amplifies one half of the signal. When V3 plate current increases, V4 plate current decreases, and vice versa.

Transformer

The center-tapped primary combines both halves. DC cancels (no core saturation), while the signal adds constructively.

Operating Class

Class A vs Class AB

Adjusting bias point determines conduction angle, efficiency, and distortion character

Bias0.5
Operating ClassClass AB
Conduction Angle270deg
Efficiency~60-78%
Key Differences

Class A (360°): Both tubes conduct the full cycle. Maximum linearity, lowest distortion, but limited efficiency. Idle current equals maximum signal current.

Class AB (180–360°): Tubes share duty at high levels. Small crossover region adds odd harmonics but dramatically increases power output.

Crossover distortion occurs when neither tube fully conducts during the transition. Proper bias minimizes this notch.

Calculator

Push-Pull Power

Estimate output power and operating conditions for common PP output tubes

Output Tube
B+450V
Operating Mode
Tube Limits
Max plate V: 800VMax plate W: 25W
Plate-to-Plate Z6.6kΩ
Voltage Swing315V peak
Output Power15W
Plate Dissipation12W/tube
Dissipation Headroom52%
Pout(PP) ≈ 2 × Vswing² / Zp-p
Classic Design

The Williamson Architecture

The 1947 circuit that defined high-fidelity: four stages with global negative feedback

InputVoltage Amp6SN7 / 12AX7PhaseSplitter6SN7 (LTP)DriverStage6SN7 (×2)OutputStageKT66 PPGLOBAL NEGATIVE FEEDBACK (20dB)
1Input Voltage Amp

High-gain common cathode. Sets overall sensitivity and provides voltage gain.

2Phase Splitter

Long-tailed pair produces two equal anti-phase signals with low distortion.

3Driver Stage

Cathode-coupled drivers provide low impedance to swing the output grids.

4Output Stage

Push-pull output with global negative feedback for low distortion and flat response.

THD at 1W
<0.1%
Bandwidth
10Hz–100kHz
Output Power
15W (KT66)
Practical

Tube Matching

Push-pull demands symmetry. Mismatched tubes reintroduce the problems PP was designed to solve.

Mismatch0%
DC Imbalance0mA
2nd Harmonic<0.1%
Core Saturation RiskLow
What to Match
  • Idle currentwithin 5% at the same bias voltage
  • Transconductance (Gm)within 10% ensures balanced gain
  • Plate resistance (rp)affects load sharing
Bias Methods in PP

Fixed bias (adjustable): Individual bias pots per tube allow precise balancing. Preferred in high-power designs (Marshall, Fender). Requires periodic adjustment.

Shared cathode bias: Single shared cathode resistor auto-balances DC but limits the benefit of matching. Common in lower-power designs (Vox AC30).

Individual cathode bias: Separate cathode resistors for each tube. Good compromise; each tube self-biases but no adjustability.

Reference

Classic PP Designs

Landmark amplifiers that defined eras of audio and music

Dynaco ST-70

1959
Tubes
EL34 (×4)
Power
35W/ch
Mode
Ultralinear
Zp-p
6,600Ω

The evergreen audiophile amplifier. Warm midrange, smooth treble, exceptional value. Millions produced.

Williamson

1947
Tubes
KT66 (×2)
Power
15W
Mode
Triode
Zp-p
10,000Ω

The first true hi-fi amplifier. Set the standard for low-distortion design with global feedback.

Fender Twin Reverb

1965
Tubes
6L6GC (×4)
Power
85W
Mode
Pentode (fixed bias)
Zp-p
3,800Ω

Clean headroom monster. The studio standard for clean guitar tone. Bright, percussive attack.

Marshall JTM45

1962
Tubes
KT66 / EL34 (×2)
Power
30-45W
Mode
Pentode (cathode bias)
Zp-p
6,600Ω

Based on the Fender Bassman. The birth of British rock tone. Rich harmonic breakup.

McIntosh MC275

1961
Tubes
KT88 (×4)
Power
75W/ch
Mode
Unity-Coupled
Zp-p
4,000Ω

The reference power amplifier. Patented unity-coupled transformer. Authoritative bass, silky highs.

Reference

Key Equations

Essential formulas for push-pull amplifier design

Push-Pull Power
PP Output PowerPout = 2 × Vswing² / Zp-pTheoretical maximum; practical output is 50-70% of this
Plate-to-Plate LoadZp-p = 4 × ZsingleThe reflected impedance is 4× the single-ended equivalent
Max Voltage SwingVswing ≈ B+ − Vk − VsatAvailable signal swing per tube (triode: ~55%, pentode: ~85% of B+)
Efficiency (Class A)η = Pout / (2 × Vb × Iq) ≤ 50%Theoretical max; practical ~25-35%
Efficiency (Class AB)η ≤ 78.5%Practical range 50-65% for tube PP
Phase Inverter (LTP)
Tail CurrentItail = (Vk − 0) / RtailSets the operating current for both tubes
CMRRCMRR ≈ 1 + 2×gm×RtailCommon-mode rejection improves with larger tail resistor
BalanceVout1/Vout2 ≈ 1 ± 1/μInherent balance of LTP; better than cathodyne
Output Transformer
Turns RatioN = √(Zp-p / Zload)Primary-to-secondary turns ratio for impedance matching
DC BalanceΔI_DC should be < 5%Unbalanced DC causes core magnetization (2nd harmonics)
Primary InductanceLp > Zp-p / (2π × flow)Sets the low-frequency −3dB point
Bias & Operating Point
Fixed BiasVg = −(Pd / Ip) adjustedSet for 70% of max plate dissipation for Class AB
Cathode Bias (shared)Rk = Vbias / (2 × Iq)Shared resistor; current from both tubes flows through Rk
Bypass CapCk > 1 / (2π × f × Rk)Bypasses Rk for AC; maintains gain at signal frequencies
Quiz de synthèse

Test Your Knowledge

Validate your understanding of push-pull amplifier design.

Question 1 / 7

What is the main advantage of push-pull over single-ended topology?

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