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Circuit Topology, Operating Point & Load Line Analysis
1. Introduction
The 3A5 (sometimes referred to as type 345 in early documentation) is a 7-pin, double directly heated triode originally designed as a battery-operated tube for radio receiver applications. While its published transconductance (Gm ≈ 1.8 mA/V) appears modest by modern standards, the tube’s intrinsic characteristics—namely a plate resistance of approximately 8.3 kΩ and a amplification factor (μ) of around 15—are entirely adequate for a wide range of audio voltage amplification tasks.
Most standard 3A5 datasheets emphasize battery operation and include characteristic curves intended for positive-grid operation, which tends to obscure an important aspect of the device: when operated in conventional Class-A, small-signal conditions, the 3A5 exhibits remarkably linear behavior. Despite its original classification as a battery receiver tube, it is fundamentally well suited for low-level audio voltage amplification when biased conservatively.
Although less celebrated than popular dual triodes, the 3A5 exhibits excellent linearity at modest plate voltages, making it particularly suitable for line-level preamplifier applications.
(The circuit diagram is shown for reference and informational purposes only)
This article examines a classic single-stage 3A5 line preamplifier circuit, focusing on real operating conditions rather than theoretical assumptions. The analysis is based directly on the original schematic, including annotated voltages.
2. Circuit Overview
Each channel employs a single 3A5 triode configured as a self-biased, RC-coupled voltage amplifier. The design priorities are clearly conservative:
Stable biasing
Moderate gain suitable for line-level sources
Low distortion through linear operating region selection
Excellent long-term reliability
3. Key Electrical Parameters
Parameter
Value
B+ Supply Voltage
+175 V
Plate Load Resistor
33 kΩ
Total Cathode Resistance
780 Ω (680 Ω + 100 Ω)
Cathode Bypass Capacitor
47 µF
Grid Leak Resistor
100 kΩ
Measured Plate Voltage
≈ 70 V
4. Reconstructed DC Operating Point
4.1 Plate Current Estimation
With a 33 kΩ plate resistor and a measured plate voltage of approximately 70 V:
Voltage drop across plate resistor: 175 V − 70 V = 105 V
Estimated plate current: 105 V / 33 kΩ ≈ 3.18 mA
Allowing for measurement tolerance and resistor variation, the realistic quiescent plate current lies between 2.5–3.0 mA.
4.2 Cathode Bias Voltage
With a total cathode resistance of 780 Ω:
Vk ≈ 2.1 V
This establishes a grid-to-cathode bias of approximately −2.1 V, safely below grid current onset and well within the linear transfer region of the 3A5.
5. Load Line Analysis
5.1 DC Load Line
The DC load line is defined by:
Vp = 175 V − Ip × 33 kΩ
At Ip = 0 mA → Vp = 175 V
At Vp = 0 V → Ip ≈ 5.3 mA
The chosen load line slope balances voltage gain and linearity, avoiding excessive plate current while maintaining useful headroom.
5.2 Quiescent Point (Q-Point)
The reconstructed Q-point is approximately:
Plate Voltage: ~70 V
Plate Current: ~2.7–3.0 mA
Grid Bias: ~−2.1 V
This placement slightly below the midpoint of the DC load line favors greater negative voltage swing and smooth overload behavior.
6. AC Load and Signal Swing
The effective AC load is determined primarily by the 33 kΩ plate resistor in parallel with the following stage input impedance. In practice, this yields an AC load of approximately 25–30 kΩ.
From the chosen operating point, the stage permits:
Upward plate voltage swing of approximately +45 V
Downward swing of approximately −30 V
This mild asymmetry is intentional and contributes to benign low-order harmonic structure.
7. Expected Voltage Gain
Using typical 3A5 parameters (μ ≈ 15–18, rp ≈ 6–7 kΩ):
Theoretical gain:
Av ≈ μ × RL / (RL + rp)
Practical measured gain after cathode degeneration is approximately 9–11× (19–21 dB).
This confirms the circuit’s role as a true line amplifier rather than a high-gain stage.
8. Distortion Characteristics
Because the load line intersects evenly spaced regions of the 3A5 transfer curves:
Second harmonic distortion dominates
Higher-order components are naturally suppressed
Overload behavior remains gradual and musically unobtrusive
This distortion profile is a direct consequence of operating point geometry, not subjective tuning.
9. Engineering Assessment
This 3A5 operating point represents disciplined, broadcast-grade engineering:
Conservative plate dissipation
Excellent tolerance to tube variation
High linearity at real listening levels
Minimal need for corrective feedback
10. Conclusion
The measured operating point and reconstructed load line confirm that this 3A5 preamplifier is optimized for clean voltage amplification, stability, and long-term reliability. It exemplifies how thoughtful bias selection and load line geometry directly translate into sonic quality.
LS3/5A Crossover Network Analysis: The Evolution of 15Ω and 11Ω Circuit Design
Published by IWISTAO
Abstract
The BBC LS3/5A is not simply a compact loudspeaker, but a precision monitoring instrument. Its legendary status owes far more to its crossover network than to driver selection alone. This article presents a detailed engineering analysis of the LS3/5A crossover evolution, focusing on the 15Ω FL6/23 and 11Ω FL6/38 production designs.
1. Design Philosophy: Beyond a Conventional Crossover
Unlike typical two-way loudspeakers, the LS3/5A crossover is not a simple electrical filter. It functions as a combined acoustic equalisation and impedance management system, designed to correct the inherent response irregularities of the KEF B110 and T27 drivers.
Driver response linearisation
Midrange resonance suppression
Phase and power response control
Controlled impedance for broadcast amplifiers
2. The 15Ω Era — FL6/23 Production Network
2.1 Historical Context
The FL6/23 crossover became the standard production network during the 1970s and early 1980s, designed for the KEF B110 SP1003 and T27 SP1032. Due to significant unit-to-unit driver variation, BBC engineers accepted the necessity of individual crossover calibration during production.
2.2 FL6/23 Circuit Topology
The FL6/23 network is best understood as three interacting functional blocks:
Low-Frequency Equalisation (B110)
An inductor-resistor network (L1 + R1) compensates for the rising low-frequency response introduced by cabinet loading and driver characteristics.
Midrange Notch Compensation
A carefully tuned RLC notch network (C5, L2, R2) suppresses the characteristic 600–1000 Hz cone-related response hump of the B110.
High-Frequency Network with Tapped Inductor
The most distinctive feature is the tapped HF inductor (L3), acting as a passive auto-transformer, allowing precise tweeter level adjustment without dissipative resistive padding.
2.3 Typical FL6/23 Component Values (15Ω)
Reference
Value
Function
L1
1.53 mH
LF equalisation
R1
82 Ω
LF attenuation
C5
6.2 → 10 µF
Midrange notch
L2
2.67 mH
Midrange notch
R2
33 → 22 Ω
Notch damping
L3
0.64 mH (tapped)
HF level control
C2
Selected under test
HF crossover
3. Transition to the 11Ω Version — FL6/38
3.1 Motivation for Redesign
In the mid-1980s, KEF introduced the B110 SP1228 with improved manufacturing consistency. This enabled a redesign of the crossover to reduce production variability and eliminate the need for individual HF trimming.
3.2 Key Architectural Changes
Aspect
15Ω (FL6/23)
11Ω (FL6/38)
HF Level Control
Tapped inductor
Resistive ladder
Production Tuning
Individual
Fixed
Nominal Impedance
~15 Ω
~11 Ω
3.3 11Ω Crossover Topology
The 11Ω crossover retains the conceptual LF and midrange correction networks but replaces the tapped HF inductor with a fixed resistive divider, resulting in improved consistency and smoother impedance behaviour.
4. Sonic and Engineering Implications
4.1 Measured Behaviour
15Ω: marginally smoother HF integration, more complex impedance
“The 15Ω system exhibits a slightly more organic HF integration, while the 11Ω version delivers improved focus and repeatability without compromising tonal neutrality.”
5. Conclusion
The evolution from FL6/23 to FL6/38 represents a shift from bespoke calibration to controlled manufacturing precision. Both designs remain authentic BBC solutions, demonstrating a level of passive crossover engineering rarely matched in modern loudspeakers.
The damping felt shall be installed after cabinet assembly and prior to final driver mounting.
Care should be taken to ensure that no material obstructs the driver aperture, crossover wiring, or terminal connections.
The felt should remain free from folds, gaps, or excessive compression, as these may alter its effective acoustic impedance.
4. Adjustment and Tuning
Differences in cabinet material, wall thickness, and construction method may result in variations in internal acoustic behaviour. Accordingly, the quantity of damping material may be adjusted to achieve optimum balance.
Insufficient damping may lead to audible coloration in the lower midrange.
Excessive damping may result in a perceived reduction in low-frequency extension and dynamic weight.
Final adjustment is best carried out by controlled listening tests, using programme material familiar to the operator.
5. Notes on Non-Standard Cabinets
For cabinets deviating from the original LS3/5A construction—including differences in internal volume, panel material, or bracing—the specified damping arrangement shall be regarded as a reference only.
Further adjustment may be required to maintain the intended frequency response and tonal balance.
6. Service and Replacement
The original quantity and placement should be restored where possible.
Replacement material should be of equivalent density, thickness, and fibre composition.
Mixing materials of differing acoustic properties is not recommended.
7. Engineering Commentary – Material Selection
The choice of acoustic damping material in the LS3/5A enclosure is governed by repeatability, stability, and predictable acoustic behaviour, rather than by absolute absorption efficiency alone.
High-density synthetic fibre felt of nominal 10 mm thickness provides a consistent and controllable acoustic impedance over the operating bandwidth of the system. Its properties remain largely unaffected by humidity, ageing, or long-term compression.
The selected thickness represents a balance between mid-band resonance control and preservation of low-frequency compliance. Excessive material thickness or mass loading may introduce over-damping.
Accordingly, the specified damping felt shall be regarded as part of the overall system design and not as an interchangeable component.
8. Listening Evaluation Notes
Listening evaluations were conducted to confirm the effectiveness of the specified damping arrangement, using programme material familiar to the evaluator.
With the recommended configuration correctly installed, the system exhibited a neutral and well-controlled mid-band presentation, with no audible cabinet-related coloration.
Comparative listening indicated that excessive damping reduced perceived low-frequency presence, while insufficient damping resulted in lower midrange coloration.
The specified arrangement was therefore found to be consistent with the original design intent of the LS3/5A system.
9. Summary and Concluding Remarks
The internal acoustic damping arrangement described herein shall be regarded as an integral element of the LS3/5A system alignment. When applied as specified, it provides predictable and repeatable acoustic performance consistent with the original design objectives.
Departures from this specification may be employed where necessary, but should be accompanied by appropriate acoustic measurement and controlled listening evaluation.
The Ultimate Guide to Essential Audio Cables: 3.5mm, XLR, and TRS Connections
Published by IWISTAO
In the world of audio, cables are the unsung heroes. They are the critical pathways that carry sound from your source to your ears, and choosing the right one can be the difference between a noisy, distorted mess and a crystal-clear, professional-grade signal. Whether you're a musician, a content creator, a DJ, or simply an audiophile looking to get the best from your gear, understanding the different types of audio cables is essential.
This guide will demystify some of the most common and versatile adapter cables you'll encounter: the 3.5mm to RCA, the 3.5mm to Dual XLR, the professional 6.35mm TRS to XLR, and the 3.5mm to Dual TRS for active monitors. We'll dive deep into their construction, use cases, and the crucial science behind them.
Before we explore specific cables, it's vital to understand the core concept that governs professional audio: the difference between balanced and unbalanced signals. This single factor dictates a cable's ability to reject noise, especially over longer distances.
A visual comparison of balanced (three-conductor) and unbalanced (two-conductor) wiring schemes.
Unbalanced Cables
An unbalanced cable uses two conductors: a signal wire and a ground wire. The ground wire also acts as a shield against interference. Common unbalanced connectors include RCA and TS (Tip-Sleeve) jacks, like those on a standard guitar cable.
How it works: A single audio signal travels down the center conductor.
Vulnerability: The shield can act like an antenna, picking up electromagnetic interference (EMI) and radio frequency interference (RFI) from nearby power cords, lights, and electronics. This unwanted noise is added directly to your audio signal.
Best for: Short cable runs (under 15-20 feet / 5-6 meters) in environments with low electrical noise.
Balanced Cables
A balanced cable uses three conductors: two signal wires (a "hot" and a "cold") and a separate ground shield. The most common balanced connectors are XLR and TRS (Tip-Ring-Sleeve).
How it works: The audio signal is duplicated. One copy (the "hot" signal) is sent as is, while the other ("cold" signal) has its polarity inverted. Both wires pick up the same amount of noise along the cable's length.
The Magic: At the receiving end, the destination device flips the polarity of the "cold" signal back. This causes the two original audio signals to reinforce each other, doubling their strength. Crucially, the noise on both lines, now in opposite polarity, cancels itself out. This process is called Common Mode Rejection.
Best for: Long cable runs, professional studio recording, live sound, and any environment where signal purity is critical.
The principle of common-mode rejection: noise is induced equally on both signal lines and is canceled out at the receiver, leaving a clean audio signal.
Now, with this fundamental knowledge, let's explore our specific cables.
1. The Ubiquitous Connector: 3.5mm to Dual RCA Cable
This is one of the most common consumer audio cables, a simple and effective tool for bridging the gap between portable devices and home stereo systems.
What It Is
This cable takes a stereo unbalanced signal from a single 3.5mm TRS plug (the standard headphone jack) and splits it into two separate mono signals via two RCA plugs. The RCA connectors are almost universally color-coded: red for the right channel and white (or black) for the left channel.
Common Use Cases
The primary function is to connect devices with a 3.5mm headphone output to equipment that uses stereo RCA inputs. This is an entirely unbalanced signal path.
Connecting a smartphone, tablet, or laptop to a home theater receiver or stereo amplifier.
Plugging an MP3 player into a set of powered speakers with RCA inputs.
Connecting a portable audio source to some DJ mixers or older audio equipment.
Technical Deep Dive
Connectors: The 3.5mm TRS plug has three parts: the Tip (carries the left channel), the Ring (carries the right channel), and the Sleeve (serves as the common ground). The RCA connector, a design from the 1940s, uses a center pin for the signal and an outer ring for the ground.
Wiring: The Tip of the 3.5mm plug is wired to the center pin of the left (white) RCA plug. The Ring is wired to the center pin of the right (red) RCA plug. The Sleeve is connected to the outer ground shield of both RCA plugs.
Build Quality: Look for cables with gold-plated connectors, which provide excellent conductivity and resist corrosion over time. Oxygen-Free Copper (OFC) conductors are preferred for minimal signal degradation. While it's an unbalanced cable, good shielding (foil or braided) can still help reduce some interference.
2. Prosumer Power: 3.5mm to Dual XLR Y-Splitter Cable
This cable is a powerful tool for interfacing consumer-level gear with professional audio equipment like mixers and powered monitors. It correctly splits a stereo signal into two separate mono lines for professional inputs.
This Y-splitter cable is essential for connecting stereo sources like laptops to professional mono inputs on mixers or speakers.
What It Is
This Y-splitter cable takes a stereo unbalanced signal from a 3.5mm TRS source and separates it into two discrete signals, sending them to two XLR male connectors. This allows you to feed the left and right channels into separate inputs on a professional device.
Common Use Cases
This is the go-to solution when you need to get high-quality audio from a consumer device into a professional sound system.
Connecting a laptop or smartphone to a mixing console for playing backing tracks or DJing.
Feeding the audio from a tablet into a pair of active studio monitors that have XLR inputs.
Connecting a portable audio recorder's output to a PA system for playback.
Technical Deep Dive & Wiring
The wiring of this cable is critical for proper function. It converts a stereo unbalanced output into two signals suitable for balanced mono inputs.
Wiring Scheme:
The Tip (Left Channel) of the 3.5mm plug is wired to Pin 2 (Hot) of the first XLR connector.
The Ring (Right Channel) of the 3.5mm plug is wired to Pin 2 (Hot) of the second XLR connector.
The Sleeve (Ground) of the 3.5mm plug is wired to both Pin 1 (Ground) and Pin 3 (Cold) on *both* XLR connectors.
Why this works: By connecting the ground to Pin 3 (the cold input), you are feeding an unbalanced signal into a balanced input correctly, preventing phase issues and potential signal loss.
Features: High-quality versions of this cable often feature color-coded rings (e.g., blue for left, red for right) on the XLR connectors for easy channel identification. Robust shielding is also crucial to protect the signal before it reaches the balanced inputs of the professional gear. Note the "splice distance"—the length of the individual cables after the Y-split—to ensure they can reach two separate speakers.
3. The Studio Standard: 6.35mm TRS to XLR Cable
This is a cornerstone of any professional or home studio setup. It is designed to carry a pure, noise-free balanced mono signal between professional-grade audio devices.
The 6.35mm TRS to XLR cable is a workhorse for connecting interfaces, mixers, and studio monitors.
The Core Concept: A True Balanced Connection
Unlike the adapter cables discussed previously, this cable connects two devices that both support balanced audio. The 6.35mm (1/4-inch) TRS connector and the 3-pin XLR connector are both designed to handle the three conductors (Hot, Cold, Ground) required for a balanced circuit. This ensures maximum noise rejection and signal integrity, making it ideal for critical recording and monitoring applications.
Use Cases: TRS to XLR Male
This is the most common configuration, used to connect a balanced output to a balanced input.
Connecting the balanced TRS outputs of an audio interface or mixing console to the XLR inputs of active studio monitors.
Linking a mixer's main or aux outputs to a power amplifier's inputs.
Connecting professional audio processors (like equalizers or compressors) in a signal chain.
Use Cases: TRS to XLR Female
This configuration is often considered a "problem-solver" cable, allowing you to connect a device with an XLR output to a TRS input.
Connecting a microphone directly to a mixer or interface that only has a balanced 1/4-inch line input available.
Running the XLR output from a DI box into a TRS input on a stage snake or mixer.
A lifesaver for gigging musicians who encounter unexpected input types on house equipment.
Technical Specs & Build Quality
The quality of a balanced cable is paramount for professional results.
Conductors & Gauge: Look for 20-24 AWG (American Wire Gauge) OFC (Oxygen-Free Copper) conductors. A lower AWG number means a thicker wire, which is better for reducing signal loss over very long runs (over 50 feet / 15 meters).
Shielding: This is critical. A combination of foil shielding (for high-frequency RFI rejection) and a dense braided or spiral copper shield (for low-frequency EMI and hum rejection) provides the best protection. Look for >95% shield coverage.
Connectors: Professional-grade connectors from brands like Neutrik are a sign of quality. Features to look for include robust zinc alloy or metal housings, secure locking mechanisms on the XLR end, and effective strain relief to prevent damage from bending and pulling.
The internal construction of a high-quality cable, featuring OFC conductors, cotton yarn filler, foil shielding, and a braided copper shield for maximum noise rejection.
4. Active Monitor Connection: 3.5mm to Dual 6.35mm TRS Cable
This cable is similar in concept to the 3.5mm-to-XLR splitter but is designed for equipment that uses 1/4-inch TRS inputs, which are common on many studio monitors and mixers.
What It Is
This cable takes a stereo unbalanced signal from a 3.5mm TRS plug and splits it into two separate 6.35mm (1/4-inch) TRS plugs. It';s important to note that while the destination plugs are TRS, the signal they carry from this specific cable configuration is typically unbalanced mono.
Common Use Cases
This cable is perfect for connecting stereo sources to devices with dual 1/4-inch inputs.
Connecting a laptop or audio player directly to a pair of active studio monitors that have TRS inputs.
Plugging a portable device into a stereo line-in channel on a mixing console that uses two 1/4-inch jacks.
Connecting the headphone output of a small device to a larger amplifier or audio interface for recording or re-amping.
Technical Deep Dive & Wiring
The wiring for this cable is straightforward but important to understand.
Wiring Scheme:
The Tip (Left Channel) of the 3.5mm plug is wired to the Tip of the first 6.35mm plug.
The Ring (Right Channel) of the 3.5mm plug is wired to the Tip of the second 6.35mm plug.
The Sleeve (Ground) of the 3.5mm plug is connected to the Sleeve of both 6.35mm plugs.
Unbalanced Signal: Because the Ring on each of the 6.35mm destination plugs is not used (or is shorted to the sleeve), each line carries an unbalanced mono signal. This is perfectly acceptable for the short distances typically found in a desktop studio setup.
Build Quality: As with other cables, look for durable jackets (like nylon braid), good shielding, and well-made connectors to ensure a reliable connection and minimize noise.
Conclusion: Choosing the Right Cable Matters
Cables are far more than simple accessories; they are integral components of your audio signal chain. Understanding the difference between balanced and unbalanced signals and knowing which cable to use for a specific task is a fundamental skill for anyone serious about audio quality.
By investing in well-made cables with the correct connectors and wiring for your application, you ensure that your signal remains as pure and noise-free as possible. Whether you're connecting your phone to a stereo, your laptop to a professional mixer, or your audio interface to studio monitors, the right cable will help you achieve the best possible sound. Always check the inputs and outputs of your gear, consider the length of the cable run, and choose quality construction to build a reliable and high-fidelity audio setup.
LS3/5A and Tube Amplifiers: A Practical Matching Experience
Published by IWISTAO
Why LS3/5A is often described as “not happy without tubes,” and what really makes the pairing work.
1. Understanding the Nature of the LS3/5A
The BBC LS3/5A is a rare loudspeaker in the hi‑fi world. Small in size, limited in absolute output, yet extraordinarily revealing of system quality. It is not a speaker that rewards brute force or excessive power.
Whether in its 11‑ohm or 15‑ohm versions, the LS3/5A does not primarily demand current delivery. Instead, it responds most clearly to voltage stability, linearity, and micro‑dynamic resolution. Its lightweight cone and dense midrange information expose the character of the driving amplifier with little mercy.
This fundamental trait explains why amplifier choice matters more here than with many modern loudspeakers.
2. Why Tube Amplifiers Fit the LS3/5A So Naturally
Many listeners encounter similar issues when driving LS3/5A with transistor amplifiers:
Thin or dry tonal balance
Over‑tight imaging with limited harmonic bloom
Reduced emotional engagement at low listening levels
When a well‑designed tube amplifier replaces the solid‑state unit, the change is usually not subtle:
Midrange density increases noticeably
Vocals gain body, stability, and realism
Reverberation tails become longer and more natural
Music remains complete and expressive even at low volume
This is not simply “tube warmth.” It is the result of a driving method that aligns closely with the LS3/5A’s electrical and mechanical behavior.
3. 15 Ohm vs 11 Ohm: Differences from a Tube Perspective
15‑Ohm Versions
Classic 15‑ohm LS3/5A models tend to integrate exceptionally well with traditional tube output transformer designs. In practice, they offer:
Higher mid‑high frequency density
A more relaxed and unforced presentation
Greater sense of depth and room ambience
For listeners committed to tube amplification, the 15‑ohm version often feels more natural and less constrained.
11‑Ohm Versions
Later 11‑ohm LS3/5A models are more tolerant of solid‑state amplification and present a slightly more neutral, controlled character. With tube amplifiers they still perform beautifully, though often with a touch less openness and bloom compared to their 15‑ohm counterparts.
4. Tube Types and Their Sonic Tendencies
300B Single‑Ended Amplifiers
Among all options, 300B single‑ended designs often deliver the most convincing results with LS3/5A:
Exceptionally rich and textured midrange
Strong vocal intimacy and emotional presence
Stable tonal balance at very low listening levels
This pairing reflects the original design philosophy behind LS3/5A more closely than almost any other.
These tubes can sound extraordinarily transparent and refined, but demand ideal system conditions. Room acoustics, volume level, and recording quality become critical. When perfectly matched, the result is exquisite; when not, the sound may feel fragile or undernourished.
5. Output Impedance and Transformer Taps
A frequently overlooked issue is output transformer matching. Using an 8‑ohm tap to drive an 11‑ohm LS3/5A will not damage equipment, but it is rarely optimal.
Impedance mismatch affects damping factor, bass articulation, and tonal density. Whenever possible, selecting the transformer tap closest to the loudspeaker’s nominal impedance yields the most balanced and coherent sound.
6. The Overlooked Strength: Low‑Volume Listening
Perhaps the greatest advantage of the LS3/5A paired with tube amplification lies in low‑volume performance. Late‑night listening reveals:
Complete vocal structure
Stable instrumental proportion
Preserved emotional narrative
Many modern high‑resolution systems fail precisely in this area.
Conclusion
The LS3/5A is not a universal loudspeaker. It has clear limits in scale and output. Yet when driven by a carefully chosen tube amplifier and listened to within its natural boundaries, it offers something rare: a long‑term, emotionally sustainable relationship with music.
It may not always impress instantly, but it is remarkably difficult to replace.
When it comes to hi-fi, the British BBC LS3/5A is a hurdle almost no audiophile can avoid. If you try to list the loudspeakers that have not only survived decades but also appreciated dramatically, the LS3/5A would likely rank near the very top.
In 2004, Taiwan’s Audio Forum published a supplement titled Everlasting Classics, and one article there pointed out that the LS3/5A was among the most recommended and most frequently featured pieces of equipment. Twenty-one years have passed since then—and even today, the situation has not changed much.
Early Research: Hong Kong and “Ah Ming”
The earliest person to conduct a dedicated, systematic study of the LS3/5A was a Hong Kong audiophile known as “Ah Ming.” Many years ago, he self-published a book titled The Immortal Legend of Loudspeakers: LS3/5A, priced at HKD 80 at that time. Although deeper research later revealed a few inaccuracies in that book, for LS3/5A fans at the time, it was practically a must-have—almost everyone owned a copy.
15Ω and 11Ω: Two Production Eras
From 1974 to 1987, the LS3/5A belonged to what is often called the 15-ohm era. The main producers included Rogers, Spendor, Audiomaster, Chartwell, Goodmans, and RAM.
From 1988 to 1998, it entered the 11-ohm era, with production mainly by Rogers, Spendor, Harbeth, and KEF. Among these, the two brands that truly spanned both eras were Rogers and Spendor.
The LS3/5A earned its fame in the 1980s, but it reached the broader market largely in the late 1980s— primarily during the 11-ohm period. It then became widely popular amid the early-1990s audiophile boom, continuing until 1998, when KEF discontinued the T27 tweeter and B110 mid-bass driver. In other words, during the hottest years of the 1990s, most people were actually listening to 11-ohm LS3/5A, and Rogers / Harbeth / KEF / Spendor effectively “ruled the world.”
Why LS3/5A Became My First Target (1995)
When I planned to buy my first hi-fi system in 1995, my target was already the LS3/5A. There were two major influences behind that decision.
Influence #1: A 1994 Magazine Article That Shaped My Thinking
In 1994, while browsing the CD section of a bookstore, I discovered a magazine called Audiophile (I believe it was the second issue). Inside was a beginner’s guide article titled “A Hi-End Starter Audio System”, which had a strong impact on me.
That article was my first real introduction to the idea of the “British sound.” It argued that when choosing speakers, it is best to start with classic British designs that prioritize midrange integrity and soundstage construction—ideally BBC-derived designs like the LS3/5A. This approach, it said, is hard to get wrong, holds value well, and delivers strong musical expressiveness. It even suggested using a tube amplifier (such as 300B tube amp) and a CEC 891R CD player—spending modestly, yet establishing a correct listening philosophy.
Looking back now, those viewpoints were surprisingly solid. It really was a proper path for beginners. From then on, I developed a deep affection for the BBC-influenced British sound.
Influence #2: A Spark Audio Demo That Sounded Like Heaven
The second influence happened around January 1995. Spark Audio—newly founded at the time—held a small promotional event. If I remember correctly, there were two sessions, and I attended both.
Spark showcased two tube amplifiers: the Model 560 using FU29 tubes, and the Model 550 using 300B tubes. The event mainly used the 560. The speakers included a pair of Rogers 11-ohm rosewood BBC LS3/5A, an LS5/9, and a pair of PSB 800 floorstanders.
The Rogers LS3/5A belonged to the host himself—well known as a radio program presenter in the audiophile world. He wasn’t tall, wore a small mustache (a bit like George Lam), had a musical background, spoke with wit and ease, and hosted the event brilliantly.
When the 560 drove the LS3/5A, the sound was, to me at that time, simply otherworldly. I still remember listening to Zhu Zheqin’s Yellow Children. The top-end had excellent density—warm, sweet, and smooth. The musical expression was rich and deeply moving. That demonstration left the LS3/5A with an exceptionally beautiful image in my mind.
When LS3/5A Sounds Bad (Yes, It Can Happen)
Of course, I have also heard LS3/5A systems that sounded genuinely poor. For example, at the audio section of a foreign-language bookstore, there was a Rogers LS3/5A paired with an AB1 bass unit. And at a hi-fi center, I heard a Rogers 11-ohm pair. In both cases, they were driven by a Rotel integrated amplifier (the 960BX, if I recall correctly). The speakers were severely under-driven—nothing opened up, and the results were disappointing.
That’s the thing about the LS3/5A: if you don’t drive it properly, it can make you doubt the legend itself. (Laughs.)
The Long “Knot in the Heart” (1995 → 2015)
Even in the autumn of 1995, I still didn’t manage to buy an LS3/5A. The reason was simple: the dealers had no Rogers stock. Harbeth was available, but it cost 11,500 HKD—far beyond my budget. Spendor and KEF were rare and not cheap either. Later, around 1998, a Spendor pair cost about 9,300 HKD, while a piano-black KEF version was even more expensive—around 14,000 HKD.
Still, the LS3/5A remained a “knot in my heart.” Before 2015, I owned several speakers; two of them leaned heavily toward the traditional British sound: the Castle Inversion 15 and the Harbeth Super HL5 in rosewood. Finally, in the autumn of 2015, I acquired a Spendor 11-ohm LS3/5A with a bi-wire crossover— and that long-held wish was finally fulfilled.
A few years later, I added a second pair: a ProAc LS3/5A in ebony veneer. At that point, I owned two pairs of 11-ohm LS3/5A at the same time.
Living with Two Pairs of 11-Ohm LS3/5A
I drove these two LS3/5A pairs with two amplification setups: an Exposure 15.2, and a classic Naim chain consisting of a NAC 32 preamp, SNAPS power supply, and NAP 160 power amp.
Overall, the two 11-ohm LS3/5A pairs were remarkably consistent in their character. Compared with the ProAc Super HL5 30th Anniversary (rosewood) that I had used for a long time, the LS3/5A put more emphasis on vocals—more captivating and emotionally “pulling” in a direct way. Vocals separated from the ensemble more clearly. The upper-mid and treble density was higher than the Super HL5, and female vocals had stronger penetration. The presentation felt more active and animated.
The decay was longer and more flavorful, and the treble stood out more. Naturally, the bass quantity was not as abundant as the Super HL5—after all, this is a 5-inch driver— but it still conveyed a convincing sense of scale. Imaging and localization were exceptionally strong; that advantage was obvious.
The Super HL5’s strength, on the other hand, is its ability to build atmosphere and tell a musical story— its sense of emotional narration is truly wonderful.
Back to 15 Ohms (2024 → Present)
In November 2024, since I no longer had either of my 11-ohm LS3/5A pairs, I purchased a pair of Rogers black-label 15-ohm LS3/5A, paired with Yue stands. A 15-ohm pair is something you simply must own—at least that’s how it feels. (Laughs.)
Then, in September of this year, to properly match the 15-ohm LS3/5A, I acquired a Line Magnetic “Ange” AS-135 300B single-ended tube amplifier and upgraded the full set of tubes.
With the AS-135 driving the LS3/5A, everything felt perfectly “on the right track.” The black-label LS3/5A seemed to grow into a small giant: richer midrange body, longer trailing decay, extremely high mid-to-high density, and abundant detail. The overall performance clearly surpassed what I achieved with my previous solid-state amplifiers.
Once again, this confirmed an old belief: the LS3/5A is better suited to voltage-driven tube amplification. The saying “LS3/5A won’t sing without tubes” truly has a solid basis.
Conclusion
For veteran audiophiles, owning a pair of LS3/5A almost feels like a matter of course. As for which brand—or whether it is 11 ohms or 15 ohms—those details feel less important in the end.
Because in the world of BBC LS3/5A, there is one simple truth: If it’s an LS3/5A, it sounds good.
DIY Tube Amplifier Testing and Adjustment --A Practical Engineering Guide
Published by IWISTAO
Building a DIY tube amplifier is never just about getting sound. True performance, reliability, and tube longevity depend on systematic testing and precise adjustment.
Improper setup may lead to shortened tube life, unstable bias, excessive transformer heating, or even catastrophic failure. This article provides a complete, practical workflow for testing and tuning DIY tube amplifiers, suitable for both single-ended (SE) and push-pull (PP) designs.
1. Pre-Power-On Inspection (Mandatory)
Before connecting the amplifier to mains power, every circuit must be carefully inspected. Even a small wiring error can cause:
Output tube damage
Electrolytic capacitor failure
Burned power or output transformers
1.1 Visual and Wiring Checks
Correct polarity of all electrolytic capacitors
Proper orientation of rectifier tubes or diode bridges
No accidental grounding of output transformer primary
Clear separation of signal ground and protective earth (PE)
Presence of grid-leak and screen-grid resistors
Practical experience: More than 80% of first power-up failures originate from power-supply wiring or grounding mistakes.
More details about grounding, please refer to the post below.
