A common opinion
among qualified audio experts (restated here by me) is that…
All modern audio
power amplifiers that present high input impedance (≥ 20 kΩ), very low output
impedance (≤ 0.2 Ω), flat power response (20 Hz–20 kHz ± 0.5 dB at rated
output), ultra-low distortion (≤ 0.1% THD at rated output), and a virtually
inaudible noise floor will sound exactly the same when operated at matched (±
0.25 dB) levels, not clipped, and properly connected to the same load.
Do appreciate that
amplifiers meeting the above specifications all sound the same because they
share a single common attribute: They are highly accurate. A power
amplifier that is accurate is one that faithfully replicates the original input
source signal without making any change, loss, or addition. Given this measured
assurance of accuracy, why do so many hi-end audiophiles conduct listening
trials to detect the audible difference between power amplifiers? Well, here’s
my opinion on…
Why listening
trials persist, and grief to avoid when conducting a listening trial…
1—Irrelevance: To
an overwhelming extent, today’s audiophiles are non-technical subjectivists*.
They have no interest (and little understanding) of the measurements that
define audio performance, and they don’t expressly seek accuracy. The
audiophiles’ primary goal is to identify equipment that renders euphonic sound;
i.e., sound that’s subjectively pleasing, and vacuum tube power amps
provide more range of choice. This accrues because…
(a) THD at rated
output runs > an order of magnitude higher for a tube-type power amp than on
a solid-state equivalent, and that difference might be audible.
(b) And because
transformer-coupled tube amps can’t approach the optimal low impedance drive of
solid-state power amps, where Zout is typically ≤ 0.1Ω. The tube amp’s higher
Zout will directly interact with the shifting Zin presented by the
loudspeaker/crossover load because both values will then be of similar order.
This will color the sound; the speaker’s sonic signature will differ slightly
from its natural voice. The result could be deemed either pleasing or
displeasing—a subjective option. Of course, the change will reflect degraded source
accuracy, but accurate sound was never the audiophile objective.
2—Expectation: Do
appreciate that it’s instinctive to assume that different amplifiers will sound
different. Indeed, for a great many decades (from the 1949 origin of “hi-fi”
until the early 1980s) most power amplifiers did sound different, and
their sound was materially affected by load impedance. Of course, few of those
power amplifiers met the stringent specifications cited in the opening
paragraph, so they were not highly accurate amplifiers, although some
might approach that goal when paired with a favorable load. When sampling
amplifiers today, some listeners still expect to hear such differences, and
some are certain to fulfill their expectation, regardless of the sound. Aural
perception is a fickle and fleeting sensation, prone to uncertainty and subject
to human frailty; be wary.
3—DC Offset
Orphans: Since power amplifier comparisons imply the probability of high
output operation, it’s helpful to know (for sure!) that your samples exhibit
only nominal DC offset. So measure the amps’ initial DC offsets before
running a listening trial. Don’t evaluate some random lemon with anomalous
excessive offset. Be certain that your intended samples truly represent the
breed. (Note: This need for offset screening applies only to direct-coupled
power amps; not to transformer-coupled amps.)
4—Marginal
Mavericks: If a comparison trial involves a power amplifier that is just marginally
accurate, that margin might prove audible. This generally involves an amplifier
with slightly out-of-spec power response, and the character of the aberration
might be perceived by a sensitive listener. Lots of audiophiles express
personal preference for a particular sort of biased sound
(warm/detailed/liquid/analytic, et al.) that marginally differs from source
reality. (In many cases they might do well to reassess their speakers’
crossover settings, rather than change their power amp.) Of course, a “maverick”
is an outcast, it’s generally not representative of the breed, so another
sample of the same model might not sound the same. Instrumented measurement is
a useful way to isolate marginal mavericks, and testing power response
(frequency response at high power output) is easily done, with basic test
equipment.
5—Output Level
Accuracy: All listening comparisons must be accomplished at precisely
identical output levels. This is best assured by actually measuring the
respective outputs at some appropriate (400-800 Hz) fixed test frequency, using
a microphone or sound level meter, mounted on a stand, and fixed precisely at
the intended listening position. Simply keeping the main volume dial at the
same position will not assure identical output because different
amplifiers exhibit different voltage gains. Most modern power amps have
internal voltage gains that fall between +23 dB and +29 dB, and some amps have
rear panel trim pots to independently adjust the left/right input balance. So,
(a) review the technical aspects and check the gain spec; (b) inspect
and adjust sample amplifiers as needed; then (c) listen as desired, but be
aware that you’ll learn very little if the amplifiers are accurate (see
opening).
6—Termination
Variables: In the course of disconnecting and reconnecting the speaker load
to the various amplifiers in a listening trial (and repeating that cycle
numerous times—often as quickly as possible), it’s quite likely that there
might be some variation in the uniformity of the termination. Indeed, sometimes
even different connector types are used (see photo**), with different results.
It’s really quite easy, in the course of this repetitive attach/detach process,
to introduce some contact inequality, and that variable could cause aural
disparity when conducting high power comparisons. To assure optimum signal
transfer it’s vital to carefully inspect, clean, reseat, and tighten all
terminations, and assure that all parts are in optimum visual alignment every
time that they’re mated.
7—Room Acoustics
& Comb Filtering: Aural comparison trials require that all acoustic
environs be uniform. This includes a precisely fixed position within the
listening space. It also means that the occupancy and every furnishing detail
must be exactly the same. Even a minor change can materially affect the
acoustic reflections and standing wave patterns, and these disruptions, however
slight, can alter the sound. Despite every effort to comply, the small
listening areas typical in most private homes can still yield appreciable (6
dB) variation over distances as small as four inches and frequencies as low as
200 Hz. This is the unfortunate consequence of comb filtering. (Refer
p.101-104 of “The Audio Expert”, by Ethan Winer [Routledge, 2nd edition,
2018], ISBN 978-0-415-78884-7.)
8—Sight Before
Sound: In a previous paper (refer “On Evaluating Audio Equipment…”), I
cited a significant study (http://www.pnas.org/content/110/36/14580),
conducted in 2013, describing the finding that visual cues convey far more
impact than any audible evidence. In sum, your eyes will implant a more
vivid and persistent impression than anything that you hear, and what you see
will determine what you think you hear. As a consequence, any
serious listening trial should be administered under blind test conditions. If
you know which amplifier is playing, you will be unable to render valid aural
judgement. The statistics in support of this finding are persuasive, and the
evidence is undeniable. Listening trial choices that were formed prior to
observing this guidance should be ignored.
9—Confirmation
Bias: When you’re comparing your old power amplifier against some new and
costly wonder that you’ve got on temporary loan, it’s very difficult to admit
that there might be no audible difference. And in the event that you’ve already
purchased that prized new model, I’d say that it’s not possible to
declare that both amps sound the same. We’re not robots.
BG (November 16, 2019)
*Among audiophile
organizations, the sole exception appears to be the Boston Audio Society, where
most members comprehend and respect the value of technical analysis in defining
product performance.
**The discrete banana
plugs that are shown in the photo are a bit unusual. They have an internal
free-floating slug that achieves uniform compression against the (side entry)
wire without transferring any twisting strain; see…
A TIP: If your amplifier’s rear clearance
(to wall) is especially tight, you can shorten these banana plugs (by 5mm) by
discarding the knurled end posts and substituting flat point metric set screws
(use M8–1.0 x 8mm) to retain the wires.
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