Now read this attentively and you will learn why Hans Van Maanen is not in the ASR team but in science :
«The theory of Fourier analysis yields that the inverse Fourier transform of
the complex valued transfer function of any filter, and thus also of our
idealised audio system, equals the Dirac delta function response of the
system in time domain. Note that the impulse response thus tells us more
than the amplitude response of a system, because it contains information
about the amplitude response at ALL frequencies (not only those between 20
Hz and 20 kHz) and about its phase response, albeit in an implicit way.
idealised audio system, equals the Dirac delta function response of the
system in time domain. Note that the impulse response thus tells us more
than the amplitude response of a system, because it contains information
about the amplitude response at ALL frequencies (not only those between 20
Hz and 20 kHz) and about its phase response, albeit in an implicit way.
.........................................
In other words, any audio system has the tendency to "smear out" the signal
both in amplitude and in time. These effects could reduce subjective
experiences like the "definition" and "transparency" of the perceived
sound. This smearing will always be a degradation of the original sound and
we will try to study its influence on the perceived sound.
both in amplitude and in time. These effects could reduce subjective
experiences like the "definition" and "transparency" of the perceived
sound. This smearing will always be a degradation of the original sound and
we will try to study its influence on the perceived sound.
........................................................
The temporal decay of high-end analog audio systems is higher than the
decay of digital systems in their present version and consequently the
temporal "smearing" of the formers is less.
.............................................
The superior sound quality of moving coil cartridges over moving magnet
ones is at least partly due to the extended frequency response and higher
temporal decay. Moving magnet cartridges with extended frequency responses
approach the perceived quality of the moving coil cartridges, especially
those which produce a higher output signal (and thus generally speaking
have a lower mechanical resonance frequency). Compensation of the
mechanisms that create the low temporal decay of moving magnet elements
leads to significant improvement of their perceived quality (ref. 1, 2).
One of the better ways to compare analog and digital systems is by lis-
tening to a good copy of an analog recording on disc and the CD made of the
same master tape. If the digital re-processing would not audibly effect the
signal, no difference would be perceivable. Yet, on a high-end audio
system, using e.g. electrostatic loudspeakers for the midrange and high
frequencies, the transparency and clarity of the analog version (half-speed
master copies) invariably showed to be better.
Comparing loudspeaker systems is one of the most difficult and tricky
aspects of audio. Yet, generally speaking, the loudspeakers sounding best
are those with the highest temporal decay. To mention some examples:
electrostatics, ribbon tweeters and last-but-not-least ionophones. Also,
loudspeakers that show a high temporal decay in Wigner distributions
generally sound best.
ones is at least partly due to the extended frequency response and higher
temporal decay. Moving magnet cartridges with extended frequency responses
approach the perceived quality of the moving coil cartridges, especially
those which produce a higher output signal (and thus generally speaking
have a lower mechanical resonance frequency). Compensation of the
mechanisms that create the low temporal decay of moving magnet elements
leads to significant improvement of their perceived quality (ref. 1, 2).
One of the better ways to compare analog and digital systems is by lis-
tening to a good copy of an analog recording on disc and the CD made of the
same master tape. If the digital re-processing would not audibly effect the
signal, no difference would be perceivable. Yet, on a high-end audio
system, using e.g. electrostatic loudspeakers for the midrange and high
frequencies, the transparency and clarity of the analog version (half-speed
master copies) invariably showed to be better.
Comparing loudspeaker systems is one of the most difficult and tricky
aspects of audio. Yet, generally speaking, the loudspeakers sounding best
are those with the highest temporal decay. To mention some examples:
electrostatics, ribbon tweeters and last-but-not-least ionophones. Also,
loudspeakers that show a high temporal decay in Wigner distributions
generally sound best.
..........................................................................
The temporal decay seems to be a useful "handle" to get grip on the
temporal behaviour of audio systems and to make a semi-quantitative
comparison. It is an excerpt of the impulse response of a system, which
tells more about a system than its frequency response between 20 Hz and 20
kHz.
High-end audio systems often sound better with analog recordings than with
digital ones. This is at first surprising because of the very high quality
specifications of digital systems. But the temporal decay is one of the few
points at which analog systems beat their digital counterparts and it is
thus a clear hint of its importance.
The behaviour of the amplitude and phase characteristic of an audio system
above 20 kHz. is of importance to its temporal decay and can thus be of
influence on its perceived quality.»
temporal behaviour of audio systems and to make a semi-quantitative
comparison. It is an excerpt of the impulse response of a system, which
tells more about a system than its frequency response between 20 Hz and 20
kHz.
High-end audio systems often sound better with analog recordings than with
digital ones. This is at first surprising because of the very high quality
specifications of digital systems. But the temporal decay is one of the few
points at which analog systems beat their digital counterparts and it is
thus a clear hint of its importance.
The behaviour of the amplitude and phase characteristic of an audio system
above 20 kHz. is of importance to its temporal decay and can thus be of
influence on its perceived quality.»