As is usually the case, I am in 100% agreement with the post by Larryi. As an illustration of his point about dynamic compression of classical recordings, I’ll mention that I have had occasion to examine the waveforms of a couple of classical orchestral recordings that I believe have been engineered with no compression. Namely the Telarc recording of Stravinsky’s Firebird Suite, Robert Shaw conducting the Atlanta Symphony, and the Sheffield Labs recording of excerpts from Prokofiev’s Romeo & Juliet, Erich Leinsdorf conducting the Los Angeles Philharmonic. I have done this on a computer, using a professional audio editing program.
In each case I observed a dynamic range (the difference in volume between the loudest notes and the softest notes) of approximately 55 db, which I consider to be an amazing "tour de force." Correspondingly, when I listen to those recordings at my preferred volume settings, with average SPLs somewhere in the 70s at my 12 foot listening distance, the softest notes are in the vicinity of 50 db or so, with the loudest notes reaching close to 105 db at my listening position. Also correspondingly, a dynamic range of 55 db means that the amplifier must supply approximately 316,000 times as much power to reproduce the loudest notes as to reproduce the softest notes. (And 316,000 is not a typo).
I believe it is safe to say that many and probably the majority of audio systems, including the majority of systems used by serious audiophiles such as those who are members here, would not be capable of handling such recordings at volume levels that are high enough to satisfy many listeners. With the most common limiting factor perhaps being the maximum volume capability of the speakers. And perhaps in some cases, and at some times, the ambient noise level in the room.
On another subject:
First, I’m not sure how familiar you may be with the Nyquist-Shannon sampling theorem. There is no "bit-sum averaging" involved in the process. And if by that you meant "interpolation" that is not involved either. And the reference to playback being "artificially synthesized" is a misconception. What is involved is low pass filtering, in the recording process at the input to the A/D converter, to prevent "aliasing," and in the reproduction process to reconstruct the analog signal. And the 16 bit quantization that is used in CDs can, if well implemented, provide a dynamic range of approximately 96 db (actually slightly more than that), which can be further enhanced by "dithering." And theoretically/potentially, at least in the case of an infinitely long series of samples, the 44.1 kHz sample rate can support a bandwidth of 22.05 kHz, without any "averaging" or "interpolation" or "artificial synthesizing" or information being "left out."
If you believe that the LP medium is inherently superior to the CD medium I suggest that instead of focusing on (and misapplying) theory you consider the potential side effects of the two filters that I mentioned, and probably more importantly on the engineering of the recordings, and perhaps most importantly on the quality of the circuit designs that are used in the specific equipment that is used for both recording and playback.
Regards,
-- Al
In each case I observed a dynamic range (the difference in volume between the loudest notes and the softest notes) of approximately 55 db, which I consider to be an amazing "tour de force." Correspondingly, when I listen to those recordings at my preferred volume settings, with average SPLs somewhere in the 70s at my 12 foot listening distance, the softest notes are in the vicinity of 50 db or so, with the loudest notes reaching close to 105 db at my listening position. Also correspondingly, a dynamic range of 55 db means that the amplifier must supply approximately 316,000 times as much power to reproduce the loudest notes as to reproduce the softest notes. (And 316,000 is not a typo).
I believe it is safe to say that many and probably the majority of audio systems, including the majority of systems used by serious audiophiles such as those who are members here, would not be capable of handling such recordings at volume levels that are high enough to satisfy many listeners. With the most common limiting factor perhaps being the maximum volume capability of the speakers. And perhaps in some cases, and at some times, the ambient noise level in the room.
On another subject:
Sleepwalker65 10-4-2018
@dynaquest4 and @cleeds you are glossing over the fundamental issue with going digital: it does not capture the infinite range of undulations. Rather, the process quantizes the input program material at the sampling frequency, and then stores it as a sequence of discrete samples.
What you are mistakenly thinking of, is the reverse process, taking that stored sequence of samples and generating a facsimile of the original analog program material, doing bit-sum averaging to compensate for dropouts.
Perhaps this is the missing information you needed to see why digital is inherently flawed.
Sleepwalker65 10-5-2018
@cleeds the fact is that while the data is still represented as a staircase, (lollipop diagram if you prefer), the nature of sampling means that some information is left out during digitizing and then on playback, it is artificially synthesized. That is the indisputable flaw in the process. No matter what quantization resolution and what sampling rate, you cannot escape this fundamental.
First, I’m not sure how familiar you may be with the Nyquist-Shannon sampling theorem. There is no "bit-sum averaging" involved in the process. And if by that you meant "interpolation" that is not involved either. And the reference to playback being "artificially synthesized" is a misconception. What is involved is low pass filtering, in the recording process at the input to the A/D converter, to prevent "aliasing," and in the reproduction process to reconstruct the analog signal. And the 16 bit quantization that is used in CDs can, if well implemented, provide a dynamic range of approximately 96 db (actually slightly more than that), which can be further enhanced by "dithering." And theoretically/potentially, at least in the case of an infinitely long series of samples, the 44.1 kHz sample rate can support a bandwidth of 22.05 kHz, without any "averaging" or "interpolation" or "artificial synthesizing" or information being "left out."
If you believe that the LP medium is inherently superior to the CD medium I suggest that instead of focusing on (and misapplying) theory you consider the potential side effects of the two filters that I mentioned, and probably more importantly on the engineering of the recordings, and perhaps most importantly on the quality of the circuit designs that are used in the specific equipment that is used for both recording and playback.
Regards,
-- Al