Always enjoy your educational videos. This one reminded me of a video by Techmoan from about a year ago demonstrating an early digital audio recorder that used VHS tape and it seems a fitting complement to yours since it includes a little history of PCM recording. kzbin.info/www/bejne/jYendKuKqdNnhbM

I have a "digital" VCR--Toshiba--made in the late 80s. It has analogue ins and outs, but the audio is PCM. My band recorded an entire CD with this format because we couldn't afford a DAT machine. When we went to master our mixes, we took the VHS tape and the mastering house was able to decode it digitally. It was amazing at the time. The VCR cost about $1100, and I still have it, and it still works.

Just as an anecdotal data point, I've been using 48k since the late 90s when I started using Cubase VST with a SoundBlaster Live! card and found that the card wouldn't sync properly at 44.1k, because it was internally 48k and doing an inaccurate downsampling to get 44.1. It's funny now remembering how I was annoyed at the extra disk space it used, totally irrelevant now. But back then, when I'd spent a lot of cash (for me) on a "massive" 17.4GB hard disk for audio recording storage, it was a significant overhead.

I share a bunch of your stuff with my TV students, I hope you haven't minded ;). I've taught the 44.1 vs 48 lecture for ages but without the PCM background. This is another gem that I can add to help make my dull lectures more engaging. Thanks John Hess!

The old filmmaker IQ is back 👍🏽

As a computer engineer with a background in signal processing, I would like to commend you on a very well presented summary of this issue. I found no issue with any of the facts you present. Sadly, that is very rare. You, sir, are a wonderful resource and I hope people appreciate you for it.

You're the first person to explain this in a way I could actually comprehend.

Great video! It is very interesting to learn why CDs use 44.1kHz. My job involves processing audio recorded from telephones. Historically, that's usually involved a sample rate of 6 or 8 kHz (due to limitations of the old hardware), although, more recently, there's been an increase in the use of 16, 24, 32, or even 48kHz. From that perspective, 44.1kHz audio is a major pain, because a lot of software used in the telephony sphere (e.g. speech recognition) still tends to expect 8kHz. If someone records some audio externally and then wants to import it into the system, it's a lot easier to deal with 48kHz than 44.1kHz if and when it's necessary to convert it to 8kHz!

Excellent. Just excellent. My 50 year media production career started with broadcast TV in the 1970's golden age of analog and rode through the evolution to digital audio and video production (starting with the introduction of character generator computers and the Ampex Digital Optics devices circa 1980). Always been fascinated with the tech of the various format standards and how the analog legacy dictated a lot of the digital video format decisions, but I didn't know about the direct influence of analog video legacies on digital audio standards until I saw this video. Thanks! Liked and Subscribed!

Love videos like these! A surprisingly in-depth review of some foundational material along with historical and contemporary context. Learning disguised as a good time, great job!

I knew about 44.1K but never got 48K, especially since 50K was already an established standard. Thank you! Side note, engineers of earlier digital recorders believed 60KHz would be ideal (you need room for the antialiasing filters to work) but it was pushing the tech a little too far, so they settled on 50K.

In the late 80's the amount of data you could put on a CD seemed unimaginable to us. The place I worked for put all of our dozen applications onto a single CD with space to spare and that was writing the contents of multiple hard drives onto this seemingly bottomless media. You could buy a 600 megabyte SCSI drive but the cost was horrific so we didn't.

We are really lucky how futureproof the 44.1 kHz CD quality standard was. It did, does, and will always sound good. Still higher quality than the audio of almost everything we stream today. It's hard to believe such a good quality standard came in the 1980s while video standards arguably didn't get futureproof until the Blu-Ray/HD DVD came out.

Also note that 48khz is still the universal standard in all HDTV formats, UHD as well. Standard HD frames rates are 23.98hz, 24hz, 50hz, 59.94hz and 60hz. Note the 59.94 still hangs on even though it's need is obsolete in ATSC. But because of conversion to and from NTSC, it lives on.

Going to digital does require that any frequency above the Nyquest limit must be filtered out or aliasing will occur. However, the best analog Low pass filters we can make are a sixth order filter with-36 dB/Octave. (Roughly 1/64 the voltage per octave) That's just not enough and any ultrasonic sounds will appear as lower frequency sounds due to aliasing. The higher the sampling rate, the greater the reduction in ultrasonic noise. No surprise that some recording studios like to sample at even higher rates of 96,000 samples per second and higher. Digital filters have an impressive reduction of over -100dB per octave, which puts all ultrasonic sounds into the floor. After that the digital audio can be reduced to a lower sample rate.

Thanks John. I have missed these tutorial videos, which seem to have been replaced by live stream content and similar. This is what I subscribed to the channel for, and I am delighted to have watched this one. I hope you will be able to make more of these very educational and interesting videos in future. Thanks.

Despite, that CD Audio standard is 40years old, only few records has been able to utilize it's 96db of dynamic range. And people believes that if they don't have at least 32bits/ 196Khz, sound will be suffering on they precious soundbar. :-D

Well, this is as good an explanation as you'll ever find - very clear with minimal techno-math. I'm never disappointed when I visit this channel

That's a well done video, Sir. Well researched, very informative and very well presented. Thank you!

Your videos are quite simply the best, most informative free online resource for the technical aspects of film making I’ve come across. Always a delight and your presentation is top notch too

Loved this one.... answered a lot of those random questions I've always wondered about...

Fascinating! Tyvm. Good to see you back.

Damn, every subject i think I know well, you teach a ton more. I remember marathoning your education series in Feb2020 when on holiday and learnt a ton. Thanks!

Your explanation is so good and on point! Congrats on the video! Hope to stay and learn lots!

I personally choose 48khz for my game engine since I can implement millisecond-based timing quite easily with that sampling frequency, otherwise it can stretch 44.1khz samples to 48 if needed.

Really well presented. i already knew the history but i couldn't have got it across as concisely and completely in 12 minutes - fantastic!

Very interesting and very well explained. This was my "serendipity moment" (learning something you weren't looking for) for today.

This content is soo dense and presented efficiently that I checked half way through thinking the video was twice as long ahaha

Super clear explanation and great visual aids... Nice work!

Nice video! To add to this: Nowadays with good conversion algorithms you won't notice it if you convert from 48 to 44.1 if you don't do it over and over again. Thus I do all recording in 48khz, even for CD productions. So in the end I always get a video version and a CD version. But seriously, CDs are almost dead so the very most audio I produce goes into video anyways. One can discuss 96khz sampling, and people do. But also there is a difference between 96khz processing which basically is a 2x oversampling on the entire process, while still having recorded at 48khz, and 96khz recording. But anyways, most videos on YT are being watched on smartphones probably, so anything will be good enough.

Great to see you back John and thanks for this very insightful video!

Hearing you is a nice class about how to use the voice pitch and level to explain physics of audio waves. Simple and it works ... wow!

I have been recording/rendering my personal electronic music projects at 48k/24bit or 48bit for yours now. With kind of powerful workstations like the one I have, I can pretty much throw whatever I want at it.

I remember some high quality formats that really didn't stick around. SACD & DVD audio. I have Natalie Merchant "Carnival" on DVD audio. Only a few DVD players would play the digital audio. I never purchased any SACD discs. I have "Las Ketchup" & "Axe Bahia" on a video CD. This was the forerunner to DVDs. Again, only a few DVD players played this oddball format or it only played on a computer. XP at the time. I remember the DAT tapes & Sony mini discs. Cassettes had chrome ıı or metal ıv & Dolby B or C. Later came S. To erase the metal required strong magnets in the cassette recorder. TDK & Teac made some studio version cassette tapes with ball bearings. (not for retail sale) That was extremely clean with headphones on. Later came MP3s. Standard was 128. Some car CD players would play those. Then you had the up to 320 & variable bit rate. WMA & AAC was out there too. Real Player had some oddball AT8 format.

What a brilliant video. Sometimes "every-day things" can be so complicated.

48k also makes circuit design just a bit easier, you can use less aggressive anti-aliasing filtering.. and it simplifies the math a bit in digital side. The other number, 24bit is even more important specially in broadcasting as it allows for more headroom. 16bit is what we need but when you are working with live signals that are often unpredictable you will enjoy having those few bits extra. This works well also in other audio production, 24/48k is what vidiots wanted and it happens to also make things better elsewhere. So, thanks.. i guess.. There is no need to go higher, we can prove it quite definitively, also when it comes to processing but with one crucial detail added: 48k requires oversampling and filtering at each processing stage (384k project sample rate is equivalent to 48k if latter uses oversampling scheme, it also uses 8 times the bandwidth and file space and has a higher processing load. 192k is worse and 96k is damn right idiotic, it is considerably worse to a point where it can be audible..). So, turn all of those "high quality" and "oversampling" buttons on in your plugins, they are there for that specific reason. Especially important with all processing that affect the time component of the signal in anyway, this includes compressors.. but not stuff like linear saturation or simple gain, distortion or even delays (repeating is not modifying the time component.. ). Chorus and phasers are especially problematic and oversampling is absolutely mandatory. 24/48k is perfect format for all audio production.

I am happy to see new videos from you.

First video, looks ok. You're not the Frugal filmaker, but... you might get me hooked. Oh, and a shoutout for mentioning Umatic, which is the second time in a couple of days to be mentioned, since I had been talking to a friend about some old editing equipment and flying erase heads. No mention of "white-a-key" - the technique we used to get a clipped area out of the picture without a fancy switcher (piece of white paper, careful positioning, clip to white which dropped out and you see what's in the other channel/camera/playback source). Of course, you still needed the TBC. Only criticism: you dropped 'kilo' twice, just before the moire moment. Nobody but me noticed.

Great explanation! But then why am I so tempted with 96khz?

I have one of Sony's PCM to video adapters, not from the PCM-1600 line, but the later, consumer oriented PCM-501ES model. It's similar to the Technics PCM deck that Mark Hesse posted, but it lacks a transport. Instead, it has a composite video input and output, designed to be hooked up to a VCR (be it VHS, Betamax or something else) It uses a different video encoding method than the 1600 series, but the three samples per line are still clearly visible. Of course, it does record and play back at 44.1 kHz. I wasn't sure about the origin of 48 kHz. I thought it might had to do something with DAT tapes, since that was the earliest widespread use of the 48 kHz sampling rate, outside of the film and video world.

Excellent contribution!! You will come across a lot of mythology surrounding the choice of 44.1Khz as the sampling frequency for the Compact Disc, but this is the true explanation. Rotating-head video machines were the only recording format we had at the time with the recording density needed to record continuous program at a sampling frequency above the Nyquist/Shannon rate of 40Khz, to deliver 20 Khz audio - and the U-Matic machine chosen for the Sony PCM 1600 - 1610 and 1630 mastering process delivered 44.1Khz using three frames per sample. Other formats did exist; As early as 1980, Sony's F1 EIAJ format allowed recording of 20Khz audio on VHS tapes at a lower cost, and a sample rate of 44.056Khz, but the PCM 1600, later to become the 1610 then 1630 had already established itself as the industry standard for mastering of CDs.

Glad you went over this! Great video 👍

I have the Sony PCM-601ESD PCM adapter, I recorded a lot of albums from my computer to VHS and Video8 tapes, a lot of fun. But there are computer programs that can do that now if you have a video card that can pull the video off of the tape and convert it to PCM inside the computer using special app or even record a PCM audio back into the video tape without needing the PCM adapter.

That was fascinating! It's one of those things I just took as a given, and never realised I wanted to know, but then you popped onto my KZbin feed, and I realised I really wanted to know this. Great explanation! Subbed.

Thankyou Sir. A much needed detailed but still understandable answer to an often asked question.

Enlightening and so pleasantly presented! Thanks very much for this.

Mind blown. Thanks for making this-I appreciate you! ✨

01:03 to 02:56 That's at least two or three one hour lectures from when I was trained in the Eighties. I congratulate the Filmaker for his clarity and jargon-free explanation. I was especially impressed by "Sound is just compression energy, flowing through the air", but the following description of PCM is just the best.

*The greatest cine-tech tutorial channel!* Thank you, John!

One little thing to add: one might wonder "Why not just use 40 kHz these days, given that we don't record on video tape anymore?" Well, to avoid aliasing artifacts, you need to use a low-pass filter on the recording to remove all frequencies that are higher than what the Nyquist-Shannon sampling theorem allows. The steeper the filter, however, the more artifacts the filter itself introduces. An infinitely steep cutoff would be a disaster, therefore you want to have a bit of give in the sampling frequency. Which also means that in principle, 48 kHz _could_ sound better than 44.1 kHz, even though no human can hear those frequencies.

Simply put, incredible video! Even the slides are awesome. I've been text messaging pics of them to my buddies in real-time as I've been watching. Sure, I could have sent a KZbin link, but hey, what's one more conversion standard? As they say, the good thing about standards, there's so many to choose from!

The process of recording sound stored in the form of thousands of indivdual measurement each at a discrete unit of time called.. very thanks for a super video....

It really helps me to understand technology when the history of the development explained so clearly. For example what was an arbitrary, unconstrained choice versus what was guided/dictated by legacy. Thank you.

Thank for that John Very Interesting answered many Questions

It's interesting to see digital audio data being saved as picture information on videotape. Just as digital data for computers used to be stored as binary code audio-signal like on Commodore 64 Datasettes or ZX Spectrum tapes. A clever concept. Something similar was later used in the 90s for VHS tapes to save digital files from harddrives to a Videotape. The software was sold for PC and came with a video-output card that had to be installed into the computer. You would then select all the files you wanted to backup on VHS and it would then pack everything into a archive dump and export it as a Videosignal which was a black & white video signal (series of blocks that looked like animated barcodes and QR codes).

Really enjoyable and well presented, thanks!

VHS PCM is gonna be the newest hipster audio format.

Very very nice clarification. The history of digital audio is very interesting!

Fantastic overview. Thank you!

That was more complicated and interesting than I expected, thanks!

Good to see you back in the saddle Hessy

Rare to find explanation. Great job

Ace. I really appreciate your efforts. Thanks.

Wow great stuff thank you. I am blown away. I'm still recording in 41

John, great video! Will definitely use it in my physics classes as a part of my sound and waves unit.

I've played a lot with a pcm-601esd with Umatic and VHS. Very interesting device! Now I've HEARD that sony "Umatic Digital" was the master format sent to CD duplication houses. I can't help but wonder how much data is lost to video drop-outs.

Thanks for boiling it and making it simple. Great job!

Excellent explanation. For those of you who can't stick with the whole 12 minutes. Engineer 1. '' We need to build an oscillator that runs at a high enough frequency to sample the audio'' Engineer 2. '' This video deck has a load of stuff already in it running at 44.1kHz'' Engineer 1. '' That'll do nicely. Let's have a beer''.

Later formats like CD, DAT etc were so robust largely thanks to error-mitigating innovations like EFM and CIRC. Those early digital audio formats on u-matic etc seemed to be very much synchronous bytestreams. Did they use any form of error checking like parity bits or such?

Interesting that they tossed the idea of 60KHz as the standard back then, as several of the more respected designers of digital audio converters suggest that as the ideal range of sample rate, for overall accuracy and quality.

Many audiophiles only listen to standards beyond CD quality at higher sample rates which are based on 48 kHz. Typical rates for high quality audio are 96 kHz (double) or 192 kHz (quadruple) with some even higher standards as well. Also bit depths are increasing to 24 or 32 bits. I don't believe any of these excessive rates and bit depths add any additional improvements, but since storage isn't an issue anymore it's not really hurting to have more headroom.

I like your use of zooming in in the beginning. I found that out myself when making our chorus's videos to classical music👌Thanks for this video Bro!

48 kHz is nice: 3 periods of 64 samples makes 4 ms. It simplifies timing over USB, leading to lower latency.

A number of agencies like the FBI keep older equipment around in the off chance an old piece of recording format is needed to be read!

As I already saw the incorrect myth popping up once again in the comments that waves close to half the sampling frequency cannot correctly be reproduced, let me point something out here: *This is nonsense* and based upon a complete misconception of how PCM sampling actually works. Every analog sine wave sampled at at least twice the frequency will be *perfectly accurate* reproduced by the combination of a DAC and a band-path filter following it, which is always required for correct PCM signal reproduction. You can use an analog oscilloscope to prove that. There is no loss in amplitude or shift in phase. A sine wave of 20 kHz sampled with 44.1 kHz and converted back to an analog wave will look exactly the same at the output as it did at the input. If you overlay them in an analog oscilloscope, they match up perfectly and yes, it will always have exactly the same amplitude, too. The misconception here is that when reproducing the wave, the signal will jump directly from PCM sample value to sample value but that's not the case at all. If it would do so, it would produce frequencies that are above half of the sampling frequency and this would violate the Nyquist-Shannon sampling theorem. That's why a band-path filter is mandatory for reproductino. It will enforce that no such violation is possible by ensuring that only analog waves are emitted that pass through all PCM sampling points (*pass through* does not mean "end at those", the wave can go far above that point before it turns around) and at the same time are never above half the sampling frequency. And for those who now say: Okay, this may be true for sine waves, but what about other kind of waves? Every wave can be broken down into sine waves, so whatever applies to sine waves applies to any shape of waves. Of course, saw waves are not reproduced as correct "sharp" saw waves, as sine waves above half the Nyquist frequency are not reproduced (and those would be required for perfect edges) but that doesn't matter as you also cannot hear these either. That means to your ear, saw waves always sounded (= "looked like") as the "imperfect reproduction" does look like. So while you can see a difference for square waves (or saw waves) on an oscilloscope, that difference does not exist for your ears as your ears never captured the waves above 20 kHz and to your ears there never wars a perfect square to begin with. This video explains all the theory about this and even proves that theory using an analog oscilloscope: kzbin.info/www/bejne/aKKpm5eHhZx4ppI

Very Educational as always really interesting to hear the History behind this brilliant video thanks

Very comprehensive as always. Of course I won't be able to know all numbers by heart, but it's always great to have a deeper understanding. With that said: I think that the Nyquist-Shannon theorem does not hold true 100%, just like the Fourier analysis. The human ear can distinguish a sine and a square wave at 10 kHz. If a sound wave is nothing more than the sum of sine wave components, then the human ear would be able to hear a 30 kHz sine wave, which it cannot. As we know, a square wave only contains odd numbered overtones (or partials), so the first overtone (or second partial) of a 10 kHz square wave is 30 kHz. I believe that we humans are great at breaking down things (analysis), but very bad at fully understanding systems (synthesis), so we assume that our senses are analysing, which they are apparently don't, but rather recognize shapes and patterns. So I'd say that digital audio is very good nowadays, but raising both sampling fequencies and bit rate would make it better. That's why since the 1990s old analog tapes are recorded onto digital at 96 Hz at 24 bit. I had the pleasure of hearing studio recordings at 96 kHz (ProTools through Apogee converters) and it sounded so much more transparent. Just my morning ramblings, thanks for reading.

Have a look at some of my videos where I get stuck into working with the PCM1630 (a slightly later machine using the same format): kzbin.info/www/bejne/pKa3lX2Xfs5sqLs

I wondered about the actual history for a while, so I put this into my watch later a long time ago. It just happened that right before this I watched some lectures on compressed sensing that showed how random compressed sensing can to aliasing to reconstruct a signal at less than half the maximum sampling rate. but shanon Nyquist still applies as the smallest interval of your random samples (and how those are distributed) still applies.

I wasn’t expecting much, most videos on the topic get the historical details wrong, but this discussion was 100% accurate. Pleasantly surprised. Now, can you explain Shannon’s and Nyquist’s theorem and show why it is not just theoretical, like gravity and evolution? Nyquist stated it, Claude Shannon provided the mathematical proof. There are those who think sampling rates are just guidelines, so we must oversample!

While I knew most of the single facts , I never got the bigger picture. Now I did. Thank you for this informative and entertaining video!

you're a good teacher, man. cheers.

This was wonderfully informative.

I had a 'portable' Beta recorder which could be used to record sound as PCM. Real ahead of its time. It was only mono though. BTW, I noticed the candle stick phone on you desk. Do you know the back story of the ringer current for telephones? It is interesting. Ninety volts @ 20 Hz. I know crazy.

Brilliant video. Great job.

Old computer sound cards had the 44.1 kHz sampling frequency as the native one. Newer ones have 48 kHz instead, as such sampling frequency became widespread amongst computer audio systems since the late 90s to make PCs be able to play DVDs. But despite that, most computer audio is still recorded at 44.1 kHz or multiples (11/22/44/88/etc kHz) even if it isn't meant to be recorded on CDs.

1980! That clunky Umatic audio recorder box was 1980! Wow. That made me feel soooooo old.

Except there is no resolution. Nyquist-Shannon describes why. Sample rate simply dictates the upper frequency reproduction limit, and bit depth does relate to dynamic range, but it might be better to think of it as how much noise is introduced alongside the desired signal you are trying to reproduce. More bits, less noise. Anyway… A 1000 Hz test tone isn’t reproduced “better” or with “more resolution” when using 48 KHz versus 44.1 KHz. The output would be exactly the same in both cases. Exactly. Nyquist-Shannon sampling theorem dictates this. It perfectly reproduces all frequencies less than half the sampling rate. A higher sampling rate doesn’t give a more accurate result. It doesn’t give better resolution because there is no resolution. You either can reproduce the input signal because the frequencies present are all less than half the sample rate, or you can’t reproduce some of it because the input contains frequencies higher than half the sample rate. As long as it is below half the sample rate you can reproduce it. There is no better or worse. Either you can do it or you can’t. Period. This is a very good demonstration and explanation of how it actually works. kzbin.info/www/bejne/mXq0anyOiLqtq68

This was very interesting to watch and very informative. Definitely going to subscribe and check out the rest of your videos. I’m interested in learning how to edit video, and learning basic film making technique/technology. Just got a Mac mini and a friend of mine is giving me a version of final cut software for me to use and start on

Beautifully explained

Really interesting!!! Thanks for the info.

Great vid. Fascinating! Thanks!

Thank you for the explanation.

Frickin' Brilliant! Thanks that is VERY INTERESTING!!!!

priceless audio lesson....thanks man!

f=2n babaaay! That was a good demystifying presentation, even though you sometimes said Hz when you meant to say kHz, but that's quite forgivable. Liked.

Just a little addon: babies are supposed to have a hearing range up to 20kHz - most people lose a lot of range in the first six to ten years (where the range drops to about 18 kHz). Most people from their thirties onwards barely reach 16kHz - most hearing tests for adults only cover a range up to 8kHz. So you're good with 44,1kHz sampling rate - but for reasons beyond the scope of my comment, you should aim at 24bit resolution then. I do my recordings in my studio at 48kHz/24 bit, which is quiet common these days, though many may argue you could use much higher sample rates. But that's another story.

Wonderful. Precise. Power Packed.

Wow as sound tech I wonder why this video was not made earlier in time. So important.

Be safe & healthy, Mr. Hess.