Ed, love the informative video! Background music is a little loud though so it might make it hard to focus on the video for some viewers. Either way love your stuff my man keep it up!

@@BrodieTV Thanks for watching and the feedback. This was an early video, I believe I have the music balance better now 🙂

@@EdThorne LEGEND

Appreciate your explanation! 👍

Yes and no. When he compares 16 to 24 Bits, he's leaving out a crucial detail. His numbers are right, but he's not mentioning the recording process. If you're recording lower volume sound (say a guitar amp at 90db at the mic, which is below 96db) you can get by with 16 bit, but the closer to 96db you record at, the lower the headroom for processing you're leaving yourself. If you were to record the same sound in 24 bit, you'd be left with about 45db of headroom. 24 Bit is for recording louder signals to minimize noise floors, which means more headroom. That's where the difference really happens. Your ears can't hear the difference between bit rates, that value is pretty much for the recording engineer only.

Exactly, mostly common in sound design for movies to create new fx

And what happens to frequencies that morph below 0 Hz ??

@@RonnieVaiArovo distortion i think

תודה עזרתה לי😂

@Gus Burdeshaw stfu

This is fantastic information, and as you saw in the video, something I did not consider. Thank you for filling in the gaps and broadening the explanation. 🙂

You welcome. Our human mind and the sensors connected to it are amazing. If you have a chance check out how the mind handles imaging and how it uses simple tricks so that we can see color, motion, detail and so on. It’s amazing. Many ideas from our bodies are taken and utilized in the digital camera design. And still our bodies beat it in many ways. Cheers.

To reduce production costs, early CD players used a single D/A converter which interleaved between channels to produce stereo sound. That did cause a tiny delay between the left and right channels, but modern D/As don't have this problem. The sampling rate ONLY determines the maximum frequency that can be represented in a digitized signal. Sampling rates cannot change the latency or timing of that signal, nor do they cause any change in the speed at which humans can perceive sound nor the speed at which those sounds travel through any given medium.

@@jonah1976 I think you did not understand what I was trying to state. When you encode a sound from natural instruments or nature sounds into two microphones for stereo recording these sounds hit the microphones at different times. The human mind can differentiate that difference to 7 microseconds. So when you encode this recording at 44.1 kHz that timing is limited to around 20 microseconds. If you do the math you’ll see that each sample the converters take is spaced out at 20 microseconds. Yes you’ll still hear the stereo. You will still hear the direction. But the resolution of that directionality is about 1/4th of what your brain is capable of resolving. Furthermore, our brain is pretty clever with audio and vision. When you have directionality that is of higher resolution the brain can actually use that data and make you feel like the sound is crisper and more detailed. That goes away if you only use one ear, or record electronic synthesizers directly into the interface as the source itself does not have such timing characteristics in the signal. There are great lectures in vision and sound and what happens when you play the same sound through headphones and introduce a tiny delay of few microseconds, you will actually think the sound is cleaner. This is one of the techniques used by our brain to get more information out of the sound and help up to decipher what we are hearing. Bose uses that trick among others to fool the listener that their speakers are better and the sound stage is larger, where in fact they heavily process and color the sound with timing phase shift snd equalization. Our eyes do the same thing. They micro vibrate or shimmer to get us higher resolution and so call ‘refresh’ the image we are looking at. And when you use a pair of eyes you get even more detail. I hope this helps a bit. Cheers.

@ReaktorLeak thank you for the link. I watched the entire video and it is informative. While he addresses the timing issue almost at the end of the video pushing through a bandwidth limited sample of the square wave, he makes an assumption that moving the sample back and forth doesn’t affect the timing as all points can be reflected. While this is true to a certain degree, it very much depends on the DA and AD converters. Each converter uses specialized circuitry to reconstruct the digital to analog by connecting the sample in time points to form the waveform that we can hear. However that circuitry is limited by its design. He addresses that when he shows the picture of alternate ways to connect these points that make no sense as going backwards in time in order to form a complex waveform is wrong. I give that to him without a question. But anything else I would argue. The reality is that while we humans are limited by 20KHz hearing range, there is a finer resolution that is part of our hearing which differentiates between the left and right which does goes beyond the Nyquist theorem. And he does say that the timing is limited by the Nyquist number. So the small timing differences are not in the resolution of as you state nanoseconds but milliseconds, otherwise we would be able to store much more data on an audio CD than the regular 700MB. We wouldn’t need Blueray if we could achieve nanosecond resolution as we could not only have a carrier signal encoded but also the modulation signal on top giving us the nanosecond resolution. His moving waveform back and forth just shows how the small details are resolved by the converters and he argues that no information is lost as timing is contained. Then my response to him would be that if he takes a decoder from today and one from 20 years ago which has the same specifications he would notice the difference using the same demo as in his video. Why? Because the function translation is much better these days on modern decoders than those from the past. Still even the best decoders and encoders can’t address all possibilities thus higher data sample rate yields better results. It would be interesting to see him comparing the 192 to 44.1 sample rate experiments and see which one yields better data beyond the Nyquist limit as that is what I talk about that it is needed to resolve timing information between left and right. I’m an expert in this as I design SerDes at rates of 25GHz for chipsets, so I know a thing or two and I would easily show the limitation of his demo as it dances around common situations of waveforms and that is what codecs and AD and DA are designed towards. But the limitations do exist. Let me give you two examples how encoders can encode analog to digital. When samples are taken they are taken at a time and recorded, or two are averaged at twice a resolution and stamped to be encoded as one average sample of half the resolution. There are many ways that encoding and decoding is done. These are just two examples I gave you. And as you see the same signal can be recorded two different ways. Which way is better? That’s a long debate. But this shows you how you can lose or average information. Do we hear that? That’s another debate as demonstrating something with scopes is limited as our brain does everything by differentiation. And Nyquist doesn’t apply in that sense. Let me give you an example I’m working on currently. I’m in Berkeley on UC Campus, from my office window I can see the Golden Gate Bridge. I take the 65 mega pixels camera and take a picture without using the zoom lens of the golden gate bridge. I can see the suspension cables of the bridge that look like the wave. But I can’t see the support cables from that main cable connected to the deck. But I can see those with my eyes. How can that be since the camera is about 4 x my eye resolution? Well, because our eye just like ears use differential calculations to form an image. Furthermore our eyes have micro movements and when our eye ‘pixels’ vibrate they see the transition of those small cables when each of our pixels goes dark and light and our brain draws that cable. But the camera of 4x the resolution didn’t see these cables as these happen to fall right between the pixels or are 1/4 the pixels. You would need a 250 megapixel camera to do what our eyes do with 1/8th of resolution. This is my friend why the gentleman who did the video should take some classes in human brain and sensory system to see that our hearing is more than the 20-20KHz sensor. Our brain uses our sensors and does many things to extract more information which his demo fails to address. We are still discovering more each day, and are wowed by the works of our brain and how it makes our limited sensors as super sensors blowing away the things we design with better specifications. Our brain can do more with limited means putting us to shame as it outperforms our designs and computers. Don’t let machines tell you they are better than you. They may calculate better and be faster, but we humans will always have tricks we are better at. Evolution made sure of that. Check out owls, how their ear offset in the height on their heads, allows them to not only differentiate left and right but also up and down much better than we humans can. It will blow your mind as it did mine. We got a lot to learn from us and nature. Engineering has yet to catch up. That’s why I became a physicist so I can poke fun of engineers. Just kidding. Cheers and love to hear from you.

Thank you, you're very kid :-)

Mike Harwood Thanks Mike. 48 provides approx an extra 2kHz of ‘hypersonic’ frequencies which although not necessarily ‘audible’, apparently has been shown to trigger alpha brainwaves, hence the ‘feeling’ of its presence. If you’re not short of storage, mate as well use the tools at your disposal 😀

@@EdThorne for recording 48, 88, 96 and even 192khz might make sense but for actual distribution you're likely going to use 44.1khz as that is the standard in music business to this day. all youtube videos are rendered to 44.1khz audio, as well spotify and all other music streaming services... unless you're using amazon ultra hd music or tidal hifi subscription, as those do provide up to 24 bit 192khz... however even vast majority of their lossless catalogue is still going to be 16bit 44.1khz. for movies and tv shows the standard is 24bit 48khz I think today.

😊🙏 Thanks Indra

Thanks. This is a simplified explanation but I think it’s useful to understand the processes involved. Glad you found it useful, and thanks for subscribing 🙂🙏

Very well said.

Thank you. 🙏

Not really, although that is a common misconception based on people trying to find an analogy between sound and image. And while in the image world the better the resolution the closer you get to “analog”, in the sound world that’s not the case. The reason is that a wave, any wave, can be represented by just two points. Imagine a sound wave described by two points, one at positive peak and one at negative peak. All you would be achieving by doubling the sampling frequency would be information redundancy, basically more points that provide nothing more than you had with the two points. The reason is that when you hit a DAC the points I mentioned are going to be converted back to a continuous wave. This stands true for any frequency till you hit the Nyquist frequency of your sample rate, i.e. half the sampling rate. There are some uses for higher rates than 48Khz but they are rather limited, namely some plugins work better at higher rates (although pretty much every modern plug in that needs it does the upsampling internally) as well as animal research (dolphins, bats, etc).

Literally the most useful comment i have found I have the same opinion

@@axilleas yea and this is where dithering comes into play. I will not entertain dithering here as it hurts my head lol but yes 44.1 is the cd and otherwise accepted standard for high quality digital audio and 48k is the film standard.

While it's true that any SINE wave can be perfectly represented by just 2 points, most real waveforms are far more complicated than just a single sinewave, plus most of what we hear is the combination of multiple complicated waveforms all interacting with one another to create something very complicated. So it is true that when you start reducing the sample rate, you do start to lose clarity of high frequencies and noise. But 44.1 kHz is generally accepted as being high enough for LISTENING (not necessarily for recording though).

I'm glad it was helpful 🙂

Thanks for watching 🙂

Thanks, Tommy. It’s a very simplified explanation but hopefully it helps. 🙂

Basically 24-bit/48kHz is sufficient for everything 🙂 Maybe 96k if you want to get into over sampling with plugins

Hi there. Thanks for the positive feedback and lengthy explanation. My video is definitely a basic summary of the topic without going into the advanced science of it. Hopefully people who want to understand it more thoroughly will see your comment, or access the further reading literature in the description. 🙂

@@EdThorne Sir, is HR versions of TASCAM US 16*8 launched by the TASCAM CO.

10/10 A +

Will a 16-bit 140dBSPL signal sound different from a 24-bit 140dBSPL signal? Even if there's more quantization error at 16 bits, will we hear that error at 140dBSPL?

You're welcome, I'm glad it was helpful.

Hey Izzy, Either because he thinks more is better and hasn’t thought about it any further (understandable, most people are like this) OR because he knows 48kHz sample rate in theory captures up to 22kHz frequency and the extra 2k in theory creates more presence in the sound. The reality is it’s hypersonic audio which we can’t hear but research suggests it triggers alpha brain waves which may explain why some people claim they can ‘feel’ the higher frequencies. At least, that’s what my research has lead me to believe. Also, broadcasting audio is recorded at 48kHz, so maybe he wants your recordings to be inline with that, without needing to convert files which may jeopardise the quality of the audio.

Because 48 Khz is half of 96 Khz

48khz let's the cutoff filter work at 22.1 khz instead of at 20.5 khz Wich allows for the cutoff filter to be less steep. Resulting in an opener bit more natural sound. It's not voodoo.

@@SuperIZL voodoo !! I use 768 sample rate

If you use your machine for more than music it should be at 48. It's the standard for the video industry.

Hi Ron, That's great to hear, and exactly what I'm aiming for, thank you :-)

>deep research >discovers youtube videos way to go xd

Your computer will have to re-sample all the tracks, but this should only be once. There’s no benefit to doing that now if you’ve recorded at 16. It won’t improve the quality. 16 is also plenty of dynamic range. Most people’s tracks realistically only cover about 2 bit of DR (12dB).

Thank you 🙏

KZbin recommends 24bit/44.1kHz. Higher sample rates are acceptable: support.google.com/youtube/answer/6039860?hl=en-GB

His channel is great, I’ll take that as a compliment 😀🙏

Thanks🙂

Thank you 🙏 It’s a simplified explanation but I’m glad it helps 🙂

Pretty much 🙂

I can’t tell if you’re being sarcastic. I’m kinda hoping you are cos that’s hilarious 🤣🙏😀

@@EdThorne Honestly, you are AWESOME! 👍🏻

Raymond Looi 雷聖雄 Ah you’re very kind, thank you 🙏

Thanks Anmol. I hope it’s helpful 🙂🙏

@@EdThorne love from india bro i wanna follow you on instagram are you in it?

@@anmolhans1288 Yes 🙂 @TheEdThorne

T and C at the Movies Thanks for the support

Best way to test the application of sample/bit rates is in editing context. You can test if aliasing occurs with high pitched voices or added saturation, sine wave is good for testing because it has only one harmonic - which is also the fundamental frequency (the note you're pressing). You will see additional frequency response BELOW fundamental frequency if the audio bounces back from nyquist threshold. Another way to test is by slowing audio down, with higher bit/sample rate you have more frequencies above 22khz to shift back down to audible range. Third way to test is by clipping recorded audio past 0db on purpose. With higher bitrate, the audio is still recoverable (to a degree) if you turn the volume down after the fact. With lower bitrate you will see the peaks flattened out and the damage is irreversable.

Chris Featherstone Thanks Chris 🙂

Interesting 🤔

You won’t notice a difference but the matter requires more CPU power. 24/48 is plenty.

Bit depth and Sample rates are different things and not linked. I suggest 24/48. Bigger than that and your files sizes are unnecessarily large and your plugins (CPU) will struggle.

Check the sample rate of your samples if you’re using sample libraries. Also check the sample rate of your interface is aligned with your DAW.

I've never even heard of 384kHz devices existing, wow.

@@EdThorne the FiiO BTR3K has it over Bluetooth but only 44.1KHz over USB-C, apparently. The FiiO BTR5 does 384KHz over both.

Its actually impossible..384khz through bluetooth.That is Bs

Thank you. You’d have to check their website. I upload everything to DistroKid at 24bit/48kHz. Spotify may convert it, I don’t know

I'm trying to find this info - Spotify support is hopeless and there is nothing online...

You’re welcome, Nathan. Thanks for watching 🙂

Conversion sample rates (as discussed in this video) and Mp3 sample qualities are different things. 192kpbs is good for a podcast 👌

Haha. Thanks 🙂🙏

Well spotted. I’ve probably just said the wrong number, it’s easy to do when doing multiple takes mentioning multiple different numbers. Your other points are spot on too, useful to consider when choosing your settings.

@@EdThorne :)

Ha. Thanks. Hope it was helpful.

Lol. It’s a very simplified explanation to what is very complicated science but hopefully it helps people understand a little better. 🙂

Sean Hebert Haha, thanks. This is definitely a simplified summary of the relatively complex science behind it, and I agree about the higher frequencies in post.

For streaming it may be worth keeping the audio quality to 16/44.1, but streaming audio is more about the Audio Bitrate (128/256/320 etc). That depends on what your streaming service (OBS/Streamyard) performs best at. Mine is currently set to 48kHz and 256AB

@@EdThorne tysm! My pc is not upgraded yet so i might stick to the smoothest one 🤍

To be safe, I would personally use 44.1 to minimise any streaming/bandwidth problems.

Glad you found it useful. This is definitely a simplified explanation but one that at least makes sense. :-)

You’re welcome. Glad it was helpful

Streaming rates are different to bit-depth and sample rates. Go with the highest your internet can handle (obviously factoring in screen capture video quality, which will consume the bulk of your band-width)

I’d always suggest recording at 24. 32 is unnecessary.

@@EdThorne Thank you very much!!!!

EPIC! Have you got audio examples?

@@EdThorne idk how to make a download link

@@bitonic589 Dropbox/Google Drive maybe? No worries if not, I’m just curious 🙂

Lol…

Thanks, Muhammad!

The dynamic range of a podcast will be very little so 48&16 will be plenty. Try it and see if you can hear a difference, it’s unlikely though

@@EdThorne thanks for the support

You’re welcome 😀

The computer understands the frequency (which we hear as pitch), yes.

@@EdThorne My question is on HOW the computer understands the pitch. And I'm asking if the interval between bit depth value's is what determines pitch and if not what does?

I’d always suggest 24bit depth. If you don’t plan on slowing down or speeding up the audio I’d suggest 48kHz for file size and system speed. Or 96Hz if you feel you notice a difference but this puts more stress on plugins and cpu load. I record everything at 24bit/48kHz.

@@EdThorne Thank you so so much Ed,,😊🥳🙏💯

@@EdThorne cool. Should I upload 44.1 or 48khz for a KZbin music video? I always upload 24 bit but unsure re the sample rate

@@therealrussellsmyth I’d suggest uploading at whatever you recorded at. Converting from 44.1 up to 48 isn’t worth doing.

@@EdThorne thanks man. From researching it seems KZbin accepts 48 but automatically converts to 44.1. Prob best to perform the conversion myself!

Ha, I recon so for sure. Try it and let me know 😜

A standard microphone doesn’t convert audio. You may have a USB/interface microphone that does, and yes, these bit depth and samples rates will be fine.

You’re welcome. Thanks for watching 🙂

The Tascam interfaces are great, they sound lovely. It was probably the best sounding interface in this Top 10: kzbin.info/www/bejne/rmaTlaqVd8uomrc

Sir, I also observed all 10 tracks of these interfaces. I also found that TASCAM sounds amazing. My second question:- is HR serial best for song recordings or I should go with old non- HR interface. I sing all Old bollywood songs. I want to setup my home studio. So pl. guide me correctly.

@@HarvinderSingh-yy8th May as well go for the newest model (HR)

@@EdThorne HR is not available in TASCAM US 16*8 interface.

No, 16/24 bit-depth refers to the dynamic range of the audio at the conversion stage. kbit/s is the resolution of the mP3 file.

Yeh, it took me a few goes to pronounce it to 🤣 That’s a strong testimonial, thank you very much 😀

@@EdThorne no problem! I subscribed also!

I have read that frequencies above 20k trigger alpha brainwaves giving us the impression of feeling them. I believe the same article also said there’s no evidence of frequencies above 25kHz triggering these brainwaves.

Okaaaaay.....

The crackling is likely digital clipping from overloading your output. Try turning the game volume down and computer/interface output up.

Your headset?

@@EdThorne seinnheiser gsp 600

Point me to a time stamp?

Cole Hi Cole. Thanks for commenting. I understand how time stretching may require a higher sample rate but what makes you think tuning would as well?

@@EdThorne I was just referring to the time chopping abilities of both of them

Cole Ah ok, yeh, that makes sense.

44.1Khz/16-bit. Search KZbin for "D/A and A/D | Digital Show and Tell (Monty Montgomery @ xiph.org)" if you wonder why.

@@jonah1976 okay, thankyou 😊

196khz 32bit of course

@@jonah1976 not true 48khz 24bit sounds much better, especially bass guitar

For me it's 48K for games & movies. KZbin and browsing random web videos: 44.1k (you can leave it at 48k if you want, downsampling shouldn't be an issue for any medium overall). For recordings: 96k/192K if you need the resolution or want to do more on your mix, depends on your goals, if not.. just straight record to 44.1 since this is the standard. Keep in mind the buffer size when recording to avoid delay. Depends on what your PC can handle, the lower the better. I know you're asking for "listening" but just wanted to simplify for others.

But humans can’t hear above 20kHz so technically anything above 44.1k (22.05kHz) is wasted (unless you’re slowing down Audio. Now, there have been studies that suggest frequencies above 20kHz, although not audible, do trigger alpha brainwaves giving us the sensation of ‘feeling’ those higher frequencies, but even then these didn’t go past 24kHz. What I didn’t find out for this video was whether or not there are companies producing devices that sample more than two samples per cycle, 2 being the minimum to avoid aliaising. For example an interface that could capture 4 samples per cycle could easily use 88.2/96kHz and sound amazing due to the resolution so at that point it wouldn’t be marketing fluff at all, just a killer product.

@@EdThorne yes i understand you very well in explanation , what i said was audio interfaces that gives just 44.1khz are not good at high frequencies at 20khz on human hearing but in 48khz interfaces they produce better on high frequencies on human hearing betwen 15khz to 20khz

@@sheffoooproductions9738 Yes, this makes sense 🙂 I think after 48kHz (which is what I record at) it’s a question of file size and processing speed. 96kHz is a LOT of data A) to store and B) for your plugins to process, and therefore CPU/DSP load.

@@EdThorne yes youre correct , i have interface with 192khz i use it on 48khz so interface with 192khz has more capable amplifiers but i set it on 48khz everytime

Learn about Islam Haha. Best stay at 48k, for the rest of 2020 at least 🤣

@@EdThorne 😂😂😂