Thanks for all your videos! Your channel is exactly what I was hoping for. There are so many tutorials out there who are simply "do as I say", but this is real high quality theory, so that one can learn and build independently. Basically, this channel is "teach a man how to fish and you'll feed him for a lifetime", that's why I love it!
thank you for all the time and polish you put into these videos, i’m here as a (still-learning) pixel artist and this whole channel is a gold-mine for useful info (and a good way to relearn some basics), and not just in the context of minecraft! i think it’s neat this much genuine artistic skill can be channeled in such an open and creativity-focused game, and thankful there are people like you who are able and willing to teach people in a polished and digestible format with the help of a literal video game 👏 (sorry for any mildly odd english if there is any, it ain’t my first language 😅)
This vídeo is amaizing dude! Not only you managed to teach me more things about color theory (wich they didnt taught me in my university) you also managed to make parallels with Minecraft and even explain using things in game. Now I believe your truely underrated. ❤
i have a color theory assignment for my bidimentional representation to finish today, and my teacher's methodology was wayyyyy too hard for me to follow. your videos helped me a ton this semester, i keep coming back to review, thank you very much
Great series! I thought I knew pretty much everything about color theory, but I was surprised to learn about complementary vision theory and certain color labeling terms. Best of luck with your endeavors.
thanks for all your colour theory videos and all. Hope you keep doing them even though this one didnt go as viral as the others. its just such high quality and easily understandable. Thanks for the work you put in these videos ❤
Huh. It's funny how much of this reminds me of music theory - the specifics aren't too related but the overarching ideas of how to use/think about theory is almost identical. I'm curious if there are people in other fields who would say the same. Neat.
@@02_920 right?? I was a musician for a decade or so before I got into visual art, and the theory overlap is awesome, especially with harmony and palettes I relation to intervals and modes
*True Yellow* 23:26 Most of the yelows we see everyday aren't actually yellow. They're either a red-green, red-yellow, green-yellow, or red-yellow-green mixture. Coming across true yellow, which isn't mixed with either green or red is rare. Mostly because we've designed our environment for normal trichromatic vision. Even "yellow" flowers don't look yellow to me, but are a red-yellow, which is very different to a true yellow. For RGB screens this becomes very apparent, because they cannot reproduce a true yellow at all. Most of the other tetrachromatic colors I see are also not reproducable with an RGB screen. Even if these people at 23:26 would identify a color as "yellow" it probably isn't true yellow and just a red-yellow-green mixture. *Human Hexachromacy* 5:43 Yes, in most everyday situations we are trichromats with 3 cone types: S, M and L. However, with the presumption that these three cone types are the only ones, we cannot reproduce all the colors we see everyday and all the colors we are capable of seeing. For example, the shimmering effect of most reflective surfaces can only be explained if you take the two eyes' color perspectives as separate, with one set of S, M and L cone types in each eye. These impossible (binocular) color combinations, that result from breaking this binocular and chromatic redundancy of our two eyes, are relatively rare in everyday life, but with the help of special filter/interference glasses and VR headsets you can access this hexachromatic color space. For normal trichromats there are six cone types in total: S1, S2, M1, M2, L1, L2. "1" stand for the left and "2" for the right eyes' cone types. While impossible color combinations are "only" binocular mixtures of trichromatic colors, they are experienced as unique colors/hues with a bit of training, just as magenta for example is "just" a mixture of red and blue. Earlier I've mentioned that I see tetrachromatic colors. This is true, however I see them non-retinally. I've designed glasses which induce a "true-red non-retinal chromatically-less-redundant" form of tetrachromacy. While I call it true-red tetrachromacy, it also allows for seeing a truer yellow, green, etc. By "non-retinal tetrachromacy" I mean I use my second, normally chromatically redundant eye as a true-red color channel (~630-700nm) and my first eye as a slightly anomalous red-deficient color channel (~400-630nm). With this setup I can see a truer yellow as well as a red-green mixture, for example. Two hues which look the same to my naked eyes, but are completely different with the true-red glasses on. In effect, I'm doing the same thing the very rare supposed female human "yellow" tetrachromats with retinal tetrachromacy do, just a little bit less effective and efficient. Here's an article I've wrote about the glasses: www.color-in-color.info/tetrachromacy_1/non-retinal-tetrachromacy As a consequence, while normal trichromats just see trichromatic yellow between red and green, for me this red-green range has as many colors as the total trichromatic red-green-blue range, because I'm simulating a fourth cone type. While most people only see about 7 main hues: S, M, L, SM, SL, ML, SML, excluding black; I see about 15 main hues: S, M, L-, L+, SM, SL-, SL+, ML-, ML+, L-L+, SML-, SML+, SL-L+, ML-L+, SML-L+. "L-" stands for the virtual 'more yellow' red cone type, and "L+" for the virtual 'more red' red cone type. I'm basically splitting the L cone type in half and giving it two unique color channels. And these are just tetrachromatic colors. With VR you can combine any trichromatic RGB color with any other. This results in about 280 trillion impossible color combinations from just 16 million RGB colors on a good RGB screen. And these hexachromatic colors are a wild experience, especially if intergrated intelligently into human vision and VR games. I've already played Minecraft while seeing billions of more impossible colors (confined to the trichromatic RGB color space) and the details you can see are incredible. You can even simulate normal trichromacy (at least as normal as it can get) with impossible colors for dichromats. Color is so much more complex than everyone thinks. Human color vision (at least for people with two "normally" functioning eyes) can only be fully explained by a hexachromatic color theory. Trichromatic color theory is close, but it doesn't capture all the impossible colors we can perceive, which are all valid colors, especially in a meaningful context. *Monochromacy* 6:18 Here you should differentiate between "cone monochromacy" and "rod monochromacy". Both result in monochromatic vision, but for cone monochromacy you can still have slightly dichromatic color vision in some lighting situations because of the influence of the rods. In rod monochromacy you additionally have really bad day light vision and can only see one monochromatic hue in any lighting situation. *Dichromacy Simulations* 5:48 The protanopia disc you're showing there isn't correct. Yellow appears as a relatively bright green (or in this case yellow) to a protanope, not as a washed out yellowish-white. The same for the deuteranopia disc, but slightly shifted.
It’s a shame that my previous comment from a few days ago where I went a little more in-depth who the man was got shadowbanned by youtube; but to keep it brief, Akiyoshi Kitaoka has made tons of optical illusions, and is a proffesor in psychology. He has lots of different works that are worth checking out!
Light does not act like a particle. Its simply only ever measured in a quantized amount. See hung's optics channel for a series on how light can be fully described as a wave. This misconception is super pervasive among otherwise very well educated science communicators.
Thanks for all your videos! Your channel is exactly what I was hoping for. There are so many tutorials out there who are simply "do as I say", but this is real high quality theory, so that one can learn and build independently. Basically, this channel is "teach a man how to fish and you'll feed him for a lifetime", that's why I love it!
Thank you! I’m glad you’ve been able to get so much from my videos and apply it like it
We learning color with this one 🔥🔥🔥
🔥🔥🔥
I just discovered your channel, this is a literal gold mine, thank you for all your work
@@Daoist0 thank you for watching!! I’m glad you found me :D
thank you for all the time and polish you put into these videos, i’m here as a (still-learning) pixel artist and this whole channel is a gold-mine for useful info (and a good way to relearn some basics), and not just in the context of minecraft! i think it’s neat this much genuine artistic skill can be channeled in such an open and creativity-focused game, and thankful there are people like you who are able and willing to teach people in a polished and digestible format with the help of a literal video game 👏
(sorry for any mildly odd english if there is any, it ain’t my first language 😅)
hey youre welcome and thank YOU! and not a problem, it all was clear to me haha
This vídeo is amaizing dude! Not only you managed to teach me more things about color theory (wich they didnt taught me in my university) you also managed to make parallels with Minecraft and even explain using things in game. Now I believe your truely underrated. ❤
@@folhadea7678 thank you so much! :D
i have a color theory assignment for my bidimentional representation to finish today, and my teacher's methodology was wayyyyy too hard for me to follow. your videos helped me a ton this semester, i keep coming back to review, thank you very much
@@merimars that’s so awesome to hear!! I’m glad I could help out 🥲
Great series! I thought I knew pretty much everything about color theory, but I was surprised to learn about complementary vision theory and certain color labeling terms. Best of luck with your endeavors.
@@vantikay there’s always more to learn! Glad you enjoyed it, thanks for checking it out
You have helped me level up with my building thanks so much you are my go to person to recommend to people
Thank you so much! :)
thanks for all your colour theory videos and all. Hope you keep doing them even though this one didnt go as viral as the others. its just such high quality and easily understandable. Thanks for the work you put in these videos ❤
@@marlindragendorf9623 haha thank you! I do it for yall ❤️
Huh. It's funny how much of this reminds me of music theory - the specifics aren't too related but the overarching ideas of how to use/think about theory is almost identical. I'm curious if there are people in other fields who would say the same. Neat.
@@02_920 right?? I was a musician for a decade or so before I got into visual art, and the theory overlap is awesome, especially with harmony and palettes I relation to intervals and modes
I did not expect quantum physics in a Minecraft video.
Really interesting, thanks for the video!
thank YOU for watching it
Thank you for your tutorials, really like them. Clear and enjoyable!
@@goodnight23672 glad you enjoy them! :)
*True Yellow*
23:26 Most of the yelows we see everyday aren't actually yellow. They're either a red-green, red-yellow, green-yellow, or red-yellow-green mixture. Coming across true yellow, which isn't mixed with either green or red is rare. Mostly because we've designed our environment for normal trichromatic vision. Even "yellow" flowers don't look yellow to me, but are a red-yellow, which is very different to a true yellow. For RGB screens this becomes very apparent, because they cannot reproduce a true yellow at all. Most of the other tetrachromatic colors I see are also not reproducable with an RGB screen. Even if these people at 23:26 would identify a color as "yellow" it probably isn't true yellow and just a red-yellow-green mixture.
*Human Hexachromacy*
5:43 Yes, in most everyday situations we are trichromats with 3 cone types: S, M and L. However, with the presumption that these three cone types are the only ones, we cannot reproduce all the colors we see everyday and all the colors we are capable of seeing. For example, the shimmering effect of most reflective surfaces can only be explained if you take the two eyes' color perspectives as separate, with one set of S, M and L cone types in each eye. These impossible (binocular) color combinations, that result from breaking this binocular and chromatic redundancy of our two eyes, are relatively rare in everyday life, but with the help of special filter/interference glasses and VR headsets you can access this hexachromatic color space. For normal trichromats there are six cone types in total: S1, S2, M1, M2, L1, L2. "1" stand for the left and "2" for the right eyes' cone types. While impossible color combinations are "only" binocular mixtures of trichromatic colors, they are experienced as unique colors/hues with a bit of training, just as magenta for example is "just" a mixture of red and blue.
Earlier I've mentioned that I see tetrachromatic colors. This is true, however I see them non-retinally. I've designed glasses which induce a "true-red non-retinal chromatically-less-redundant" form of tetrachromacy. While I call it true-red tetrachromacy, it also allows for seeing a truer yellow, green, etc. By "non-retinal tetrachromacy" I mean I use my second, normally chromatically redundant eye as a true-red color channel (~630-700nm) and my first eye as a slightly anomalous red-deficient color channel (~400-630nm). With this setup I can see a truer yellow as well as a red-green mixture, for example. Two hues which look the same to my naked eyes, but are completely different with the true-red glasses on. In effect, I'm doing the same thing the very rare supposed female human "yellow" tetrachromats with retinal tetrachromacy do, just a little bit less effective and efficient. Here's an article I've wrote about the glasses: www.color-in-color.info/tetrachromacy_1/non-retinal-tetrachromacy
As a consequence, while normal trichromats just see trichromatic yellow between red and green, for me this red-green range has as many colors as the total trichromatic red-green-blue range, because I'm simulating a fourth cone type. While most people only see about 7 main hues: S, M, L, SM, SL, ML, SML, excluding black; I see about 15 main hues: S, M, L-, L+, SM, SL-, SL+, ML-, ML+, L-L+, SML-, SML+, SL-L+, ML-L+, SML-L+. "L-" stands for the virtual 'more yellow' red cone type, and "L+" for the virtual 'more red' red cone type. I'm basically splitting the L cone type in half and giving it two unique color channels.
And these are just tetrachromatic colors. With VR you can combine any trichromatic RGB color with any other. This results in about 280 trillion impossible color combinations from just 16 million RGB colors on a good RGB screen. And these hexachromatic colors are a wild experience, especially if intergrated intelligently into human vision and VR games. I've already played Minecraft while seeing billions of more impossible colors (confined to the trichromatic RGB color space) and the details you can see are incredible. You can even simulate normal trichromacy (at least as normal as it can get) with impossible colors for dichromats.
Color is so much more complex than everyone thinks. Human color vision (at least for people with two "normally" functioning eyes) can only be fully explained by a hexachromatic color theory. Trichromatic color theory is close, but it doesn't capture all the impossible colors we can perceive, which are all valid colors, especially in a meaningful context.
*Monochromacy*
6:18 Here you should differentiate between "cone monochromacy" and "rod monochromacy". Both result in monochromatic vision, but for cone monochromacy you can still have slightly dichromatic color vision in some lighting situations because of the influence of the rods. In rod monochromacy you additionally have really bad day light vision and can only see one monochromatic hue in any lighting situation.
*Dichromacy Simulations*
5:48 The protanopia disc you're showing there isn't correct. Yellow appears as a relatively bright green (or in this case yellow) to a protanope, not as a washed out yellowish-white. The same for the deuteranopia disc, but slightly shifted.
Knoknowledge and fun! Luv it!
25:40 It’s Akiyoshi Kitaoka!
It’s a shame that my previous comment from a few days ago where I went a little more in-depth who the man was got shadowbanned by youtube; but to keep it brief, Akiyoshi Kitaoka has made tons of optical illusions, and is a proffesor in psychology. He has lots of different works that are worth checking out!
Thank you!
Teaching classes in Minecraft this is crazy about to recommended this to people who don’t even play games just to understand colors better.
@@cameronbeaudoin8760 that’s the goal! Spread the word! Lol
Ive struck gold
@@RACECAGD ❤️
Goose is smartest goose 👌🏻
I mean as far as geese go, I am the smartest, yes... but the bar is quite low
Light does not act like a particle. Its simply only ever measured in a quantized amount. See hung's optics channel for a series on how light can be fully described as a wave. This misconception is super pervasive among otherwise very well educated science communicators.
@@Dogo.R I’ll check it out, is there a specific video by the channel you suggest?
And are you referring to the double slit experiment misconceptions?
@@TheLoosestOfGooses it starts with light and coherence part 1
@@Dogo.R I’ll check it out, thank you
@@TheLoosestOfGooses Have fun!
❤️🔥
4:18 jumpscare