Why don't they teach simple visual logarithms (and hyperbolic trig)?

It seems that you are able to provide a geometric interpretation for any mathematical concept that exist. Simply amazing.

I'm almost 40 and back in school to become an engineer, not having touched math since my teens. This type of visualization is so helpful getting my old brain back on track! I have a feeling I'm gonna be replaying this video a lot 🤓

Here's the thing. I just got home and am extremely tired and definitely not ready to get my brain working on math, or anything demanding that is. So, I got hooked in the first few seconds and my brain started working again. Your skills, sir, are of another world.

I think your visual derivations of the fundamental mathematical concepts is amazing. It helps the people who struggle with visualising the algebraic operations with something visually tangible and making connections which were forgotten by the maths teachers.

The fact that amyone on earth can connect to the web and have their mind expanded in this manner, for free, is wonderful. I am very grateful for this and other maths content on TH-cam. Thank you!

For the demonstration of A(X) + A(Y) = A(XY)
Definitions :
- we define A’(x,y) as the area under the curve between x and y (we notice that A’(1,y) = A(y) and that A’(a,b) + A’(b,c) = A’(a,c))
- we define f_p(z) the transformation of an area z by a factor p
Let’s find an expression for f_p:
Given z=A’(a,b), the top left hand corner of the area is mapped to:
1/p * 1/a = 1/(ap) (squeezing)
which corresponds to the inverse function for a value ap (shifting). Same goes for the top right hand corner.
We can conclude that:
f_p(A’(a,b)) = A’(pa,pb) = A’(a,b)
Let now prove the theorem :
A(x) + A(y) = A’(1,x) + A’(1,y)
= A’(1,x) + f_x(A’(1,y))
= A’(1,x) + A’(x,xy)
= A’(1,xy)
= A(xy)

When I saw the 1+1/2 case for figuring out the base (and mentally extrapolated the rest of the proof), I was shocked- such beauty!

I cant believe after all these years of calculus ive finally seen an intuitive argument for how lnx appears when integrating 1/x 😮

for the 1/x is a anti-shapeshifter
if you squish the graph by 2 along the y axis, then each value of y gets mapped to y/2, while values of x stay where they are. the function that describes this graph is f(x)=(1/x)/2 = 1/(2x)
now let's stretch this graph by 2 along the x axis
each value of x gets mapped to 2x while y doesn't change so f(2x) = 1/(2x) and so f(x)=1/x
the function of this graph is 1/x; same as before

"I can't be bothered to do the hard cases" in my day = "Left as an exercise."
"I can't be bothered to do the hard cases" today = "Leave your thoughts in the comments."

I thought I'd know all of this already, but was pleasantly surprised when you put the circle and hyperbola together and at the geometric proof of the e^α identity. Great video!

The visualization for finding the base (14:30) to (16:30) is marvelous :D

A great way to look at familiar stuff. Top 5 Mathologer video of all time.

I can’t get over how big the dude’s forehead in the thumbnail is.

I love all the visual intuition for why logs and e fall out of 1/x with all the squeeze maps. This video gave me so many aha! moments.

The Professor's workroom looks like a boy's playroom, and vice versa; an anti-shapeshifting space, home to a brilliantly playful and playfully brilliant mind.

As year 10 students were explicitly mentioned:-
First the horizontal strech by a factor of 2, means that the input x was changed to x/2, hence plugging that in gives 2/x.
The vertical squish divides that by 2, leaving us with 1/x.

Apparently the names of the hyperbolic functions are pronounced differently in different places! I had no idea. Perhaps this is a US vs. UK thing?
In my schooling in the US, I have never heard anything other than COSH for cosh(x) and SINCH (homophonous with cinch) for sinh(x).
The other functions I've heard more variation. For tanh(x) some people say TANJ like 'tangerine' and some TANCH. The most difficult one by far to incorporate, I think, is csch(x) wherein you can try to say COSEECH or instead bail out to '1 over SINCH.'

20:58 All this time, I never knew that ln stands for _logarithmus naturalis_
always thought that it's just **natural** to use ln (pun intended)
Also, another beautiful visual explanation from Prof. Polster
Thank you.

I just discovered this channel a couple hours ago, and I have spent over 3 hours in a row watching your videos about sequence, derivatives, and of course trig and log .. it’s funny because I’m not really a math person because I feel like knowing something by just memorizing its efficient enough to apply it on a test but not into real life so that really doesn’t motivates me into doing maths. So it’s nice seeing a deep explanation of these concepts and not just something superficial.

Thanks for taking us on a stimulating mathematical journey! I love the animated proof at the end. It's almost like a poem.

Es hat wie immer sehr viel Spaß gemacht. Die Zusammenhänge der Funktionen geometrisch in dieser Form zu erleben ist wirklich der Hammer.

I put on the captions for my deaf mother and we both appreciate not only the effort you put into them but also the smilies :)

What a pleasure!
So many new perspectives that seem to have been just waiting to be noticed:
1. Looking at y=1/x as a shape invariant to stretch&compress
2. Defining ln(x) and e^x using the curve
3. deriving cosh+sinh identity from their geometric definitions (as opposed to the exponential identities definitions)

Great ways to conceptualize and visualize properties of logarithms. One of my favorite videos.

I paused right after you defined anti-shapeshifters and I tried to find one. I was only looking for finite-area ones though, so here's what I found: the ellipse x^2 + y^2/4 = 1, when stretched horizontally by 2 and squished vertically by 2, becomes x^2/4 + y^2 = 1, which is the same ellipse just rotated by 90 degrees. Every ellipse has one stretch/squish factor for which this works.
Also, as a jaded know-it-all calculus demon, I was completely enamored by 1:50, 14:06, and 28:51. Really excellent!

One of the very few channels I have subscribed to!
This video saved to favorites.
Keep up the fantastic work!

Your excitement is absolutely contagious! What an enjoyable watch!

Always, fascinating!
I followed, surprisingly, until the last example. That's when my brain went flat and would inflate no more, until patched with a second cup of tea.
Why, at the end of each video, is there a smile on my face, and a chuckle in my heart? Perhaps they have much to do with your own gentle encouragement along the way with a chuckle here and a giggle there, however, I'm also quite fond of that sweet tune, pleasingly harmonized on a collection of folksy strings, that serves as a segway and ending to your videos.
As always, thank you and I'll look forward to the next time. 😊

It is nice to see this geometric approach to the topic. The result is not new to me, but the path 😊

18:41 Stretching... reverse of squishing... yes good please keep the mathematical insights coming

I have discovered the "expressing angle as area inside the curve" idea myself when I first encountered hyperbolic sin and cos, but this video makes an incredible job of it and another AMAZING way to find e inside 1/x. Thank you!

Great video! I recently had a project related to hyperbolic trigonometry and it was really nice to see a completely different approach.

This is how I was taught the logarithm definition in school, great video

Excellent video as always! Thanks for your work!

I've missed these videos on my sub feed. Glad to check the channel today :)

Love you mathologer. Great video. I was particularly excited by the proof of the value for the base, it was my first time seeing it.

Excellent introduction to logarithms, I liked the video! Thanks.

Amazaing visualisation and explanation! You do great job!

When you showed the equal area segments on the hyperbola I finally felt like I "got" why it was a rotation. I was aware of the various taylor expansions and exponential related similarities but this was a really good thing to comfort my gut about it.

you were right, that animated proof at the end was absolutely worth the wait!
and thank you SO MUCH for explaining natlogs. I took trig in high school and in college and never understood where e came from or what a natlog was :/ this made sense! thank you!

Excellent explanation. I especially liked the explanation of the hyperbolic trig functions. It's always puzzled me why they're called hyperbolic.
I appreciate the work you've put into this. It must have taken hours and hours to get right.
Well done.

Sometime before Christmas 2023, i started revisiting Trig functions then went down a math rabbit hole. I have been binging videos like this. In high school, we never truly covered log, ln, e. Merely memorized formulae. You have opened up doors for me to understand log/ln/e. Similarly in high school, hyperbolic Trig was avoided. I had no idea until watching this video that trig and logarithms were connected like this. Love the visuals and the in-depth explanations. Keep up the amazing work.

i have never seen the bridge from conic to catenary explained this way! now i understand why so much effort went into trying to find the catenary as a conic section in early days of math

Simplesmente maravilhoso

This was one of the clearest mathologer videos yet. Everything worked. I loved it!

Solid, it gave life to hiperbolic trignonometric that felt allways pretty blury. Thank you!

15:50 The missing chunks look approx triangular, so I calculated the size of the missing triangles, and used that to find a correction factor for the (1+1/n)^n approximation of e. If you multiply that approximation by (2n+2)/(2n+1), you get a much more accurate approximation. For n=100, (1+1/n)^n has an error of 1.35%, but ((1+1/n)^n)*(2n+2)/(2n+1) has an error of just 0.001%

I liked the motivation and the path it took us down, but now I want to know if there are more of these anti-shapeshifters, besides the class we explored!

ngl, when i saw where the visual proof that the base of the "area function" is e was going i had the biggest grin on my face

OMG. I wrote my first (FORTRAN) program 55 years ago to find the solution for x = cosh(x). And yet I didn't know that cosh and the catenary were the same thing until just now! Thank you, Mathologer :)

the length of this one is perfect, and i love the geometric proofs. the logical proofs get so boring! and its always helpful to confirm what you know by coming from a different starting place and taking a different path

A wonderful video! By the way: because alpha is the arclength in sin/cos and the area in sinh/cosh the inverse functions are called arcsine/arccos and ar(ea)sinh/ar(ea)cosh.

I'm always looking for geometric interpretations for the hyperbolic trig functions, and this surely delivered 👍

This is definitely going on my rewatch list

You've taken me back 39 years (!) to my days at Technical College and the seemingly endless amounts of Calculus theory that we had to learn and then had to apply to physical laboratory works it was great to predict the answers mathematically and then prove them on a test rig (we were taught to think in terms of 'analogues' so we could apply the theory equally happily to mechanical or electrical systems)
Today my work involves less mathematics but it still stretches my brain and memory. I'm working on a problem at the moment that involves a lot of electrical relays and, after having spent three days going through electrical wiring diagrams, it has occurred to me that I need to recreate the original logic diagram for the system in order to identify the cause of the problem. I wonder if I still have a good chart template kicking around...

That visual proof that e^a = cosh(a) + sinh(a) is really satisfying! I've always wondered how the exponential related to hyperbolas, i.e. why we call them hyperbolic trig functions. I'd seen the construction in terms of hyperbolas, and I'd seen the representation in terms of the exponential, but whenever I tried to find an explanation how these two were connected, all I got was, "That's just the definition." (Read: I don't know, and I've never thought about it.)

Absolutely deserves a follow! This was amazing. There are too many amazing channels on TH-cam. It really is a golden age ot maths learning! How will I ever have time to watch them all!

very good entertainment! thank you, for the excellent visuals and calm music selection! this is one of my favorite math videos!

Amazing content, as always :)

This is my boyfriend's favorite video. He watches it at least once a week.

I like all of your videos, but for some reason I really loved this particular video. Thank you 😊

Too beautiful. Keep making such videos

Nice work! Gives me some flashbacks to Paul Lockhart's lovely book _Measurement,_ which is like the one textbook that I, as a soon-to-be math teacher, actually really like; of course, I can't base my teaching on it because of these soul-crushing standardized requirements and tests, though (I guess I can at least use it for inspiration). One of my favorite related proofs when it comes to understanding the logarithm based on the graph of the function defined by f(x)=1/x that could have been mentioned, though, is a lovely visual argument that the alternating harmonic series sums to the natural logarithm of two. You restrict yourself to the little region from 1 to 2 and ponder the area under the graph - it's the natural logarithm of two, of course, but you can also approximate it with rectangles. If you use a 1x1 square, you're overshooting a lot, but you can remedy that by taking a rectangle out horizontally to remove the second half, where the overcounting is most egregious. You then add the smallest rectangle you can that still covers the desired area in that region, which has a height of 1/(3/2)=2/3 and a length of 1/2, so its area is a third. I think most of you will know where this is going, right? Our estimation, which still overcounts but is much more accurate, is 1 - 1/2 + 1/3. Now, we remove the second half of the first rectangle (area 1/4) and add a better fit back in that has an area of 1/5, and we also remove the second half of the second big rectangle we have (area 1/6) to get a better approximation with an area of 1/7. And so on and so forth - it's not too hard to convince yourself that this approximation strategy does indeed amount amount to evaluating partial sums of the alternating harmonic series, and the argument shows that they approach the logarithm of 2. Isn't that beautiful, even if it's tricky to describe everything just with words? This is exactly the kind of thing I want to teach eventually.

This video was a joy to watch.

Excellent video! Logarithms are fascinating

The transformations of your cube are glorious 🥰🥰🥰🥰👏👏👏

Great video, as always! Fun fact: in French, ln is usually referred to as "logorithme népérien" or "Neperian logarithm", from Scottish mathematician John Napier who created the first log tables.

Great video as always!
2:28 "1/x was hiding in a spinning cube" because a hyperboloid of two sheets is a ruled surface.
9:00 (Wish we could use A(X)=ln(X) here :P)
Consider the region bounded by {x=1, x=Y, y=0, y=1/x}, after squishing and stretching it becomes the region bounded by {x=X, x=XY, y=0, y=1/x}, thus A(Y)=A(XY)-A(X).
25:40 We have the parametrization (cosh(a), sinh(a)) for x^2-y^2=1. But I never realized the parameter a is indeed the area.

Amazing as always. These always make my day. 😊

Brilliant !! This was precisely the video I had been waiting for all my life !!!

concerning the one-liner: f(x) = 1/x => 1/c * f(x * c) = 1/c * c/x = 1/x Q.E.D.

I know that cosh has a pretty obvious pronunciation in English and that sinh doesn’t, but I’ve often heard that there is no one way of pronouncing sinh because of that. I was taught at least 3 different ways of pronouncing it, but none of them were “shine”. I’ve since opted to use “sinch” since it at least expresses the “h” being at the end and sounds similar enough to cosh to be obviously the related function cosh.

You have shown that knowledge has various facets, some of which are quite stunning and amazing! Thank you.

That was great (as always.) and for once I followed all of it. Thanks.

10:46
For negative integers, A(x^n x^-n) = A(x^n) + A(x^-n) = nA(x) + A(x^-n), so A(x^-n) = -nA(x).
For rationals, qA(x^(p/q)) = A(x^p) = pA(x), so A(x^(p/q)) = (p/q)A(x).
For reals, I'm pretty sure we have to assume A is continuous? For any real number c, we get a sequence of rationals q_1, q_2, ... approaching it. By continuity, the limit of A(x^(q_i)) is A(x^c). To compute this, we want the limit of q_iA(x), which is cA(x).
If we don't assume A is continuous, I'm not 100% certain. My real analysis class has traumatized me to the point that I'm pretty sure there's a weird discontinuous counterexample lurking around the corner, but I can't find it.

20:57 As a French, I was taught "ln" stands for "logarithme népérien" after John Napier, discoverer of logarithms (John Napier's name is often francizied as "Jean Neper").

Nothing short of brilliant visual representation. Thank you for this!

Wow this actually cleared a lot of my confusion regarding the properties of e. Thank you

Galileo was one of the first to notice the "part equals the whole" weirdness with infinities. I find it interesting to contemplate how this then plays out in another puzzle he wrestled with - the shape of cables or ropes under gravity. (He got it wrong- he guessed that they were parabolic.)

I've always pronounced sinh as sinch.

When I saw your fascinating animation, it reminded me of a monograph I read in the Little Mathematics Library when I was young. Those were some very nice little math books! I am moved a lot by your work! One of my friends once said that people are moved by art and music, but why not science and math? Now I understand what he meant!

Finally getting around to this one. I would LOVE some more hyperbolic trig.

This is a really nice visualization. Here’s another you may appreciate… draw a 45 [deg] line through the origin intersecting with f(x)=1/x and label these points B and B’ , with B being the intersection in the positive quadrant. Now draw a circle with diameter BB’ (i.e. centred about the origin with radius |B|). Pick a point, C, on the circle. Take the tangent to the circle at C and intersect it with the line BB’ to get D. From D, draw a perpendicular line and intersect it with the line B’C to get E. The point of intersection, E, will lie on f(x)=1/x and |CD|==|DE|. As a bonus, reflect f(x)=1/x about the circle to generate a very special shape 😉

Another beautiful experience. Thank you

I haven’t used school or university maths in over a year but soon will have to again since I’m going to study and this video got me so hooked on maths again that I see absolutely no problem in doing so. Really great work in visualising and explaining! This video got me really curious again about everything maths related

My brain exploded out of excitement at 14:44 when I realised your argument might be the most beautiful one in existence!😂

Amazing video and visual proof. Thank you for making my day!

Excelent !! Congratulations. Amazing explanation. Best regards 👏👏👏

Very awesome video and insights. Thank you.

Whole thing was great, I especially liked the outro proof. 👍😀

Wow! I wish I'd learned this stuff before I learned calculus! It's pretty amazing that you don't need calculus to explain why the area under the hyperbola y = 1/x is a logarithm, and you only need to evaluate a simple limit to define e. I was equally amazed by your definitions of the hyperbolic functions in terms of areas invariant to shapeshifting, which also doesn't require calculus. Pretty amazing stuff!

Nice. I'm particularly happy to see motivation for sinh and cosh. I've never seen these before.

Awesome video and intuitive visuals as always.

this is the first one of your videos i've been able to follow in a while

Each time I open a mathologer video,its maginficence hits me.

Great video as always, love the geometric proofs! I just wanted to say, there are shape-shifters among closed surfaces. For example the torus (as the quotient of the plane deformed under any 2×2 integer matrix of determinant 1), and perhaps more interestingly, hyperbolic surfaces (genus 2 or higher) under the so-called pseudo-Anosov maps. sinh and cosh also appear in a lot of formulas for these surfaces.

I haven't been for a while on Mathologger, my bad, the content never ceaze to amaze me, this episode was awesome, thanks you 🤠

Danke vielmals für die reichhaltigen Beiträge. Insightful as always.

hi, thank you so much for adding closed captions. youtube can't automatically pick up on math notation and wording so it's suuuper helpful.