Fun fact, the letter π was chosen to describe the ratio of circumference/diameter because of the word 'περιφέρεια' (~periphery) that is the 'περίμετρος' (perimeter) of a circle.

The animations in this video were very good, Presh!

Math history is amazing. This was excellent! Thank you.

If you want the area of a non-circular ellipse, then you can use the formula πab, where a and b are the major and minor axis. For a circle, a and b would be the same.

BUT MY DOUBT IS STILL NOT CLEARED . I always had the doubt about the discovery of pi . Like you have told , old mathematicians found out that every circles circumference to diameter ratio is a constant , which was later given the notation pi . But we tell pi is an irrational number , and from what i know an irrational number cannot be a ratio . If the old guys were trying to find out a ratio then how did we end up in an irrational number?

It seems like the common insight to all these proofs is: 1) The circular curve can be approximated by a sequence of straight lines placed regularly in some pattern close to the curve (ie a regular piecewise linear approximation). 2) The more lines there are, the more closely the sequence approximates the curve with less distortion to the area. In my opinion, calculating π must have been much more difficult than finding the formula for the area given pi. If I recall correctly, I heard somewhere that Archimedes approximated π by finding the perimeter of an inscribed (inside the circle) regular polygon as the video showed, but also a circumscribed (outside the circle) regular polygon. Then he could measure or calculate the perimeter of the outer (circumscribed) and inner (inscribed) regular polygons and use this to figure out some sort of upper and lower bound on π (I might be citing this story incorrectly).

Regarding the last example, I was thinking that you can integrate the different circumferences for the radius going from 0 to r, which is \int_{0}^r 2xpi dx= r^2pi.

It’s amazing how much school doesn’t teach you. From the area of a circle to the quadratic formula, they teach a lot of hows, but not a lot of whys. It makes sense for brevity’s sake, but it’s almost like they’re trying to make you hate math by making it a memory game rather than a problem solving game.

Hey, I'm a brazilian fan of your channel, and I loved it last year when you solve our Pinocheo math problem from OBMEP. This year we again had an interesting problem about some flowers which, if you want to, I can translate to you.

Great video! It's fascinating to see that they came to such an understanding 2,000 years ago.

@1:20 Actually, Liu Hui (劉徽) found the fraction approximation 3927/1250, not the decimal representation.

presh checkout the 2024 JEE advanced paper, all the questions are good and u can get to the solution in one step

I remember at one time thinking π = 22/7 exactly. I missed the point being that it's just a very good approximation that works for a lot of everyday calculations.

I really like methods 2 and 3. This was a great video!

Thank you for an amazing video!

Find the function F(n) = the area of a regular polygon of n sides inscribed in a circle of radius r. Then take the limit of F(n) as n tends to infinity. I did it as an undergraduate taking calculus 2. I found it convincing.

They used pi to represent the value because there was no Greek letter for cake, which as we all know is the superior circular dessert.

nice music as the circle was unwrapped in the 3rd proof. Interesting how each proof used limits to get from a concrete figure towards infinity and a circle.

Okay. But how did they even calculate π?

That’s really wild. But it occurred to me that a guy invented a way to wheel. Then another guy decided to reinvent the wheel. Then some third dude again reinvented the wheel.

Great video. Thanks.

Very nice - though sadly "rectangle" has been spelt as "rectange" on a few screens.

The ancients really had the ability of reasoning and mental extrapolation !

I had never seen the third method before, it's pretty nice (but was probably a pain to formulate and enunciate clearly back then).

Nothing explains it better than the pizza illustration.

I think the question is how to establish a way to prove that this constant ratio of circumference to diameter that we call pi is equal to 3.14...etc . After that areas and volumes follow.

Because pi is, by DEFINITION, the ratio of the circle's circumference to its diameter. So: C = pi*D But D = 2*r, so C = pi*(2*r) To get the area, we can integrate all the little annular rings, each of thickness dr, which just means integrating that circumference formula from 0 to R. The integral of 2*r*dr is r^2, evaluated between the limits: Area = pi*R^2 - pi*0^2 = pi*R^2 Q.E.D. Couldn't be simpler or more obvious.

Old joke: Pi r squared? No, pies are round.

It is sad that back in grade school eons ago we were made to memorize the formulas for basic shapes w/o any form of explanation of WHY.

It was derived by iteration of small slices

Of course it's related with calculus. Just like why deriving the area of a circle is its circumference.

If the curvature remains constant at the perimeter the depth of the wedge will not equal the radius unless the wedges base is a single point ie zero width. Another words at that point the wedge can no longer be used to estimate area. Or given the inability to perform the required measurements approaching infinity the value of Pye can not be finitely determined?

Wow!..really nice

What is so delicious about πr² is that it's describing an infinite number of pieces of cake (or pizza).

Next given the area of a circle find the volume of a sphere and hyper sphere

Mind blown! How is it that pie are square and circle at the same time? 🤔 😝

pie r round. cornbread r square.

Pie are not squared. Pie are round. Cornbread are square. Thank you for detailing the math which overrides my father's joking about Pi.

Is π actually a constant as always claim in human-invented notions of mathematics? The answer is no, it is not. Here is why it is so: A constant is a value which remains the same or fixedly unchanged in all different situations or contexts. Since π is merely a notional quantity value invented by human limited knowledge as a tool to help humans understand or interpret the observed in the physical world in a certain human subjective way, and thus does not actually exist in the real physical world, and its unknowable unknown value always has to be truncated to become approximately definable to be applicable to human-invented mathematical formulas. It depends on each individual's personal purposes how it is truncated, or how many of its endkess digits after the decimal point should be kept. When more accuracy is required more digits of it will be kept, and when less accuracy is needed , less digits of it will be used. It means that its value can be arbitrarily or subjectively changed according to specific purposes of the user, and thus it cannot be considered as a constant, while it varies in different contexts or requirements

what if r=

Thanks

_Ancient thinkers developed this formula, and taught it to the modern civilization.

How did we figure out the value for π ? By brute force ... initially by humans doing basic arithmetic (addition, subtraction, multiplication and division) to numbers that had dozens (then hundreds then thousands) of digits to the right of the decimal point. These days it's computers doing the same basic arithmetic to numbers with 105 trillion digits to the right of the decimal place ... still brute force. The only interesting mathematics is/was (repeatedly) finding a new infinite series that converged faster than the previous fastest converging series.

Thank u

Maravilloso

So what calculation gets you to pi?

What about a fourth method-integration?

Cake are square! Pi are round!

Up until 9:47 - wow I'm smart everything's clear By 10:13 - I rather watch police chase videos

Ok, but how in the first place was the ratio of c/d derived. Was it derived by measuring c and d or what?

22÷7 is really close to pi

The answer is plain obvious , if it wasn't it wouldn't be a circle. 😊

Awe geez MYD, just let it go.

Can anyone tell me when and where the rabbi behind method #3 lived?

Study shouldn't be just for examination!

It's not, everyone knows pie are round 🫵😂

I value much more this type of content and historical background investigation than solving nearly-impossible questions/puzzles. Amazing video!

Just for fun, I pulled out my old Calculus book from college and integrated using the equation for a circle (after solving for y to get y= sqrt(r^2-x^2). I simply integrated from 0-1 (quadrant 1 of a circle with radius r with its center at (0,0)) and multiplied by 4. Sure enough...Area still equals (pi)r^2 !

r² is the area of a square implied by two radii of a circle of radius r that are at 90° to each other. 4r² is therefore the area of the square in which the circle with radius r is inscribed. If πr² is the area of the inscribed circle, then π/4 is the fraction of a square with sides 2r that is taken up by its inscribed circle. Maths is a beautiful thing.

Pie are not square. Pie are round.

Thank you!! I've just done it!! Upon learning of William Jones 1706 work you referenced, I went to Wikipedia and found out that this work (with the first use of the Greek letter pi for representing the ratio between a circle's circumference and its diameter) is titled "Synopsis Palmariorum Matheseos." Then within mere minutes, I found myself buying a copy of it on Amazon!! Thank you so much, Presh, for enlightening me!!!!

One thing if you try the second method on a sphere to get the surface area, you will get the wrong answer.... 3blue1brown did a video on why it breaks for a sphere.

idk i just imagine having 3 squares of side r, and then there's a little bit left to fill once you like cut the corners

archimede's method was so good. felt like a plot twist. thats why i love maths

Never was a fan of Method #2. Method #1 would be great to teach in schools, while method #3 (via numberphile and 1minutephysics) is my personal favorite

I like this format as an addition to the usual problems.

Stop the vid at 8:44 you will see that Rabi Abraham bar Hiyya's proof resembles a Menorah. What an intriguing coincidence. 🙂

The symbol pi, has been around THOUSANDS of years. It just was used for the phoneme p.

Wow, thank you so much for enlightening on very fundamentals of formula for a Circle's area.

But how do you prove C/d for any circle is a constant (pi)?

From first principles, we define A = 2πr. Now consider the infinitesimal increase in area δA arising from an infinitesimal increase in radius δr. That is very close to 2πr.δr. So δA ≈ 2πrδr which leads to δA/δr ≈ 2πr. In the limit as δr tends to 0, the approximations becomes an equality and we get dA/dr = 2πr. That can be solved for A by taking the integral from 0 to r and we immediately find A = πr^2. It's not particularly rigorous, but once you can see that the rate of increase of the area of a circle wrt its radius is 2πr, it should be obvious what the area is.

Here is a simple method: Picture the concentric rings from the third approach. The innermost ring has a circumference of zero (it's basically a point). The outer ring has a circumference of 2πr. Now add up all the circumferences by integrating 2πr from 0 to r. It's a very simple integral that results in πr^2

Ancient People having better imagination than us...

A= 1/2*Tau*r^2 long live tau

Love this history of math stuff. I know middle school and high school students don't really care about where math comes from (I didn't), but I do think it's vital to teach it before college. You never know whose interest could pique.

Why is there ambiguity going on recently ? Sum of angles inside a circle = 360 OR ♾️ , 0.99999 = 1 or ≠ 1 ( by law of scientific significant figures ) ,

8:42 - Ironic that in the Rabi Abraham's solution, it appears as a many-candled Menorah while unwrapping!

You might want to re-read Archimedes' "Measurement of a Circle".

The answer to this question is quite easy, but a little in involved. You are give a straight line on a flat plane of a length, doesn’t matter how long but the whatever the length is you subdivided the line into 2 equal parts, each part represents a unit scale (for simplicities sake). We establish the center as the origin and one reference point at one end of the segment. The length of the line is 2, but we should imagine an esoteric line traveling back to the reference point so in actuality the line is length 4. What is the enclosed area. To have an area you need some sort of enclosure in s second dimension, but the two lines superposition so there is zero. Segments =2 Cum. Len = 4 Area = 0 So at the origin we bisect segment and stretch it so that now we have a square joining points equal distance on two orthogonal axis. The 4 points form 4 chords. We pretend we don’t know the length or any thing about sines and cosines. So if the line going from the reference point and back is a flat loop and we stretch it out the center we are adding length into to each half a segment. 2/2 = 1. The length the line is traveling towards is 1 unit from the circle and since its point was at the origin the distance traversed of the new point is 1. Thus new point it how far from old point, let’s just do one. The reference point is 1 unit in original dimension say a, in the new dimension created the new point is b So length is SQRT((a(new) - a(ref))^2 + (b(new) - b(ref))^2) = SQRT ((0-1)^2 + (1-0)^2) = SQRT(1+1) = SQRT (2). So the tilted square is composed of 4 chords, each chords on an imaginary ⭕️. What is the area under the chords? To arrive at the area we need to project a new radii that bisects each chord. At the intersect of each chord we have a bisector that junctions with 2 equal half chords in this case it’s the SQRT(2)/2=SQRT(1/2). This bisector length is SQRT(1- SQRT(1/2)^2) = SQRT(1/2). Thus treating the chord as the base the area = halfchord * bisector which is SQRT(1/2)^2 = 1/2, the combined area under the chords is 4*1/2 = 2 # c p A/c A 2 2.0 4 0 0 4 1.4 5.7 0.5 2 The answer is right here we just cannot see it yet. I will point it out where I hid it. When I said we will use the chord as the base this means we used the bisector as the height, so I did a change of basis. But the I calculated based on the halfchord and bisector, which is correct, but as we will see that in calculating the area we’re removing piecemeal half the perimeter. I will do one more. So we are going to create 8 new chords. Again we start at our reference point (1,0). So we have defined the length of the halfchord or bisector as SQRT(1/2). The new chord is SQRT((bisector-1)^2 + (halfchord-0)^2)^2. The segment outside of the bisector is (1- SQRT(1/2))^2 = 1.5 - SQRT(2) the square of the halfchord is SQRT(1/2)^2 Chord “⭕️/8” = SQRT((1.5 - SQRT(2))+(1/2))=0.7653, its bisector = 0.923 and the area/ea = 0.3535 and total area is 2.828 If we repeat this process about 23 more times eventually we get to a point where the bisector is indistinguishable from 1 on most devices and does not change, each new chord is equal to the previous halfchord. But unchanging is the per chord calculation of area, area is 1/2 base x height. So the question is why this is the case. The ⭕️ is an abstraction created by humans, it’s actually points on a line connected by chords. A rectangle is another abstraction created by humans. We defined this as 4 rectilinear line segments and using this system we define simple area. But the area swept by each line segment,chord on circle, is not rectilinear. When we bisect the chord we generate 2 right triangles, when the diagonal sides are abutted to each other they are rectilinear and we have a calculable area, but in doing that, in 2-D space the displacement of the chord in simple area with one dimension now superpose half upon itself. So there is one detail here we need to make this work. In the beginning of the problem I set the parameter of the argument. Whatever the length is I am assigning a new length of 2 new units, I then mystically stretched the line by 2 units so that I could fill in an empty area. These are artificial processes, they are not real, they begin in the imagination. In doing this I forced the radius to be 1, in the third step I forced out another dimension. So let’s argue the original line length is 200, I set its length to 2, I stretched its length to 400 (4) so it would return to its reference point, then I processvely stretched it in another dimension to 628.32. In essence I forced most of the line into 2 dimensional space by creating a curvature. The force is 100 outward in every direction. And so to make this work in need to multiply the area I made by the area scale factor which is r^2. Where is this, let’s look at the first second dimensional stretch. I forced out in the second dimension 100 units. I then defined a line going from the second dimension back to the first. I then defined the area as area between the line and the origin as defined by to radii. So now I have an area centered around a direction vector (45°), so that area is 0 units/height on one end and 141.42 units per height one the other end of each radii. But the radii point along different vectors, the bisector splits the difference. In doing this we create a new basis z for each radii which displaces along z a fraction of the displacement along x (for the reference point). As a consequence that displacement is the cosine of the angle which centers the bisector between to radii that with the chord form the area. The halfchord just happens to be the sine of half the angle of the chord. Thus in this case area along each bisector is (r * sine = halfchord)(r*cosine = bisector) = r^2 sin*cos where angle is 1/2 the chord. As perimeter goes to 2pi, cosine goes to r and area goes to the r^2 * sine of 1/2 the chords angle. In this case To der

I love how excited you get, Presh! Keep it up! 👏👏👏

What do you use to make your animations? They're superb!

For those that can't remember that area=π r r (phone doesn't have a squared symbol) I think of the hexagon in a circle, and think of the fact that the 6 triangles make 3 rhombi (is the plural or rhombus correct I wonder), which are slightly squashed squares with 'r squared' as their area...thus the whole circle area is a bit bigger than 3x the rhombi areas and that π allows for this slightly bigger amount....thus area = π (3,14etc) X a rhombus area (approx R squared). Thus I am never in doubt about the formula....Similarly circumference is just more than 6 x the 'r' of the hexagon so c = 2 x π (6,28etc) x 'r' ......not much help, but with those of us who struggle to remember formulas clearly in our dotage it's a way of checking you have the right one!

Years and years of math education and I don't recall ever being taught any of these derivations. I was just told how to calculate it.

Loved it ❤ my fav proof is the 2nd one

Area = 4 ∫ √(r²-x²)dx between 0 and r let x = rcos(x) then dx = -rsin(t) dt Area = -4r² ∫ sin²(t) dt between π/2 and 0 Since cos²(t) + sin²(t) = 1 and cos²(t) - sin²(t) = cos(2t) we get sin²(t) = ½ (1 - cos(2t)) So... Area = 2r² ∫ 1 - cos(2t) dt between 0 and π/2 = 2r² [ t - 2sin(2t) ] between t=0 and t=π/2 = πr²

While target shooting at 300 yards I found something strange. 1 MOA (1/60 of a degree) at 300 yards is pi, the cord dimension of 1MOA included angle in inches. I checked this on my calculator it rounds to 10 digits so I used EXCEL. (300 yds) 10800" x 1/120° sin x 2 = π and it is correct to 98 digits.

Keep on posting these videos 🙏

Of course, what you *didn't* show was how they got the numerical values they had... 😁

One more explanation is the one you can call the ratio of a circle to a square with equal radius and apothem using the percentage of the circle's π (constant of 3.14159) and the square's perimeter-apothem ratio (constant of 4) which is approximately 80%: (3.14159÷4)×area of the square(diameter or 2×radius)^2 or (π÷4)×D^2=(π÷4)×(2r)^2=(π÷4)×(4r^2)=πr^2

This is the second video of yours that I have watched related to Pi. In both videos you only go back in history to Archimedes. The approximation for Pi goes back much farther than that. There is an ancient Egyptian papyrus dating back some 3,500 years describing an estimation for Pi. I believe this papyrus is held in the British museum. Back then they used fractions to denote the value as decimals hadn't been invented yet. The value for Pi they came up with 3,500 years ago was approximately 3.16. Or, 4(8/9)^2. Close enough for Egyptian government work I guess, LOL.

If you're going to include a "rigorous" approach that includes a double integral, why not just do the single integral of the circumference? Integrate 2πr with respect to r and you get πr^2, the fastest method of any you showed (albeit requiring knowledge unavailable to the ancients).

Alternately you can simply roll a wheel of diameter D, x number of revolutions, and distance traveled will be D÷2πr= revolutions. Interestingly enough. If r=h+t hub radius plus tread thickness. And h=t=2"/π What you end up with is a version of the viral incorrect video. 8"÷2(2"+2")=1 revolution. Also, you find that D÷2πr≠D/2πr Illustrating the difference between ÷ and /.

A circle, centered around the orgin with radius R can be defined by the equation: x^2+y^2=r^2. But, when does the limit as N -> inf. sided polygon inscribed inside a circle, centered around the Orgin approach the circle equation? Also, if it approaches the shape of a circle, then how come polygons corner points are connected with line segments, but 2 points on a circle's circumference aren't connected with a line segment, being shaped more like a curve between 2 points? Moreover, can it be proved that this area between the polygon and the curve of the circle converges, and approaches ZERO as the number of points on the infinite sided polygon approaches infinity?

The Surya Siddhanta was conceived 12500 BC. Zero was known to the ancient Hindus and so was the ratio of the circumference to the diameter. Indeed calculus was written down in text books at least 200 years before Newton ! Plagiarism ? Copernicus we know today, did not contribute any thing new to mankind. Aryan invasion of India has been definitely debunked , not just by genetics. Eugenics persists despite the demise of colonialism. Aryabhatta wrote a (lost) treatise on the Surya Siddhanta. The ancient Hindus had a word for 10^32 and 10^~32 ! Base 10 and the zero were well known to them.

The original definition of π in Greek mathematics was not as the circumference constant (C/d) but as the area constant (A/r²). That A = π × r² was essentially proven in proposition XII.2 of Euclid's Elements. But Euclid never mentioned a circumference constant. That, as the video describies, is due to Archimedes.

How about the other simple calculation for 3rd method? The area contain circles perimeter with r=0 to r=R so integrain of (2pi*r) and r from (0 to R) will be (2* pi * R^2 / 2) or simply (pi * R^2)

r is raised to the power of the dimensions the radius is filling. A 2D circle is power 2. A 3D circle (sphere) is power 3. So a 1D ‘circle’ on a straight line is just r, and a 4D circle (Hyper sphere) is r raised to the power 4. Dunno what Pi does in these instances though…I mean it just stays Pi in circles and spheres, but what about higher and lower dimensions? Further brain stretching…what happens with -ve dimensions, ie. Less than a point.

Integrals is easier

Archimedes' proof does NOT use limits. How are you going to discuss this amazing proof without showing both the inscribed and circumscribed polygon and solving by inequalities?

Just curious, as I am old. Don't schools still have teachers write out this proof on the blackboard in ninth grade in Beginning Geometry? As I recall, much of the year was spent on proofs like this and how to solve complex questions combining various properties of curves and polygons.