It makes infinitely more sense when you stop thinking of TSC as a stick figure, and start thinking of him as the numerical value that he is: *frames per second.* He is innately math meeting visuals. That’s why, for example, the multiplication sign speeds him up: it increased his play rate.

I think the reason symbols work on TSC is because he's using the number on his attributes, such as speed and position, the two attributes he edits in the animation. He isn't a number, but he's composed of them, like atoms.

You see that a youtuber makes a really masterpiece when even the university teachers are talking about it.

There's a lot of people who are going to finally understand concepts by seeing them in visual form. This is incredibly well done

10:04 something interesting about the integral is that it leaves behind a trail because the integral is the area under a curve

I'm always so shocked to see the attention to the tiniest of rules and details in their videos. Most of the tricks we saw in the Minecraft series could be done in-game, which is insanely cool as the videos serve an "educational" role too in that regard. Same with this video, just nothing but tremendous praise

THE MATH LORE 0:07 The simplest way to start -- 1 is given axiomatically as the first natural number (though in some Analysis texts, they state first that 0 is a natural number) 0:13 Equality -- First relationship between two objects you learn in a math class. 0:19 Addition -- First of the four fundamental arithmetic operations. 0:27 Repeated addition of 1s, which is how we define the rest of the naturals in set theory; also a foreshadowing for multiplication. 0:49 Addition with numbers other than 1, which can be defined using what we know with adding 1s. (proof omitted) 1:23 Subtraction -- Second of the four arithmetic operations. 1:34 Our first negative number! Which can also be expressed as e^(i*pi), a result of extending the domain of the Taylor series for e^x (\sum x^n/n!) to the complex numbers. 1:49 e^(i*pi) multiplying itself by i, which opens a door to the... imaginary realm? Also alludes to the fact that Orange is actually in the real realm. How can TSC get to the quantity again now? 2:12 Repeated subtraction of 1s, similar to what was done with the naturals. 2:16 Negative times a negative gives positive. 2:24 Multiplication, and an interpretation of it by repeated addition or any operation. 2:27 Commutative property of multiplication, and the factors of 12. 2:35 Division, the final arithmetic operation; also very nice to show that - and / are as related to each other as + and x! 2:37 Division as counting the number of repeated subtractions to zero. 2:49 Division by zero and why it doesn't make sense. Surprised that TSC didn't create a black hole out of that. 3:04 Exponentiation as repeated multiplication. 3:15 How higher exponents corresponds to geometric dimension. 3:29 Anything non-zero to the zeroth power is 1. 3:31 Negative exponents! And how it relates to fractions and division. 3:37 Fractional exponents and square roots! We're getting closer now.. 3:43 Decimal expansion of irrational numbers (like sqrt(2) is irregular. (l avoid saying "infinite" since technically every real number has an infinite decimal expansion...) 3:49 sqrt(-1) gives the imaginary number i, which is first defined by the property i^2 = -1. 3:57 Adding and multiplying complex numbers works according to what we know. 4:00 i^3 is -i, which of course gives us i*e^(i*pi)! 4:14 Refer to 3:49 4:16 Euler's formula withx= pi! The formula can be shown by rearranging the Taylor series for e^x. 4:20 Small detail: Getting hit by the negative sign changes TSC's direction, another allusion to the complex plane! 4:22 e^(i*pi) to e^0 corresponds to the motion along the unit circle on the complex plane. 4:44 The +1/-1 "saber" hit each other to give out "0" sparks. 4:49 -4 saber hits +1 saber to change to -3, etc. 4:53 2+2 crossbow fires out 4 arrows. 4:55 4 arrow hits the division sign, aligning with pi to give e^(i*pi/4), propelling it pi/4 radians round the unit circle. 5:06 TSC propelling himself by multiplying i, rotating pi radians around the unit circle. 5:18 TSC's discovery of the complex plane (finally!) 5:21 The imaginary axis; 5:28 the real axis. 5:33 The unit circle in its barest form. 5:38 2*pi radians in a circle. 5:46 How the radian is defined -- the angle in a unit circle spanning an arc of length 1. 5:58 r*theta -- the formula for the length of an arc with angle theta in a circle with radius r. 6:34 Fora unit circle, theta /r is simply the angle. 6:38 Halfway around the circle is exactly pi radians. 6:49 How the sine and cosine functions relate to the anticlockwise rotation around the unit circle -- sin(x) equals the y-coordinate, cos(x) equals to the K-coordinate. 7:09 Rotation of sin(x) allows for visualization of the displacement between sin(x) and cos(x). 7:18 Refer to 4:16 7:28 Changing the exponent by multiples of pi to propel itself in various directions. 7:34 A new form!? The Taylor series of e^x with x=i*pi. Now it's got infinite ammo!? Also like that the ammo leaves the decimal expansion of each of the terms as its ballistic markings. 7:49 The volume of a cylinder with area pi r^2 and height 8. 7:53 An exercise for the reader (haha) 8:03 Refer to 4:20 8:25 cos(x) and sin(x) in terms of e^(ix) 8:33 This part +de net tnderstand, nfertunately... TSC creating a "function" gun f(x) =9tan(pi*x), so that shooting at e^(i*pi) results in f(e^(i*pi))= f(-1) = 0. (Thanks to @anerdwithaswitch9686 for the explanation - it was the only interpretation that made sense to me; still cannot explain the arrow though, but this is probably sufficient enough for this haha) 9:03 Refer to 5:06 9:38 The "function" gun, now 'evaluating" at infinity, expands the real space (which is a vector space) by increasing one dimension each time, i.e. the span of the real space expands to R^2, R^3, etc. 9:48 logl(1-i)/(1+i)) = -i*pi/2, and multiplying by 2i^2 = -2 gives i*pi again. 9:58 Blocking the "infinity" beam by shortening the intervals and taking the limit, not quite the exact definition of the Riemann integral but close enough fo this lol 10:17 Translating the circle by 9i, moving it up the imaginary axis 10:36 The "displacement" beam strikes again! Refer to 7:09 11:26 Now you're in the imaginary realm. 12:16 "How do I get out of here?" 12:28 Den't quite get this-One... Says "exit" with t being just a half-hidden pi (thanks @user-or5yo4gz9r for that) 13:03 n! in the denominator expands to the gamma function, a common extension of the factorial function to non-integers. 13:05 Substitution of the iterator from n to 2n, changing the expression of the summands. The summand is the formula for the volume of the n-dimensional hypersphere with radius 1. (Thanks @brycethurston3569 for the heads-up; you were close in your description!) 13:32 Zeta (most known as part of the Zeta function in Analysis) joins in, along with Phi (the golden ratio) and Delta (commonly used to represent a small quantity in Analysis) 13:46 Love it - Aleph (most known as part of Aleph-null, representing the smallest infinity) looming in the background. Welp that's it! In my eyes anyway. Anything I missed? The nth Edit: Thanks to the comment section for your support! It definitely helps being a math major to be able to write this out of passion. Do keep the suggestions coming as I refine the descriptions! Comment credit goes to @cykwan8534

This reminded me of why I started to like math in school, before college ruined it. Feels nostalgic.

Imagine this is like a game, where you discover maths and the dialogue explain to you endlessly

While I don't like maths all that much, I used to and this brings a smile to my face. This is amazing.

It’s insane that this animation about math is not only flashy, but also makes sense! Props to Alan Becker’s team for making this animation, and to you for giving an in-depth analysis!

as someone who hated doing math but loved learning the concepts and what math can do, this video is amazing; visuals are so important for learning and being able to see it in form helped me learn what I couldn’t in class. Your analysis really helps!!

5:04 in this case, TSC Is considered as X, since he is not a number, the "math dimension" has to do something with him if he include himself in an equation of sort, so TSC is X, making X rotate 90° on the axis, so watever his position was (if x was a point on the axis), it is rotated by i

0:27 I think you should’ve added the fact that the “motion blur/blending/in-between” frames actually have an equals sign! I find that really neat and fascinating, because they took the 1 = 1 concept and smudged it in with animation!

As a physician who loves physics and maths, I absolutely love this gem of a masterpiece ❤️

Honestly I was scared looking at all this without an explanation, fearing I forgot “how to math” but once I saw this I understood I had an understanding of the math because I recognized it, I’m filled with calm now that I can understand this level of math, thank you?

You have managed to condense trigonometry, algebra, introduction to calculus, and all the fundamentals required for those subjects within a single animated video with an entertaining plot of 14 minutes. Outstanding work. Definitely will be sharing this as a reference for anyone I end up teaching some math to.

Of all the analysis videos I've seen on this animation so far, this one is definitely the best

0:08 Everything starts with 1 0:15 a=a 0:18 Addition discovered 0:28 You can add as many numbers as you want 0:33 2-digit numbers discovered 0:45 2 = (1+1) 0:48 You can add any number 0:58 3-digit numbers discovered 1:24 Subtraction discovered 1:35 Negative numbers discovered 1:39 -1 = e^i(pi) 2:05 Negative numbers are unique too 2:23 Multiplication discovered 2:35 Division discovered 2:48 a ÷ 0 = undefined 3:03 Square numbers discovered 3:17 a³ = area of cube with side length a 3:29 a⁰ = 1 3:30 a^-1 = 1/a 3:37 a^(1÷2) = sqrt(a) 3:43 sqrt(2) is irrational 3:50 sqrt(-1) = i 3:57 i + i = 2i 3:59 -1 = i × i 4:46 -1 + 1 = 0 (Look at the swords) 4:53 2 × 2 = 4 part 2 at 5 likes

Let’s simplify these Mathematical Concepts for you: 1. **Calculus**: • Calculus is like a superpower in math that helps us understand how things change and move. • Imagine you’re driving a car and want to know how fast you’re going at any given moment. Calculus helps you figure that out by looking at how your speed changes over time. 2. **Derivatives**: • Derivatives are like the magic glasses of calculus that let us see how a function changes at a specific point. • Picture a roller coaster - the slope of the track at any point tells you how steep the ride is. Derivatives do the same thing for math functions, showing us the slope or rate of change. 3. **Anti-Derivatives/Integrals**: • Integrals are like the reverse of derivatives. They help us find the total amount or area under a curve. • Imagine you’re filling a pool with water. Integrals help you calculate how much water you’ve added by looking at the rate of flow over time. 4. **Number Theory**: • Number theory is like a treasure hunt in math, where we explore the properties and relationships of whole numbers. • Think of it as solving puzzles with numbers, like finding prime numbers or figuring out patterns in sequences. 5. **Euclidean**: • Euclidean geometry is like the basic building blocks of geometry, dealing with points, lines, and shapes in flat space. • It’s like playing with blocks and building structures in a 2D world, where everything follows simple rules. 6. **Topology**: • Topology is like the study of shapes and spaces, but with a twist - it’s more interested in the properties that don’t change when you stretch or twist them. • Think of it as studying rubber bands and playdough, seeing how they can be squished and pulled without changing their essential properties. 7. **Game Theory**: • Game theory is like playing chess but with math. It’s all about making strategic decisions in competitive situations. • Imagine you’re playing a game of rock-paper-scissors. Game theory helps you figure out the best strategy to win, even against tough opponents. 8. **Linear Algebra**: • Linear algebra is like the superhero of math that helps us solve systems of equations and understand transformations in space. • Picture a Rubik’s cube - linear algebra helps you figure out how to twist and turn the cube to solve it, using matrices and vectors. (Tips and Tricks: • Think of Calculus as the detective, derivatives and integrals as its tools for understanding motion and change. • Remember Number Theory as the treasure map leading you to hidden mathematical gems. • Visualize Euclidean Geometry as building blocks and Topology as rubber bands and playdough. • Picture Game Theory as a strategy guide for winning games, and Linear Algebra as a toolkit for solving puzzles in space.) In summary, these mathematical concepts are like tools in a toolbox, each serving a different purpose but working together to solve problems and unlock the mysteries of the universe. Whether you’re exploring the properties of numbers, analyzing strategic decisions, or understanding shapes and spaces, mathematics is always there to guide you on your journey of discovery!

I knew that there was a lot of math in this video that was going directly over my head, but I trusted the animator to have done their research. I'm glad to see that I was correct. I'll have to send this to some of my engineer friends and see what they think.

10:32 had me stumped for a while, but I think the interpretation is that he's feeding every point along the circumference of the circle (sinx + cosx) into the tan function simultaneously, so every point along the circumference of the circle is emitting the tan death ray at once

Python with Prosper also covered this animation frame by frame and with some historical explanation. The effort being put into the animation and analysis is insane.

1. **Coefficient**: • Coefficient is like the number that hangs out 😎 in FRONT of a Variable ❎ in a math expression. • It’s like the price tag 💲🏷️ on an item in a store - it tells you HOW MUCH of the Variable you have. (For example, in the Expression 3x, 3 is the Coefficient of x.) 2. **Base**: • Base is like the foundation of a math operation, especially in Exponentials and Logarithms. • It’s like the bottom of a building 🧱 - everything else rests on top of it. (In the Expression 2^3, 2 is the BASE.) 3. **Exponent**: • Exponent is like the little number floating above ☁️ the base, telling you how many times to MULTIPLY✖️the base by itself. • It’s like the power that makes things Grow ⬆️ or Shrink ⬇️ in Math. (In the Expression 2^3, 3 is the Exponent.) 4. **Variable**: • Variable is like the mystery number in a math problem that can CHANGE or VARY 📈📉. • It’s like a box that can hold different things depending on the situation. (In the Expression 3x + 5, x is the Variable.) 5. **Constant**: • Constant is like the unchanging part of a math expression, always staying the SAME ✅. • It’s like the fixed number that NEVER MOVES in a game. (In the Expression 3x + 5, 5 is the Constant.) 6. **Monomial**: • Monomial is like a simple math expression with just ONE term, like a single ingredient in a recipe. • It’s like a SOLO player🧍‍♂️in a game, doing its OWN THING without any partners ❌👫. (For example, 3x or 5y are Monomials.) 7. **Polynomial**: • Polynomial is like a more complex math expression with MULTIPLE TERMS added or subtracted together. • It’s like a team of players working together to solve a problem 👫🧑‍🤝‍🧑. (For example, 3x + 5 or 2x^2 - 3x + 1 are Polynomials.) 8. **Relationships and Differences**: • Coefficients, Constants, Variables, and Exponents are ALL PARTS of Expressions, while Base is specifically related to Exponentiation. • Monomials are a specific type of Polynomial with just ONE TERM, while Polynomials can have MULTIPLE TERMS. • Coefficients and Constants are similar in that they’re BOTH FIXED numbers, but Coefficients are associated with Variables while Constants stand aline. (Tips and Tricks: • Remember the “C” connection: Coefficient, Constant, and Constant Base (in Exponentials). • Think of Variables as the “variable villains” that can change their value anytime! • Monomials are like “mono” (single) and Polynomials are like “poly” (multiple) - simple and complex, respectively.) In summary, these Math Terms are like building blocks that help us understand and manipulate expressions and equations. They each have their own role to play, but together, they create the rich tapestry of mathematical concepts and problems we encounter.

That's a really good video! It explained everything in a good way, and was the first one that came in the recommendations that actually says something smart about the math. As a big math fan, I learned today some new stuff. The Tailor series, the small integral references etc. were all incredibly helpful. Thanks for the video!

Now when it's explained like this, i would love to have a game that makes us use maths like they did in the animation. Learning maths like that would have been way more fun!

1. **Reciprocals**: • Reciprocals are like the mirror image🪞or opposite of a number, but FLIPPED UPSIDE DOWN 🙃 in a fraction. • If you have a number like 2, its RECIPROCAL is 1/2. It’s like turning the number UPSIDE DOWN 🙃 and making it a FRACTION 1️⃣/2️⃣. • Reciprocals are like partners in a dance 🕺💃 - they’re different, but they fit together perfectly ✨. 2. **Usage in Math**: • Reciprocals are used in math to solve equations, simplify expressions, and perform operations like division. • For example, when you divide a number by its reciprocal, you get 1. It’s like dividing a pizza 🍕 into equal parts - you get one whole pizza. 3. **Usage in the Real World**: • Reciprocals are used in many real-world situations, like when you’re cooking and need to adjust a recipe. 🎂 If a recipe calls for 1/3 cup of flour and you want to make THREE TIMES 3️⃣✖️ as much, you’d use the RECIPROCAL (3/1 or just 3) to multiply the amount of flour needed. • They’re also used in measurements, like converting between different units of measurement. For example, if you know that 1 mile is equal to 1.609 kilometers, you can find the reciprocal (1/1.609) to convert kilometers to miles. 4. **Tips and Tricks**: • Think of reciprocals as the opposite numbers that complete each other, like puzzle pieces fitting together. • Remember that when you multiply a number by its Reciprocal, you get 1. It’s like UNDOING the operation you started with. • Reciprocals are like friends who always have each other’s backs - they’re different but always there to help out when needed. (In summary, reciprocals are like the FLIP SIDE of numbers 🪞, essential for solving Equations, simplifying Expressions, and performing Operations in math and the real world. Whether you’re dividing pizzas 🍕 or converting measurements ⚖️📏, understanding Reciprocals helps you navigate the world of numbers with ease. Just remember, they’re like the Yin to the Yang ☯️ of Mathematics, always ready to lend a helping hand!)

Thank you!!!!! I’ve been waiting for someone to do this! ❤ I loved the Aleph at the end. I have dyscalculia but love the concepts of math. So frustrating! It was so nice to see all this laid out like it was and I was just hoping someone would label all the different functions and formulas!

3:16 power is repeated multiplication (which itself is repeated addition) 5:05 the bow that TSC uses is actually just '2x2=' oriented differently (idk how to explain it), which is why the projectile is '4' (answer)

Everything Alan Becker touches is given full respect of the concept

Let’s break it down these Calculator Symbols 🔢 step by step: 1. **MC, M+, M- and MR:** • MC (Memory Clear) clears the memory in the calculator. • M+ (Memory Plus) adds the current number on the display to the memory. • M- (Memory Minus) subtracts the current number on the display from the memory. • MR (Memory Recall) retrieves the number stored in memory and displays it on the screen. Example: Let’s say you’re adding up a list of numbers on your calculator. If you want to store a number in memory, like 10, you would press “10 M+”. Then, if you want to recall that number later, you press “MR” and it will show 10 on the screen. 2. **Rad:** • Rad switches the calculator to “radians” mode for trigonometric functions. Radians are a way to measure angles, like degrees but slightly different 📏⭕️. Example: If you’re solving a math problem involving trigonometry in radians, you’d press “Rad” on your calculator to make sure it’s using the correct mode. 3. **Sinh, Cosh, Tanh (Hyperbolic Functions):** • These are special functions used in mathematics, especially in calculus and geometry. They are related to exponential functions and have applications in various fields. • Sinh (Hyperbolic Sine), Cosh (Hyperbolic Cosine), and Tanh (Hyperbolic Tangent) are used to calculate values based on hyperbolic functions. Example: Imagine you’re studying a rocket’s trajectory 🚀. Hyperbolic functions might help you understand the rocket’s acceleration or velocity over time ⏳. 4. *X!:* • This symbol represents factorial, which is the product of ALL positive integers up to a GIVEN NUMBER ⛓️. For example, 5 factorial (written as 5!) is 5x4x3x2x1=120. Example: Let’s say you want to calculate how many different ways you can arrange a set of 5 books 📚 on a shelf. You’d use factorial: 5. *In:* • This is the Logarithm function with base , where is Euler’s number, an important mathematical constant approximately equal to 2.71828. Example: If you have a problem involving exponential growth 📈 or decay 📉, you might use the natural Logarithm function to solve it. 6. *Rand:* • Rand generates a random number between 0 and 1. It’s useful for simulations, games, or any situation where you need randomness 🤪. Example: If you’re playing a game that involves rolling a dice 🎲, you might use Rand to simulate the randomness of the roll. 7. *e and EE:* • is Euler’s number, a mathematical constant approximately equal to 2.71828. It’s used in Calculus, Exponential Growth and Decay, and many other areas of mathematics. • EE is often used on calculators to represent POWERS OF 10 in scientific notation. For example, can be written as . Example: If you’re calculating compound interest, you might use as the base of the exponential function to represent continuous compounding 💹. (*Tips and Tricks:* • Memory Functions (MC, M+, M-, MR): Think of these as a calculator’s way of keeping track of numbers for you, like a little notepad 🗒️. • Rad: Remember “Rad” as short for “Radians,” which are like a different kind of measurement for angles ⭕️📏. • Hyperbolic Functions (Sinh, Cosh, Tanh): These are like cousins of the regular trigonometric functions, but they’re used in different situations, like when dealing with curves that look like bows or arches 🏹. • Factorial (X!): Think of it as “multiply all the numbers from 1 up to this one.” It’s like making a big chain of multiplication⛓️. • Natural Logarithm (In): This is like the “logarithm version” of the exponential function. It helps undo exponential growth or decay 📈📉. • Random Number (Rand): Use it when you need to add a little bit of unpredictability to your math 🤪. • Euler’s Number (e): Remember it’s a special number like 3.14 but even more special because it shows up all over the place in math 🧮.) By understanding and using these symbols and functions, you can solve a wide variety of mathematical problems and even have some fun along the way!

8:51 got me dead 😂 " someone touched that radius again"

4:34 I believe this is mostly a velocity thing where instead of TSC’s speed Accelerating by let’s say 1.2units(or Meters)/second, by adding a Multiplication Symbol to their legs, TSC’s Acceleration is now x1.2ups instead of +1.2ups. 7:26 This is fun because the Number just normally clashes with the Arclength/Radii, unlike the Number Sword Clashing Earlier. The Radius Length is a defined term, and therefore cannot be “deducted” or other similar variables would also have to adjust to this truth. However, the Arclength(of r=1), is as strong as a 1 +/- sword, and will be deflected by a 2 or higher.

You sir, are a hero, spreading our word of math to the world. Goddamn, now everyone can appreciate the beauty of math :)

Let’s explore the differences between Parabolas and Hyperbolas in a simple way: 1. **Parabola**: • A Parabola is like a graceful curve ⤴️ that looks like a smile 😃 or a frown 🙁, depending on its orientation. • It’s the shape you get when you graph a quadratic equation, like . • Picture throwing a ball into the air 🏈- its path forms a parabola as it goes up and then comes back down. • Parabolas have a special point called the VERTEX, where the curve changes direction. It’s like the peak of a hill 🏔️ or the bottom of a valley. 2. **Hyperbola**: • A Hyperbola is like two mirrored curves🪞⤴️ that stretch out to infinity ♾️, forming a symmetrical shape. • Imagine two branches of a tree 🌲 that grow apart from each other, but NEVER touch ❌. • Hyperbolas have two SPECIAL LINES called ASYMPTOTES, which the branches get closer and closer to but never actually touch ❌. It’s like chasing after a dream that you can never quite reach. (Differences: • Parabolas have a SINGLE curve ⤴️, while Hyperbolas have TWO distinct branches ↩️↪️. • Parabolas can open upwards, downwards, left, or right, while Hyperbolas stretch out horizontally or vertically. • Parabolas have a Vertex, while Hyperbolas have Asymptotes.) (Similarities: • Both Parabolas and Hyperbolas are types of conic sections, which are shapes formed by SLICING a cone. • They’re both used in mathematics to model various phenomena and in engineering to design structures like satellite dishes and reflectors.) In summary, while both Parabolas ⤴️ and Hyperbolas ↩️↪️ are curved shapes, they have distinct characteristics that set them apart. Parabolas are like graceful smiles or frowns 😃🙁, while Hyperbolas are like mirrored branches stretching out to infinity🪞📏♾️.

more things to note and perhaps clarify, 4:22 graphically, using a negative sign on the x coordinate of a point in space flips it about the y-axis. Here, it flips TSC around. This happens again at 8:03 but relative to the graph's (0,0). 6:01 θ and r are polar coordinates. Where θ is a phase and r is a magnitude. The equation θr equals the arclength the dot travels from a reference direction. 7:04 the highlighted area is equal to the area of the unit circle. This becomes more significant at 10:38, when it projects into an area of effect. 7:30 subtraction of radians when depicted in the complex plane results in a clockwise rotation, which is the direction that the slash arcs travel. 7:45 The formulation for this is a little confusing. 2πr is the equation for circumference, while πr² is the equation for a circle's area. The way TSC forms his shield suggests that his shield has a circumference of 4, and an area of 4π, which isn't possible. A circle with an area of 4π has a radius of 2, and the circumference of a circle with a radius of 2 is 4π, not 4. (But interestingly enough, a circle with a radius of 2 has the same circumference and area.) 8:26 Personally, I would depict e^(-iπ) as cos(π) - i*sin(π) because that negative symbol bears a lot of significance when working with signals. Sine and cosine have this weird relationship with negative symbols. cos(x) = cos(-x), but sin(x) ≠ sin(-x). Instead, sin(x) = -sin(-x).

My question is how TSC learnt math so fast, enough to use things people who have been studied for years cant remember

Was completely expecting text to show up at 1:00 saying "Math sends you to the void" or something lol

1. **Sine (sin)**: Imagine you’re on a roller coaster going up and down. The sine function tells you how high or low you are at any point on the ride.🎢 In a triangle, if you divide the length of the side opposite an angle by the length of the hypotenuse (the longest side), you get the sine of that angle. It helps us understand how steep or gentle a slope is. (For remembering, think of “Sine” as “SLIDE” - it’s like sliding up and down the roller coaster.) 2. **Cosine (cos)**: Cosine is like a buddy to sine. It tells you how far you are from the starting point on the roller coaster. 📏🎢 In a triangle, if you divide the length of the side adjacent to an angle by the length of the hypotenuse, you get the cosine of that angle. It’s like measuring how far you are from the starting line. (For remembering, think of “cosine” as “COZY” - it’s like getting cozy with the starting point.) 3. **Tangent (tan)**: Tangent is like a secret agent that loves to climb. 🧗 In a triangle, if you divide the length of the side opposite an angle by the length of the side adjacent to that angle, you get the tangent of that angle. It helps us understand how steep a slope is compared to how far you move horizontally. (For remembering, think of “Tangent” as “TANGLED/TRIPPED” - it’s like getting tangled up and getting tripped down in how steep the climb is.) These functions are super important because they help us solve all kinds of problems involving triangles, like figuring out the height of a mountain 🏔️ from a distance or the angle a rocket 🚀 needs to launch into space. And guess what? They’re not just for triangles! They’re like Swiss army knives of math - you can use them in all sorts of shapes and situations to figure out Angles and Distances. 📏📐 So next time you’re on a roller coaster or climbing a hill, remember, Sine, Cosine, and Tangent are there to help you understand the ride!

1. **N-dimension**: Think of dimensions as different directions you can go. In our world, we have three dimensions: up-down, left-right, and forward-backward. But in math, we can have more! N-Dimension means we’re talking about ANY number of dimensions, NOT JUST THREE. It’s like having more roads📍to travel on a map 🧭 🗺️ 2. **N-d sphere**: Imagine a ball, like a basketball. 🏀 Now, picture this ball existing in MORE than just our regular three dimensions. An N-Dimensional sphere is like that, but with more dimensions than we can easily imagine. It’s like trying to picture a shape that’s not just round, but also has directions we can’t see. It’s a mind-bending concept! 🫨 3. **What they do in mathematics**: N-Dimension helps mathematicians explore and understand shapes 🏀and spaces in more complex ways. It’s like giving them a bigger playground 🛝to play in, where they can imagine and create new things that we can’t even see in our regular three-dimensional world. It’s crucial for studying things like Geometry, Topology, and even Physics. 4. **Real-world concepts**: While it might be hard to imagine objects existing in more than three dimensions in our everyday lives, concepts from N-Dimension mathematics actually help us understand things like how the universe works on a fundamental level. For example, theories in Physics, such as String Theory and Quantum Mechanics, rely on ideas from N-dimensional spaces to explain the nature of reality. 5. **What would happen if it didn’t exist**: If N-Dimension didn’t exist, mathematicians would be limited in their ability to describe and understand many phenomena in the universe. It’s like trying to navigate a maze with only a few paths instead of having the whole map available. Without n-dimension, our understanding of mathematics and the world around us would be much narrower. To remember, think of N-Dimension as a magic doorway🚪✨ to worlds beyond our own, where mathematicians explore and discover new wonders. Just like exploring a new video game with endless possibilities, N-Dimension opens up endless possibilities for exploration and discovery in mathematics and beyond!

so glad this is here! i'm really happy with how much i was able to recognize the first time (aleph, complex plane, ∞-dimensional ball) but the slightly more in depth explanations of the sum figure and the integral staff helped a lot!

I still can't believe that is literally a lot of math explained just on one video!

Thank you for this! I loved the original video but knowing more of the context behind it is great

Let's break down Quadratic Equations and their different forms in a simple way: 1. **Quadratic Equation**: - A quadratic equation is like a special math recipe for solving problems involving squares and squared terms. ▪️ - It's written in the form (ax^2 + bx + c = 0), where (a), (b), and (c) are NUMBERS, and (x) is the VARIABLE. - Quadratic equations show up in many different situations, from physics and engineering to finance and computer science. 2. **Forms of Quadratic Equations**: - **Standard Form**: The standard form is the basic format of a quadratic equation, written as (ax^2 + bx + c = 0). It's like the DEFAULT SETTING for quadratic equations. - **Factored Form**: The factored form shows the quadratic equation factored into its LINEAR FACTORS, like (x - r1)(x - r2) = 0), where (r1) and (r2) are the roots or solutions of the equation. It's like breaking the equation into its building blocks. - **Vertex Form**: The vertex form is written as a(x - h)^2 + k = 0, where (h, k) is the VERTEX or turning point of the parabola. It's like zooming in on the most important point of the graph. 3. **Differences and Usage**: - **Standard Form**: Used for GENERAL ANALYSIS and solving quadratic equations ALGEBRIACALLY. - **Factored Form**: Used to find the ROOTS OR SOLUTIONS of the quadratic equation easily by factoring. - **Vertex Form**: Used to identify the VERTEX or TURNING POINT of the parabola and to graph the quadratic equation efficiently. 4. **Purpose in Math and Real World**: - Quadratic equations help us model and solve problems involving motion, optimization, and geometry. - For example, they're used in physics to describe the trajectory of a projectile, in engineering to design structures like bridges and buildings, and in finance to analyze investments and loans. (**Tips and Tricks**: - Remember the Standard Form as the DEFULT SETTING ⚙️ for quadratic equations. - Think of Factored Form as breaking the equation into its BUILDING BLOCKS 🧱. - Visualize Vertex Form as zooming in on the most important point of the graph - THE VERTEX. ⚫️) In summary, Quadratic Equations and their different forms are like versatile tools in mathematics and the real world. They help us solve problems involving squares and squared terms efficiently and accurately, whether we're calculating trajectories, designing structures, or analyzing financial investments. Understanding the differences between Standard, Factored, and Vertex forms helps us choose the right tool for the job and unlock the power of Quadratic Equations!

5:04 I think he uses i with his arrow to make the translation upward (2x2xi) but since he was running so it makes an arc. That also explains why he can't sustain his elevation like e and falls down right after.

I still remember calling math an easy subject when I was 1st, 2nd grade etc. But oh boy! Match is much harder than I thought it would be.

I have watched many analyses on this subject, but none of them noticed the exponential relationship with dimensional shapes like you did. Impressive stuff.

There is still a lot of stuff with which I struggle in here (everything that involves the radian gives me a headache) but there are some stuff that I finally begin to grasp when given visual form. Alan truly outdid himself with this one and your explainations are very welcome.

8:25 I think you might have put sin(x) and cos(x) the wrong way round? Still the best explanation of this I’ve seen, with so many easy-to-miss details!

10:00 One point i think you missed is right after the integral appears, there's some expressions that appear on the left and right of it. The integral is 5 separate integrals, which are in the exponents of the e^...i on the left of the integral, each of the top 3 evaluate to π/2, the fourth goes to 3π/8, and the last to π/3, meaning that each of the five expressions evaluate to e^iπ. Also at 8:30 i didn't realize why the tan function was cancelling out the e^iπ since I didn't see the π that was multiplying in the tan function, good job spotting that. And at 13:04, while i knew the formula for the volume, It just didn't connect for me, so overall great job of explaining it.

Dude that was boss. Loved it. I was happy to have already learned 99% of that stuff otherwise it would have be way harder to follow along. Still had to slow down the speed to .5 to really grasp what was happening though. made me so happy watching this.

I was thinking the video was going to explain more the maths, but its very cool like this !

This was exactly the mathematical breakdown I was looking for. Thank you so much for posting it!

Seriously somebody better make a game based on this animation as I'm pretty sure it can be a real entertaining way to teach kids of any age Mathematics how i know I'm pretty sure mathematicians and math teachers would agree to the idea

Best explanation on the video so far, a lot of others I found missed more intricate details and the ending concepts

this is literally the best analysis of it I've seen so far

I personally thought the reason why the circle increases is because more E^i[pi] enters it, thus 'adding' to the radius. I only noticed with multiple watches, but as more enter the circle, it increases in size. I don't think any of them are actually touching the equation-just that their mere presence is adding into it!

9:59 this my favorite part of you commentary, really nails what happened

Detail: in this fight 7:23 stickman grab as a sword the lenght unit (1) and the "e" fights with -1 and that is 0. Then "e" transform the -1 into 2 that is the double of 1. That's why stickman it's pushed back. 2 is more than 1.

Alan Becker and his team are Genius 🤯🤯

As someone who took honors math classes throughout high school, the fact that recognize almost all of these mathematical concepts both amuses me and horrifies me.

Noone's talking about this, but in 5:53 TSC multiplies itself with the radian(or seems like it) making another copy of it impling that TSC's value is 2 in the "math dimension". Just theory crafting over here lol

This was really nice. I recognized most of the math in the animation, and at least understood what sorta math most of the rest was, but this really filled in the blanks in an understandable way, thanks!

This is by far one of my favorite animations of all time, because it combines two things I love: math and epic battles.

4:41 "By the power of addition, i compels you -e^i(pi) !!"

"The smallest cardinal infinity (hence why its so big)" you realize how insane that sounds right /pos AVM has me in a chokehold man. And watching this video explaining the things in it just made me love it even more. Thank you so much!

Note that at the third appearance of Euler's Identity, when they're fighting, TSC uses the arc of the radian, which is the radius, of 1. This is why the swords cancel each other out.

Seeing all of this makes me realise just how visually striking this animation is in terms of what it conveys, such as 8:15 and 9:57

respect for this guy for putting hard work for this so the kids can understand some stuff

Thank you for doing an analysis of this.

Please make more of these, I know you didn't animate this but it adds so much to the video, really cool

Finally someone that can explain it easier and straight to the point, great job!

I'm surprised how much of this I actually totally understood after just a little explanation lol. And THANK YOU, the mystery of Aleph has been itching my brain for days. Couldn't figure out how to even search for it by visuals.

You are the best explaining everything in this video and helping me understand this!

Sure, let's break down Extrapolation 📈 and Interpolation 📊: 1. **Extrapolation**: Extrapolation is like predicting 📈 what might happen in the future based on what we already know 🧐. It's like guessing where a story 📖 will go based on the beginning or estimating how tall a plant 🌱 will grow based on its current height. In math, Extrapolation means EXTENDING a line or curve beyond the known data points📍. For example, if you have a graph showing the population growth of a city over several years, you can use Extrapolation to estimate the population in future years 📊. 2. **Interpolation**: Interpolation is like filling in the missing pieces of a puzzle 🧩 based on what we already have. It's like guessing what happened between two scenes in a movie 🎥 or estimating someone's age based on their height🧍‍♂️. In math, Interpolation means estimating values WITHIN the range of known data points📍. For example, if you have a set of data points representing the temperature at different times of the day 🌡️, you can use interpolation to estimate the temperature at times between the recorded data points. 3. **Relationship and Tips**: - **Relationship**: Extrapolation and interpolation are like two sides of the same coin 🪙. They both involve making educated guesses based on existing information, but they do it in different ways. Extrapolation looks to the FUTURE or BEYOND the known data 📈, while Interpolation looks within the known data range 📊. 4. **Real-Life Examples**: - **Extrapolation**: Imagine you have a graph showing how fast a car is accelerating 🏎️💨. You can use Extrapolation to predict how fast the car will be going at a certain time⌚️in the future 📈. - **Interpolation**: Imagine you have a recipe for baking cookies 🍪, but it only lists the ingredients for making one dozen 1️⃣2️⃣. You can use interpolation to figure out how much of each ingredient 🗒️ you'll need if you want to make two dozen 2️⃣4️⃣ cookies. (5. **Tips and Tricks**: Remember that "EXTRA" in Extrapolation means going BEYOND what we already know, like extra toppings 🍄🥓🧀 on a pizza 🍕 representing future predictions. For Interpolation, think of "INTER" as meaning between, like filling in the gaps between known points📍on a graph 📊.) In summary, Extrapolation and Interpolation are both methods of estimating values based on existing data, with Extrapolation looking to the FUTURE or BEYOND 📈 and Interpolation filling in THE GAPS📍within the KNOWN RANGE 📊. Whether you're predicting future trends or filling in missing information, these techniques help us make educated guesses and solve problems in math and real life.

6:22 When a circle is stretched like that, it turns into an ellipse. So, any ellipse with major and minor axis greater than or equal to the radius of a circle and be created by stretching said circle.

9:57 "Integrals can handle infinites". Bro is saying it like he's a marvel supervillain or something

Okay, thank you for breaking this down. Most of it's over my head, but I love how you explained everything.

12:59 - I'm not sure if it's intentionally, but when e is stood next to the circle and beckoning TSC to enter, the "iπ" part overlaps with the circle and looks like it says "in", which is where it wants TSC to go.

I love it that you chose this form of anaylsis with editing in text instead of stopping it every time something comes up, much better

This video made me realise how much detail they put in ! Even the having the "bullet" make a tangent wave !

Honestly, There is SERIOUS work done in alns video, the insane attention to detail, its almost like itts full of MATH REFERENCES? Wasn't expecting this from the channel with stick figures on a windows desktop

Alright, let's simplify the Riemann Hypothesis: 1. **Riemann Hypothesis**: - The Riemann Hypothesis is like a big mystery in mathematics, waiting to be solved. - It's named after Bernhard Riemann, a famous mathematician who came up with the idea in the 19th century. - The hypothesis is about Prime Numbers, which are like the building blocks of all other numbers. 2. **What it Means**: - The Riemann Hypothesis is all about understanding the distribution of prime numbers along the number line. - It suggests that there's a special pattern or formula that can predict where prime numbers will show up, but no one has been able to prove it yet. 3. **Why it's Important**: - Solving the Riemann Hypothesis would be like cracking a secret code in mathematics. - It could unlock new insights into the behavior of prime numbers and help us solve other math problems, like factoring large numbers and encrypting data. 4. **Usage and Practicality**: - The Riemann Hypothesis is used in many areas of mathematics and science, including Cryptography, Number Theory, and Computer Science. - It's like a treasure map that mathematicians follow to uncover hidden gems of knowledge about Prime Numbers and their properties. (**Tips and Tricks**: - Remember the name "Riemann" and think of it as the key to unlocking the mystery of prime numbers. - Picture prime numbers as special treasures waiting to be discovered along the number line.) In summary, the Riemann Hypothesis is like a mathematical puzzle that has baffled mathematicians for centuries. It holds the key to understanding the mysterious patterns of Prime Numbers and has the potential to revolutionize our understanding of mathematics and its applications in the real world.

4:34 He multiplies his speed by... anything i guess

WHERE'S THE VIEWS THIS IS SO GREAT i subbed

I learned new things out or Alan's animation and your explanation, thank you very much!🎉❤

Fantastic video shown to me by my kid, now he is excited by complex numbers and integrals. What a great way to make Maths lovable and Interesting 👍👏 Big Thank you

I loved this analysis!

That was amazing. Thanks for the analysis, I learned something from this.

thank you for this analysis,very entertaining,is a very cool additive to the original video

Let's Explain what are Metric Tensors and Transformation Matrixes and what they do: 1. **Metric Tensor**: - The Metric Tensor is like a special tool in math that helps us measure distances and angles in curved spaces. - It's like a ruler 📏 that changes depending on where you are in space - it tells you how distances and angles warp and stretch. - In physics, the Metric Tensor is used in Einstein's Theory of General Relativity to describe the curvature of spacetime caused by massive objects like stars and planets. 2. **Transformation Matrix**: - A Transformation Matrix is like a magic recipe that tells you how to change or transform Vectors from one coordinate system to another. - Imagine you're playing a video game and you want to rotate or scale an object - you'd use a Transformation Matrix to do that. - Transformation matrices are used in Computer Graphics, Robotics, and Physics to describe movements and transformations in space. 3. **Vector**: - A Vector is like an arrow that shows both Direction and Magnitude (Size). - Imagine you're giving directions to a friend - you'd say something like "Go 3 steps to the right" or "Walk 5 steps forward." - Vectors are used in math and physics to represent Movements, Forces, Velocities, and more. **Relation to Dimensionality**: - Both the Metric Tensor and Transformation Matrices are related to dimensionality because they describe how things change or transform as you move through different dimensions. - They help us understand and navigate complex spaces with multiple dimensions, like curved surfaces or higher-dimensional spaces. **Usage and Practicality**: - The Metric Tensor helps us understand the geometry of curved spaces in physics and cosmology, while Transformation Matrices are used in computer graphics, robotics, and physics to model and simulate movements and transformations. (**Tips and Tricks**: - Remember Vectors as arrows ↔️ that show both Direction and Magnitude. - Visualize the Metric Tensor as a flexible ruler 📏 that bends and stretches in curved spaces. - Think of Transformation Matrices as magic recipes that transform Vectors ↔️ from one coordinate system to another ↕️.) In summary, the Metric Tensor and Transformation Matrices are like powerful tools that help us understand Curved Spaces, Higher Dimensional Spaces, and Vectors in Math and Physics. Whether we're exploring the curvature of spacetime or animating characters in a video game, these concepts play a crucial role in our understanding of the world around us.

This truly explains a lot about how Alan Becker is truly one of the best Number Lore creators of all time. ✊

2:57 I think it is like “turn ‘on’ to calculate and turn ‘off’ to stop the process” But these symbols are the same, if I haven’t forgot.

You and Alan have just made the best math tutorial video in Human history

A best content always get a explanation that some people dont get it. Thanks man

"TSC makes some shapes; it can't handle the integral" omg he just like me fr

Instructions unclear. I am falling off a bridge now. Help!!!

Thanks for making this commentary! Once they started dealing in calculus, the original animation lost me, 😅 but your explanations really help!

I like how when hes pulling numbers apart their still displaying logic. Pulling one away from one has two "strings" still holding them together: an equals sign

Im glad I found this its the only review/breakdown video I could find that properly covers everything that happens thanks a ton for the explanation of all this it was amazing to learn