how to solve these HARD integrals

Paused the video:
The way I did the second one
(x^6 + x^3)(x^3+2)^(1/3) = x^3(x^3+1)(x^3+2)^(1/3)
Integral of x^3(x^3+1)(x^3+2)^(1/3) dx
Let u = x^3 + 2
du = 3x^2 dx
1/(3x^2) du = dx
u = x^3 + 2 => x^3 = u-2
=> x = (u-2)^(1/3)
Integral of x^3(x^3+1)(x^3+2)^(1/3) dx = Integral of x^3((u-2)+1)(u)^(1/3) * 1/(3x^2) du
= Integral of x(u-1)(u)^(1/3) du
= 1/3 Integral of (u-2)^(1/3)*(u-1)*(u)^(1/3) du
= 1/3 Integral of u^(1/3)*(u-2)^(1/3)*(u-1) du
= 1/3 Integral of (u*(u-2))^(1/3)*(u-1) du
= 1/3 Integral of (u^2-2u)^(1/3)*(u-1) du
Let w = u^2 - 2u
dw = 2u - 2 du
= 2(u-1) du
1/3 Integral of (u^2-2u)^(1/3)*(u-1) du = 1/3 *1/2 Integral of (u^2-2u)^(1/3)*2(u-1) du
= 1/6 Integral of (w)^(1/3)* dw
= 1/6 * w^(1/3 + 3/3) / (4/3) + K
= 1/6 * (3/4) * w^(4/3) + K
= 3/24 * (u^2-2u)^(4/3) + K
= 1/8 * (u(u-2))^(4/3) + K
= 1/8 * ((x^3+2)(x^3 + 2 - 2))^(4/3) + K
= 1/8 * (x^3(x^3+2))^(4/3) + K
= x^4(x^3+2)^(4/3) / 8 + K
0:39 If I let u equal to the inside, it's a no (actually it's a yes technically just look above)
The way I did the first one:
1/(x^2(x^4+1)^3/4) = 1/(x^2(x^4(1+1/x^4))^3/4)
= 1/(x^2(x^3(1+1/x^4)^3/4))
= 1/(x^5(1+1/x^4)^3/4)
Integral of 1/(x^5(1+1/x^4)^3/4)) dx
Let u = 1 + 1/x^4
du = -4/x^5 dx
Integral of 1/(x^5(1+1/x^4)^3/4)) dx = -1/4 Integral of (-4)/(x^5(1+1/x^4)^3/4)) dx
= -1/4 Integral of 1/(u)^3/4 du
= -1/4 Integral of u^(-3/4) du
= -1/4 (u^(-3/4 + 4/4))/(1/4) + C
= -(u^(1/4)) + C
= -(1+1/x^4)^(1/4) + C
= - ((x^4 + 1)/x^4)^(1/4) + C
= - (x^4+1)^(1/4) / x + C
The second one took me longer because I failed to see that I could do something with (u-2)^1/3*u^1/3 and combine them.

I hate doing the arithmetic when evaluating definite integral. I'm definitely an indefinite integral person.

Can someone give this man a bigger whiteboard?? 😂😂

The second problem was asked in IIT-JEE in the year 1992!
Now that form has become a standard form!

Hey!
I've been studying for an exam and I'm not sure what it is about you, but you help more than these other math teachers and people on TH-cam. I wanted to comment this just to let you know how much you help me and these other viewers. Hats off to you, I give a sincere thanks. You've earned my subscription.

i'm still waiting the day where he would forgot the +C 😂

Dude, you got a cute little 3blue1brown pi there!

Me reading the title: Well.....I mean yes...no...maybe

Wow Randy is really getting around, such a fan

Almost forgot the +C. I still remember my calculus teacher:
If you don't add the +C, you're giving only one solution, and no infinite. How many points should you get because of that?, use cross multiplication to know it.
∞→ 10 points
1→ ?

9:26 I thought you are going to write the power on the wall. Lol!

For the first question taking the substitution x^2 as tan(u) also solves the integral in a very concise way.

0:01 *"tunanenunanenuna"*
18 year old me: starts singing *Doraemon* theme song...

We see many of these hard equations, but what we are most interested in is how to identify a situation and then create the equation that fits it. So, how to model real life problems into a mathematical form. I think that skill is more rewarding than solving, because much of the solutions are now done virtually.

Congratulations man you are always dedicating ur time for students around the world thanks for making maths a fun thing

I used the trig substitution: x^2=tan(u) for the first integral. You just have to do some cancellations and convert sec and tan into sin and cos.

I watch these videos and am sometimes frustrated because I can't figure out any strategies I can use. The first problem, though, I think I can pull this strategy out: if you've got a complicated denominator with polynomials, you'll need some powers of "x" on the top so you can make a "du" to go with the "u" on the bottom. So, multiply top and bottom by whatever powers of "x" are required to make it happen, and don't be afraid of negative exponents on top and bottom.

I just started integrals and I highly recommend everyone to watch bprp! I know it does sound a casual commercial advertisement but it isn't! I mean he is good at it definitely. There are few who can explain such easily like that and fully understands the point. I just started like a week ago and I already know a lot cuz of bprp. Greet love from somewhere else on earth.

Hello BPRP! I was wondering if you are going to record a video like the "Ultimate Integral Starter", but with derivatives, something like "Ultimate Derivative Starter". I have watched the entire video of Integrals and now I see all techniques cleaner, and whenever I see Integrals, I remember all the wonderful explanations of every one of the tecniques (u sub, Trig sub, By Parts (DI and u-dv Methods), Partial Fractions...). But after learning all of this amaizing content, I say to myself "I wish there was a Ultimate Derivative Starter made by bprp, It would be so nice!! both for new students and for people like me who wants to see Derivatives again nicely, watching a great long video with all the rules and formulas. Hope you read this comment, I enjoy a lot math watching your videos, and thanks to you I got motivation to study Mathematics at University (Currently I haven't finished high-school).
Sorry for my bad english, I'm Spanish :P

substituting x^3 + 2 as u and taking out x^3 common from x^6 + x^3 can also work. Then in the resulting expression (u^2 -2u)^1/3(u-1), u^2 -2u can be resubstituted as t.

I passed the previous math analysis exam practically just because of you. Thank you a lot

On the 2nd one I factored out x^3, u subbed for x^3+1.
Had to isolate x, and followed that line down…
…1/3(u^5-u^3)^1/3
(during this step, I did have to bring the u into the cube root, multiplying the now u^3 within, which seemed natural to make it less complicated)
Factored out u^3 to bring it outside the cube root, resulting in…
…1/3 u(u^2-1)^1/3
W subbed for u^2-1 and followed that line to get 1/6(integration(w^1/3))dw
Do the fundamental theorem, and sub back in twice, getting 1/8[(x^3+1)^2-1]^4/3. Then, classic square technique, and the +1 and -1 cancel to get
1/8[x^6+2x^3]^4/3 +c
Though my way felt worth the effort, seeing your simplistic approach was surprising. Idk how to get that insane intuition 😅

BPRP: Almost forgets the +C
Me: *PANICC*

2nd one :
First I took x^3 common
=X^3(x^3+1)(x^3+2)^1/3
=( x^3+1) = t ( for substitution)
Therefore, 3x^2.dx=dt
Also, x=(t-1)^1/3
So if we substitute everything then. It becomes
= ((t-1)1/3 .t. (t+1)^1/3) /3
(note :- x^3+1=t ,
So, x^3 + 2 = t+1)
Now, =( (t-1)^1/3.(t+1)1/3. t) /3
----------------------------
Now the terms above the underlines ( or whatever it is) is, (t^2-1)^1/3
So, = ((t^2-1)^1/3. t. dt) /3
Now, can substitute t^2-1 = u
So, 2t. dt = du
So, after substituting everything
= (U^1/3 . du) /6
= (u^4/3 . 3) 24
= (u^ 4/3 )/8 .
Now after , Putting value,
= (x^4/8 + c)
It's different from your answer teacher but I think in indefinite Everyone will get different values so. Here is my answer.

*Spiderman: Every video I go*
Indian Jee Aspirants
*Spiderman: I see his face*

I am getting addicted to your videos . Your videos are so interesting.

The first problem can be solved like this too
x=1/u
du/dx=-1/x²
Now it becomes
-u³du/√(u^4+1)³ [fourth root]
u^4+1=z
To solve the second one take x³ common from the left lart and x³+2=u³
From this we also get x³+1=u³-1
The method shown in the video is better

Great video as always

@9:30
Dear bprp,
I like the way in which u fit everything in such a small board
So beautifully...

Yeah same pro i struggled with the integral on the right and the integral on tge right is a piece of cake

1. Differentiate the integral formula
2. The result formula is the just problem.
So reverse thought for 1. formula is necessary but difficult.

solved the second integral before watching it in the video: let u = x^3 + 1 . Thus du = 3x^2 dx. The integrated can be rewritten as x^3(x^3+1)(x^3 + 2 )^(1/3). the x^3 at the front becomes 1/3x * 3x^2, which then becomes 1/3 (u-1)^(1/3), and the 3x^2 can be lumped with the dx at the end to equal du. The x^3 + 1 in the middle is just u, and the (x^3+2)^(1/3) becomes (u+1)^(1/3). The integrand, in terms of u, then becomes u*((u-1)(u+1))^(1/3), or u*(u^2-1)^(1/3), which then is just a simple u-sub that yields 1/8 * (u^2 - 1)^(4/3) + c, or 1/8 ((x^3 + 1)^2-1)^(4/3) + c = 1/8 (x^6 + 2x^3)^(4/3) + c

In the first problem, I recognized 1/x^2 right away and found u=1/x could work.

He's holding that stuffed Pi like a Totem of Undying. 😆

Can you do a series answering all the questions from the MIT integration bees explaining all the steps? Thank you!!!!

1:20 We love that as WELL!

Put x=1/t and first one gets solved in a moment

i cracked when he said "keep these things in your mind because maybe you will encounter them in your dream and attack you" lmao

I did this problem when i was preparing for jee(entrance exam in india for admissions in engineering colleges)
This ones considered the easiest type in indefinite integration..

Surely a indefinite Integral person

taking the fourth root of something put to the fourth power: should it be absolute value ?

The first one could have been done easily just by taking x^16/3 and then putting the inside value equals to 't'

Oh, my god, this guy is just a Genius

Well done !

If you can't taking out of the square root doesn't work , force it into the root

Now don't say even this was a lost video.

One of the reastest abilities is not be able to solve these integrals but instead to smoothly change between color pens

Almost lost my last brain cell from mistaking the 1/8 as 13/8

Lol for the second integral I factored out an x^3 first for some reason and split it into x^2*x. I had to do 2 subs but it eventually worked

I love these integrals

Any time you see questions like this, there is often some manipulation which simplifies it greatly. Failing that,
Either the answer will be simple, but the technique will be tough
Technique will be easy but the answer will be something monstrous.

We do such questions in 12th here in India

No one :
My brain: He is holding square-root of 6[1/1² + 1/2² + 1/3² ....... ]

I love being the only archeologist understand and solve integrals in my class. NICE VIDEO, DUDE.

I'm an indefinite person. I don't want to add in my limitations while searching for the area. I'll take the arbitrary constant over anything.

The algebraic manipulation is insane.

they taught us the first one in school checkout ncert class 12th integrals exercise-7.5 Q16😭

you can just substitute x=1/t in the first question, right? I've got the same answer but doin' like this and I followed the same procedure as u did in the second one tho. Can you please reply and justify my statement sir?

I’m watching this and I am nowhere near this level of mathematics. I’m picked advanced math but am dropping to standard because it’s too hard

Shouldn't the fourth root of x⁴ be |x| instead of x? Why didn't you use the absolute value?

I think some step in the first problem isn't clear. How can you take the power inside the root directly without considering the root itself?

For the first one, when taking out x^3, don’t you need to take the absolute value?

This isn't really a hard integral exercise it's a niche elementary math applied to solving integrals. It doesn't test my knowledge of integrals, it tests if I remember that niche thing my math teacher told us not to worry about.

It's been 3 days I had started learning definite integration so I don't know maybe I am which one but until then proud to be indefinite integral person ..🙃
Btw love your videos they are actually helpful and interesting 🙂

was that the doraemon theme song at the start? haven't heard that in a long time

when you take out of the 4th root the (x^3)^4 , isn't it |x^3| in case x is a negative number?

I handed my tuition fee to the wrong school

i want the blue pi plushie so badd

Hmm. The first one was very easy, but the 2nd one really made me scratch my head.

Damn they are easy, most of the time in such complex ones, there just lies to factor out or create one exponential term of x that directly converts into a substitutable question. And Im a definite integral person btw, cuz thats all brain and indefinite is just try this try that!

Lovely videos. What's he holding the dolls for though?

Just one question is x cubed an odd or even function? My math teacher wrote it as even but i wonder if she made a mistake

since last tuesday i'm patreon of your channel. however, I couldn't see my name in this video published just 18 hours ago.

Can i draw an imaginary circle with negative radius on complex plane???

So, when you have a root, just say what you have inside is u and manage to have du showing up

Can we asume x³+2 as t³

Shouldnt it be absolute value of x on the first question? it s techinically 4rth root of x^12 =sqrt of x^6. Correct me if i m wrong

1st one is a ncert question of class 12 and this is actually easy😂😂😊

Hello great video, I have a question. In the second question why does the x from the outside get raised to the power of 3 once it enters the cubed root

Hi bprp I don't know that you remember or not but few months ago during that covid 19 lockdown I have emailed you four integral battle problems if you remember than can you make video on them ?????????????

And this is why I ended up with a 12 in senior year math :/

If you fight an integral
Dont cry just look at the sky
And say
Wouldn't it be nice

When people make integration problems do they just differentiate a function and then rearrange and rephrase the derivative until it is sufficiently difficult?

I am definitely a "Definite Integral" person :)

That white board is too small :(

your teaching is superb can you teach 3D vectors

What an idea mann😢

▶All time your problem is highlighted in my life, being a good person I love your teaching and I'm happy to accept you as my teacher. Heartful thanks for hard work. ✔

My answer is . . . Most DEFINITELY INDEFINITE integrals
Just work out the primitives/anti-derivatives.

These are so easy

I guess u broke ur board into two

I have a question could we let u = x^2 in the first one and let u= x^3 in the second one?

Es hermoso tu Universo de la Matematica , saludos

Strange : I write your 2 first expressions (before 3:29) : the first one is even and the second one is odd???? How is possible?

In india we call this the kutur putur technique

amaziiiinnngggg

What happened to big board

I kinda hate Definite Integrals. Hate the extra work lol.

Very good

Hi all, would someone be kind enough to explain this next thing to me ?
I don't understand the last line of the first integral, the step where he says "Of course add one which is going to be positive one over four".
Thanks for (maybe) helping me out !