Glad it helped! :^D

Thanks! :^D

Blackpenredpen also made a video on the “stops” and how to use the method for compound e^x and trig functions

Best of luck! :^D

Seems it didn’t help you lol 😅

Many calculus classes do, but there are some integrals that require using integration by parts many times. Using a table like this (aka tabular integration) helps so when this happens. Glad I could show you this great technique. :^D

mine too. I guess professors must not like tabular integration!

Isn't it like the more precision one in ILATE gets differenciated n the other integration

It's a bullshit. Sometimes it works and sometimes not. How do we know, when to stop in case of e^(2x)×sinx? And LIATE doesn't work now...😂 It looks like magician who makes his movements with his hands with poker cards... Bullshit.

@@ramyar669 For exponentials multiplied by simple trig in integration by parts, it makes no difference which function gets which treatment. Both functions follow a cycle when given either treatment, and you'll end up spotting the original integral and solving for it algebraically. ILATE or LIATE is a rule-of-thumb that works about 80% of the time. It isn't always true, and it generally works for the simplest of examples. The groupings are really more like IL:A:TE, since T&E are interchangeable if they come together, like your example. I&L are also interchangeable if they come together, such as integral arcsin(x)*ln(x) dx, which is a very hard one. I find that last one easiest to do, if you differentiate the combination of them with the product rule, and integrate 1 dx instead.

There are three standard stops to integration by parts: 1. The ender. Stop when you annihilate your derivative column to zero. 2. The looper. Stop when you spot a constant multiple (other than +1) of the original integral across a row. Assign I as the original integral, construct result with I replacing the original integral, and equate to I. Solve for I, algebraically. 3. The regrouper. Stop when you can regroup your functions to either integrate by another method, or start an independent table with new functions.

For the last example, given integral ln(x) * x^(3/2) dx. Let ln(x) be differentiated, and x^(3/2) be integrated. After just one step, the ln(x) function becomes an algebraic function, which you can regroup with the other algebraic function in the integral column. This allows you to end the table, and proceed to integrate it with the power rule. S _ _ _ D _ _ _ I + _ _ ln(x) _ _ x^(3/2) - _ _ 1/x _ _ _ 2/5*x^(5/2) Construct result: 2/5*ln(x)*x^(5/2) - integral 2/5 * 1/x * x^(5/2) dx Combine the 1/x with the x^(5/2), pull the 2/5 out in front and get: 2/5*ln(x)*x^(5/2) - 2/5*integral x^(3/2) dx This you can integrate with the power rule, and get 2/5*x^(5/2). Thus, our result with +C is: 2/5*ln(x)*x^(5/2) - 4/25*x^(5/2) + C

I love those explanations! I'll have to use those in my class. :^D

ILATE is a thumb rule, it doesn't need to be always true, if you find any function whose derivate can be found easily, you take that function as 1st function and other one as second.

Anytime you can use integration by parts, you can use this method.

@@MySecretMathTutor Thank you so much 🙏🏻.

That's the part that takes a bit of practice to learn. A good "rule of thumb" is to pick the part that's easy to differentiate as the derivative column, and the part that's easy to integrate as the ant-derivative column. Of course if this doesn't work out, you can always try switching them and try again. After doing a few of these, you'll start to get a sense of the types of integrals this technique works best on.

There's a rule called the LIATE (Acronym explained below) Rule, that helps you better determine which part of the function should be your u, and then the rest of the function, by default, becomes your dv. You look at the function that you're integrating, and you go left to right, in the word, "LIATE." Whichever one appears first in LIATE becomes your u, and then everything else becomes your dv. L = Logarithmic I = Inverse Trig A = Algebraic T = Trig E = Exponential

So, for example, suppose that we were integrating x^2*(sin(x))*dx. Going from left to right, in LIATE, we do not see a Logarithmic Function or an Inverse Trig Function. However, we do see an Algebraic Function (In this case, x^2), whereas the sin(x) is a Trig Function. The letter, "A," comes before the letter, "T," in the word, "LIATE," so we take our u to be x^2. Everything else in the function becomes our dv, by default, so our dv would be sin(x)*dx. Hence, u=x^2, and dv=sin(x)*dx.

When this happens it might be two things.... 1) Try a different choice for the "u" and "dv" pieces. The chain might no be long enough when it cycles back to get a useful value so a different choice could help. 2) It may be an integral that does not work well with integration by parts. This is an unfortunate problem with many of the techniques for integrals. Some tools will work better for different integrals. If these still don't work, feel free to post it in the comments and I can take a look at it. :^D

Generally yes, but it may not always work. There is no quotient rule for integration, so you have to express your divided function as a multiplied function with a negative exponent instead. For instance, sin(x)/x can't be integrated with this method, and there is a special function called Si(x) that is assigned as the solution. For your example, that's an easy one. Let ln(x) be differentiated, and 1/x^8 be integrated with the power rule. After 1 row, you regroup them when they are both algebraic, and integrate the result with the power rule.

Since the tabular method is integration by parts, I will say yes! :^D

I learned LIPET in class and it seems to follow that- though apparently both of them are just general guidelines and you can just choose whichever is easier to integrate/derive

Yes Given: integral cos(2*x) * e^(3*x) dx Let e^(3*x) be differentiated and cos(2*x) be integrated. S _ _ D _ _ _ _ _ _ I + _ _ e^(3*x) _ _ _ cos(2*x) - _ _ 3*e^(3*x) _ _ 1/2*sin(2*x) + _ _ 9*e^(3*x) _ _ -1/4*cos(2*x) Spot the original integral across the bottom row, and call it I. Equate to I, and construct result: I = 1/2*sin(2*x)*e^(3*x) + 3/4 *cos(2*x)*e^(3*x) - 9/4*I Solve for I: 13/4*I = 1/2*sin(2*x)*e^(3*x) + 3/4 *cos(2*x)*e^(3*x) I = 1/13*[2*sin(2*x) + 3*cos(2*x)]*e^(3*x) Add +C and we're finished: 1/13*[2*sin(2*x) + 3*cos(2*x)]*e^(3*x)

you can apply as normal. derivative of inverse trig functions is in terms of x and not in terms trig functions

Take note that neither of the expressions will go to zero. By stopping it at some point we'll be able to combine the expressions so hat it only has x's in it (no logarithms any more). We could have stopped it later on as well, but this would have given us more terms before the integral. Hope that helps out. :^D

For this problem it will start to cycle. You can use the table for this, just stop the table when it starts to cycle. The video should cover an example of how to deal with this situation. Hope it helps. :^D

@@MySecretMathTutor Sure! Thanks!

integral of e^x is just e^x

Glad you liked it! :^D

Good catch! I better fix that. :^D

MySecretMathTutor Your calculus videos helped me pass by Calculus course. I graduated with my bachelors in March 2019.

Ehhh, whats kal-culas